Metallophthalocyanines as Catalysts in Aerobic Oxidation

Copyright: © 2021 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https:// creativecommons.org/licenses/by/ 4.0/). 1 LAQV-REQUIMTE, Department of Chemistry, University of Aveiro, 3810-193 Aveiro, Portugal; faustino@ua.pt (M.A.F.F.); gneves@ua.pt (M.d.G.P.M.S.N.) 2 BBG-DiSB, Department of Biomedical Sciences, Cagliari State University, 09042 Monserrato, Italy * Correspondence: cmonteiro@ua.pt (C.J.P.M.); msimoes@ua.pt (M.M.Q.S.); sanjust@unica.it (E.S.); Tel.: +351-234370360 (C.J.P.M. & M.M.Q.S.)


General Introduction
After the casual discovery of phthalocyanines (Pcs) at the beginning of the 20th century [1], these macrocycles have been the subject of deep studies, mainly focused on their valuable dye properties [2]. Along the first decades of 20th century, the importance of the coordination of Pcs with metal ions in their synthesis, and in the tuning of their chemical and dyeing properties was explored and emphasized [3,4]. In more recent years, the role of Pcs and their metal complexes (MPcs) as industrial dyes and pigments, was accompanied by an intensive search aiming to develop new fields of application [5,6]. In particular, a growing attention is focused on the redox catalytic properties of MPcs [7]. Although nonnatural, Pcs show a noticeable resemblance to the structurally related macrocycle porphyrin, and also to other non-natural macrocycles such as porphyrazines and tetrabenzoporphyrins ( Figure 1).
Like porphyrinoids, Pcs are aromatic macrocycles obeying the Hückel's rule (with 18 delocalized π electrons). However, the UV-Vis spectral patterns clearly reveal sharp differences that are reflected in the general chemical properties. Rather than from the benzocondensation, such differences mainly arise from the tetra-aza substitution of the four methinic bridges joining the pyrrolic-type rings in porphyrins. The four additional nitrogen atoms exert an electron-withdrawing effect, but also bear filled non-bonding orbitals, which are responsible for n→π transitions, increasing the width of the main absorption bands [8]. In fact, the Q bands of Pcs arise from a 1u to e g transitions, whereas in porphyrins the corresponding bands are due to a 2u to e g transitions [9].
Pcs show a high appetency to form the corresponding dianions upon deprotonation under suitable conditions, affording in the presence of the adequate metal ions the corresponding metal complexes MPcs ( Figure 2). Such a tendency is so strong that very often the syntheses of Pcs is carried out in the presence of a suitable metal salt, thus giving directly the desired products in the form of the corresponding MPcs. Nearly all the elements of the periodic table are capable of forming complexes with Pcs, directly or, also, by metal-exchange reactions. With regard to such metal complexes, a further important difference between porphyrins and phthalocyanines is a consequence of the shorter bonds between the pyrrolic carbon atoms (from the isoindole units) and the nitrogen atoms of the aza bridges in phthalocyanines when compared with their porphyrin counterparts. So, the central cavity in a phthalocyanine ring is smaller than the corresponding one in porphyrins, and by consequence the central metal ions are forced to lower their spin. The more compact electron cloud of the coordinated metal ions in MPcs is also due to the stronger both σ donor and π acceptor character of Pcs when compared to identically substituted porphyrins. Therefore, in spite of the smaller space available, the metal ions fit better within a phthalocyanine rather than in the corresponding porphyrin, and thus in general they lean only slightly out of the phthalocyanine molecular plane [10,11].
An outstanding and well known feature of many Pcs and also of MPcs is their thermal stability that allows their purification by sublimation in high vacuum above 250 °C. Thermal stability is paralleled by a noticeable chemical stability that is better defined as inertness for many Pcs and MPcs.
The four condensed benzene rings present in the isoindole units could undergo a number of electrophilic aromatic substitutions; however, a complex mixture of isomers, varying both in substitution degree and substituent positions, are usually formed, that Such a tendency is so strong that very often the syntheses of Pcs is carried out in the presence of a suitable metal salt, thus giving directly the desired products in the form of the corresponding MPcs. Nearly all the elements of the periodic table are capable of forming complexes with Pcs, directly or, also, by metal-exchange reactions. With regard to such metal complexes, a further important difference between porphyrins and phthalocyanines is a consequence of the shorter bonds between the pyrrolic carbon atoms (from the isoindole units) and the nitrogen atoms of the aza bridges in phthalocyanines when compared with their porphyrin counterparts. So, the central cavity in a phthalocyanine ring is smaller than the corresponding one in porphyrins, and by consequence the central metal ions are forced to lower their spin. The more compact electron cloud of the coordinated metal ions in MPcs is also due to the stronger both σ donor and π acceptor character of Pcs when compared to identically substituted porphyrins. Therefore, in spite of the smaller space available, the metal ions fit better within a phthalocyanine rather than in the corresponding porphyrin, and thus in general they lean only slightly out of the phthalocyanine molecular plane [10,11].
An outstanding and well known feature of many Pcs and also of MPcs is their thermal stability that allows their purification by sublimation in high vacuum above 250 • C. Thermal stability is paralleled by a noticeable chemical stability that is better defined as inertness for many Pcs and MPcs.
The four condensed benzene rings present in the isoindole units could undergo a number of electrophilic aromatic substitutions; however, a complex mixture of isomers, varying both in substitution degree and substituent positions, are usually formed, that could find application in industrial dyeing, whereas they are very tedious-if not impossible-to separate and purify for research purposes. To afford definite substitution products, the preferred routes start from the synthesis of properly substituted phthalonitriles. Once the derived Pcs are obtained, they could be further modified with the known organic synthesis tools [12]. However, unsymmetrically substituted phthalonitriles unavoidably afford isomeric mixtures of substituted Pcs.
Another noticeable feature of many MPcs is their very low solubility in many organic and aqueous solvents. Simple MPcs as well as the corresponding free-bases are completely water-insoluble, whilst slightly to moderately soluble in several organic solvents [13]; on the other hand, solubility in concentrated sulfuric acid is often high, owing to the protonation of the aza bridges between the isoindole rings. The introduction of alkyl or alkoxy substituents at the periphery of the Pc or MPc macrocycle causes a noticeable increase in the solubility of the substituted compounds in organic solvents. Under this context, the t-butyl substituents are bulky enough to prevent aggregation and stacking, and consequently are considered particularly suitable to improve the solubility of Pcs [12]. On the other hand, the introduction of very polar or ionizable substituents, such as -SO 3 − , -N + (CH 3 ) 3 , and pyridinium groups, affords water-soluble derivatives. Pcs and MPcs very often show a definite tendency to aggregate in solution, in particular in water or aqueous solvents, even when ionic substituents are present on the benzene rings. The aggregation state could be reliably estimated by means of spectroscopic techniques [9,14,15]. Aggregation could arise by simple stacking, driven by strong hydrophobic and π-interactions between the Pc rings, or also it depends on covalent interactions involving the central metal ions, linked each other by axial µ-oxo bridges. As expected, a decrease in the Pc concentration and an increase in the temperature milieu favor the presence of the monomeric form. MPcs facing to Pcs could form two additional, axial bonds with coordinating species and solvents, when the central metal ion prefers an octahedral coordination geometry. By consequence, MPcs that are insoluble or poorly soluble in "usual", non-coordinating solvents such as chloroaromatics are well soluble in coordinating solvents, such as pyridine (Py). As a well-known example, ZnPc is soluble in dichloromethane as its pyridine complex (Zn(Py) 2 Pc), whereas it is quite insoluble in the absence of such a ligand [16]. Weakly coordinating solvents such as dimethylformamide (DMF), dimethylacetamide and dimethyl sulfoxide (DMSO) often represent a reasonable compromise as they dissolve many MPcs but are readily exchanged with stronger coordinating species when required. MPcs solutions in concentrated H 2 SO 4 are useful for spectroscopic measurements as they contain protonated monomeric species, although their usefulness to determine other properties or find practical applications is negligible.

Metallophthalocyanines as Redox Catalysts: An Overview
As noted above, the first noteworthy property of MPcs was their chemical "inertness", which made and make them very attractive as stable and durable industrial dyes. However, their rich redox chemistry has only been explored in the last few decades [17].
In fact, MPcs are protected by their structure against the main threats jeopardizing redox-active metalloporphyrins, and that is the outstanding limitation towards an extensive use of the latter as industrial catalysts. First, the methinic bridges joining the pyrrole-type rings in porphyrins are the preferential targets of oxidative attack, leading initially to oxophlorins and later to macrocycle breaking and therefore to catalyst destruction [18]. Such methinic bridges are replaced in MPcs by aza bridges, which obviously are generally inert towards oxidative attacks. Second, the four condensed benzene rings protect the pyrrolic β-positions against any unwanted substitution reaction and prevent any possi- The experimental conditions have a great influence on the equilibria between Mn(II) and Mn(III) Pcs, as well as on their oxygenated derivatives; under certain conditions, the oxygenation to afford Mn(III)PcO2 is reversible [27]. The peculiar catalytic properties of The experimental conditions have a great influence on the equilibria between Mn(II) and Mn(III) Pcs, as well as on their oxygenated derivatives; under certain conditions, the oxygenation to afford Mn(III)PcO 2 is reversible [27]. The peculiar catalytic properties of such superoxide adducts have been reported many years ago, as it catalyzes the dioxygenation (with concomitant ring cleavage) of some indole derivatives [28]. Interestingly, the reaction is rather specific: 3-methyl-, 2,3-dimethyl-indole, and tryptophan are substrates, whereas plain indole, 1-methyl-, 2-methyl-, 1,2-dimethyl-, and 1,3-dimethyl-indole are not. In conclusion, a substituent must be present at the 3-position, whereas the 1-position must be unsubstituted, and the 2-position has not influence towards the susceptibility of the compound to the catalytic di-oxygenation reaction. When it happens, the di-oxygenation invariably affects the 2,3-bond, and in the case of the simplest substrate, 3-methyl-indole, the reaction product is 2-formamido-acetophenone. Although no detailed mechanism was proposed for the reaction, there is evidence that at the end of each catalytic cycle Mn(II)Pc must be obtained, which in turn reacts again with dioxygen to produce the reactive superoxide adduct.
The behaviour of the MnPcs to cycle between the two oxidation states of the central metal ion opened the way to a number of studies about the redox catalytic properties of the manganese complexes of variously substituted-and very often water-solublephthalocyanines. Moxon and colleagues [29] studied in detail the dioxygen adduct of symmetrical tetrasulfonated-Mn(II)Pc, and some of its changes upon pH variations. First of all, the solid adduct contains manganese(III) and superoxide. This arrangement changes upon dissolving the adduct in water, where it changes to a Mn(II) complex, binding dioxygen in a manner formally resembling oxymyoglobin and oxyhemoglobin. When pH is raised to >11, an intramolecular redox reaction takes place, and the Mn(III) adduct of superoxide is formed. At pH values > 14, the complex is reversibly destroyed with dioxygen evolution, but the process can be reversed by lowering the pH, for example to ∼3, where the Mn(II) is formed again, for which the authors have also claimed an H 2 O 2 -forming oxidase activity. These results form the background for further studies on the suitability of MnPcs as redox catalysts which be discussed in detail in Section 3.
Adducts arising from Fe(II)Pcs and O 2 must exist as reactive intermediates, very quickly evolving to stable products, namely the µ-oxo dimer of the type PcFe(III)-O-Fe(III)Pc. In relation to such a reactivity of the primary adduct, different FePcs under Catalysts 2021, 11, 122 6 of 36 different experimental conditions could participate as catalysts in a wide variety of aerobic oxidation or oxygenation reactions. Many years ago, Ercolani and colleagues [30], working on unsubstituted Fe(II)Pc, found that the putative O 2 -Fe(II)Pc complex, under suitable experimental conditions (toluene solution, high oxygen pressure), was able to catalyze the oxygenation of triphenylphosphine to the corresponding P-oxide. During the reaction, the insoluble Fe(III)-containing µ-oxo dimer slowly precipitated, with concomitant exhaustion of the catalysis. In the presence of two equivalents of pyridine, which promoted the formation of the soluble and catalytically very active Fe(II)(Py) 2 Pc complex, the efficiency increased, and for this reaction the authors proposed the formation of the transient ferryl species O=Fe(IV)(Py)Pc. However, also this complex slightly decomposed with formation of the µ-oxo dimer, but the excess of pyridine prevented the formation of the latter and consequent catalyst inactivation. Interestingly, under the same experimental conditions, both Mn(II)Pc and Co(II)Pc were found to be quite inactive, despite their ability to form dioxygen adducts.
Additionally, rather complicated is the chemistry of the CoPcs with O 2 , which in some cases requires the presence of H 2 O 2 to afford the adduct formation [31]; the formation of a transient O 2 − -Co(III)Pc adduct has been suggested for other "autoxidation" reactions [32]; the behavior of non-supported Co(II)Pcs to readily form Co(III) µ-peroxo dimers is a well-established fact, which can be prevented by proper axial coordination [33]. As a consequence of a mono-axial coordination, the O 2 -CoPc adducts become more efficient as oxidants. Of particular interest is the catalytic activity of Co(II)Pcs in aerobic oxidation of thiols to the corresponding disulfides, whose mechanism has been fully elucidated by Pan and coworkers (see Figure 16, as an example) [34]. The Co(II)Pc catalyst forms a ternary, bis-axial (octahedral) complex with the thiolate ion and dioxygen (the latter in the superoxide form, whereas the cobalt ion is in its +3 oxidation state). Then, a one-electron transfer to the cobalt(III) ion takes place, affording a thiyl radical RS • whereas the metal is reduced back to Co(II). This causes the release of superoxide anion, which in turns reacts very rapidly with another thiolate ion, leading finally to disulfide and H 2 O 2 as the reaction products.
As noted above, another crucial feature of MPcs containing redox-active metal ions such as Fe, Co, Mn, Ru, and others, is their ability, in particular when in their +3 oxidation state, to react with peroxo compounds or other oxygen donors such as iodosobenzene and iodibenzene derivatives [35]. More frequently, H 2 O 2 and its alky or acyl derivatives have been explored for their ability to form peroxo complexes or hypervalent derivatives of MPcs ( Figure 4). In principle, some compounds should be formed upon reaction of a suitable M(III)Pc with a generic hydroperoxide R-O-OH: (1) a Compound zero analogue, RO-O-M(III)Pc; (2) a Compound I analogue O=M(V)Pc ↔ µ O=M(IV)Pc •+ ↔ µ O • -M(IV)Pc; (3) a Compound II analogue O=M(IV)Pc ↔ µ O • -M(III)Pc. As noted above, the electron-withdrawing effect of the phthalocyanine ring is, generally speaking, stronger than that observed for its porphyrin counterpart, and as a consequence the above reported compounds are more reactive but also more unstable [17]. This explains why until now only a few examples have been isolated and characterized, such as the inert O=V(IV)Pc [36,37] and O=Nb(IV)Pc [38], contrarily to that observed in the case of the corresponding metalloporphyrin compounds [39][40][41][42][43][44]. Apart from the formal resemblance between the porphyrin and Pc series, some substantial differences can be observed between the two families of redox-active metal complexes [7]. In fact, several different mechanisms can operate, as a function of the particular MPc catalyst, of the chosen oxidant, and of the particular substrate to be oxidized. The system Fe(III)Pc-BuOOH could operate with a one-electron mechanism-starting from the homolytic scission of the peroxo bridge O-O-when oxidizing phenols to quinones, although it oxidizes to quinones some other substrates such as anthracene and xanthene with a two-electron mechanism (as a consequence of a heterolytic scission releasing OHand affording a very reactive hypervalent intermediate), as shown by the absence of oxidative coupling products, that are typical for one-electron (radical) mechanisms. On the other hand, the significant incorporation of 18 O from 18 O 2 along the oxidation of alkynes is a convincing proof of the radical mechanism. The reasons for such varying behavior of this and other MPc catalysts is still unknown. The propensity of Fe(III)Pc complexes to remain in the +3 oxidation state of the Compound 0 analogues has been assessed and discussed many years ago [45] and confirmed more recently [46]. In fact, the anionic form of such complexes, -O-O-Fe(III)Pc, is an effective nucleophile acting as an epoxidizing agent towards electron-deficient double bonds, incorporated into an aromatic ring, for example in polychlorophenols [47].
ate, as a function of the particular MPc catalyst, of the chosen oxidant, and of the particular substrate to be oxidized. The system Fe(III)Pc-BuOOH could operate with a one-electron mechanism-starting from the homolytic scission of the peroxo bridge O-O-when oxidizing phenols to quinones, although it oxidizes to quinones some other substrates such as anthracene and xanthene with a two-electron mechanism (as a consequence of a heterolytic scission releasing OHand affording a very reactive hypervalent intermediate), as shown by the absence of oxidative coupling products, that are typical for one-electron (radical) mechanisms. On the other hand, the significant incorporation of 18 O from 18 O2 along the oxidation of alkynes is a convincing proof of the radical mechanism. The reasons for such varying behavior of this and other MPc catalysts is still unknown. The propensity of Fe(III)Pc complexes to remain in the +3 oxidation state of the Compound 0 analogues has been assessed and discussed many years ago [45] and confirmed more recently [46]. In fact, the anionic form of such complexes, -O-O-Fe(III)Pc, is an effective nucleophile acting as an epoxidizing agent towards electron-deficient double bonds, incorporated into an aromatic ring, for example in polychlorophenols [47]. An outstanding feature of some MPcs is their high tendency to form μ-bridged dimers, where the two metal ions are linked together by -O-(oxo), -N= (nitrido) or also =C= (carbido) bridges [48]. Among these, diiron-oxo-bridged phthalocyanines have been deeply studied, mainly due to the easily preparation [7], as well as other binuclear complexes, containing different metal ions such as Ru, Cr, Mn, in different combinations (homo-or heterometallic) eventually hosted in the same Pc or in different Pcs (homo-or hetero-leptic complexes) [49]. In fact, when such a complex is treated with a peroxo compound, a Compound 0 analogue, involving only one Fe(III), is formed. This evolves preferentially to a Compound An outstanding feature of some MPcs is their high tendency to form µ-bridged dimers, where the two metal ions are linked together by -O-(oxo), -N= (nitrido) or also =C= (carbido) bridges [48]. Among these, diiron-oxo-bridged phthalocyanines have been deeply studied, mainly due to the easily preparation [7], as well as other binuclear complexes, containing different metal ions such as Ru, Cr, Mn, in different combinations (homo-or hetero-metallic) eventually hosted in the same Pc or in different Pcs (homo-or heteroleptic complexes) [49]. In fact, when such a complex is treated with a peroxo compound, a Compound 0 analogue, involving only one Fe(III), is formed. This evolves preferentially to a Compound I analogue, as the formal positive charge arising on the involved Fe ion is efficiently delocalized, through the µ-oxo bridge, on the other Fe ion. In this way, a O=Fe(IV)Pc-O-Fe(IV)Pc is formed, lacking both the radical cation character and the positive charge, inherent to the Compound I analogue arising from the monometallic counterpart [46]. As a consequence, the hypervalent oxo compound deriving from the binuclear complex represents the optimal balance between stability against auto-destruction and effectiveness of oxidation catalysis. In other words, the two-electron oxidation mechanism arising from the heterolytic cleavage of the -O-O-peroxo bridge in the binuclear complex affords selective oxidation pathways for many to-be-oxidized substrates, in contrast with the mononuclear counterpart, where the homolytic cleavage leads to radical mechanism with concomitant oxidant wasting and catalyst consumption. Unluckily, along the catalysis the binuclear complex could gradually decompose into the mononuclear species, therefore lowering the overall catalytic efficiency [46,50]. The immobilization of the binuclear complexes on to suitable insoluble supports could obviate to this drawback, when a reaction medium is chosen, unable to dissolve the formed mononuclear species.
The things go quite differently in the case of binuclear complexes where the two metal ions are linked by a nitrido bridge. In fact, these compounds, whose importance in catalysis of recalcitrant substrates oxidations is steadily increasing, show some useful features such as their noticeable operational stability along the catalytic cycle, and high effectiveness as oxidants for their hypervalent oxygenated derivatives ( Figure 5). In fact, a nitrido-diiron-phthalocyanine in its resting state is a mixed-valence compound showing a formal oxidation number of +3.5, PcFe(III)-N=Fe(IV)Pc ↔ µ PcFe(IV)=N-Fe(III)Pc. Upon reaction with H 2 O 2 , a ultra-high valent peroxo species arises: O=Fe(IV)Pc-N=Fe(IV)Pc ↔ µ O=Fe(IV)Pc +• -N=Fe(IV)Pc, passing through a peroxo complex, formally analogous to Compound 0, such as the ultra-high valent complex is the formal analogue of Compound I [46]. With time, the unprecedented, exceptional oxidizing catalytic power of µ-nitridobridged diiron complexes has been further explored, and such compounds are among the most promising oxidation and oxygenation catalysts for many practical applications, such as organic synthetic chemistry and degradation of recalcitrant pollutants. Outstanding examples are the controlled oxidation of methane at nearly ambient temperature and neutral pH [51] and the oxidative hydroxylation and dehalogenation of perfluoroaromatics [52], for which the reaction mechanism has been elucidated [53]. reaction with H2O2, a ultra-high valent peroxo species arises: O=Fe(IV)Pc-N=Fe(IV)Pc ↔ μ O=Fe(IV)Pc +• -N=Fe(IV)Pc, passing through a peroxo complex, formally analogous to Compound 0, such as the ultra-high valent complex is the formal analogue of Compound I [46]. With time, the unprecedented, exceptional oxidizing catalytic power of μ-nitridobridged diiron complexes has been further explored, and such compounds are among the most promising oxidation and oxygenation catalysts for many practical applications, such as organic synthetic chemistry and degradation of recalcitrant pollutants. Outstanding examples are the controlled oxidation of methane at nearly ambient temperature and neutral pH [51] and the oxidative hydroxylation and dehalogenation of perfluoroaromatics [52], for which the reaction mechanism has been elucidated [53]. In the next sections, special attention will be given to recent research concerning the catalytic activity of MPcs in the presence of O2 towards different substrates like thiophene and other mercaptans, alkyl arenes, alcohols, and olefins.

Thiols and Thiophenes
High activity, robustness, and the relative facile functionalization and immobilization of MPc in solid supports made these macrocycles excellent candidates for large scale industrial process catalysts. A paradigmatic example is the Merox ® Process (Mercaptan Oxidation) [54], an industrially important worldwide process used on the desulfurization of different petroleum fractions from various thiols. This process, also known as "sweetening" in the petroleum refining industry, typically comprises the use of catalysts based on Co(II)Pcs In the next sections, special attention will be given to recent research concerning the catalytic activity of MPcs in the presence of O 2 towards different substrates like thiophene and other mercaptans, alkyl arenes, alcohols, and olefins.

Thiols and Thiophenes
High activity, robustness, and the relative facile functionalization and immobilization of MPc in solid supports made these macrocycles excellent candidates for large scale industrial process catalysts. A paradigmatic example is the Merox ® Process (Mercaptan Oxidation) [54], an industrially important worldwide process used on the desulfurization of different petroleum fractions from various thiols. This process, also known as "sweetening" in the petroleum refining industry, typically comprises the use of catalysts based on Co(II)Pcs or other MPcs (e.g., Fe, Mn, Mo, or V) to oxidize the foul-smelling and corrosive mercaptans (thiols) into innocuous disulfides with dioxygen (Equation (1)). The MPc catalysts can be used either as a suspension in alkaline medium (sulfonated MPc) or supported on a composite (e.g., MPc catalysts impregnated on charcoal granulates as a solid support). pH [51] and the oxidative hydroxylation and dehalogenation of perfluoroaromatics [52], for which the reaction mechanism has been elucidated [53]. In the next sections, special attention will be given to recent research concerning the catalytic activity of MPcs in the presence of O2 towards different substrates like thiophene and other mercaptans, alkyl arenes, alcohols, and olefins.

Thiols and Thiophenes
High activity, robustness, and the relative facile functionalization and immobilization of MPc in solid supports made these macrocycles excellent candidates for large scale industrial process catalysts. A paradigmatic example is the Merox ® Process (Mercaptan Oxidation) [54], an industrially important worldwide process used on the desulfurization of different petroleum fractions from various thiols. This process, also known as "sweetening" in the petroleum refining industry, typically comprises the use of catalysts based on Co(II)Pcs or other MPcs (e.g., Fe, Mn, Mo, or V) to oxidize the foul-smelling and corrosive mercaptans (thiols) into innocuous disulfides with dioxygen (Equation (1)). The MPc catalysts can be used either as a suspension in alkaline medium (sulfonated MPc) or supported on a composite (e.g., MPc catalysts impregnated on charcoal granulates as a solid support). (1) Under the context of catalytic oxidative desulfurization (ODS), Zhou and coworkers [55] compared the efficiency of the three Fe(III) phthalocyanine catalysts, Fe(III)Pc(NO2)4, Fe(III)Pc(NO2)3NH2 and Fe(III)Pc(NH2)4, bearing nitro and amine substituents ( Figure 6) for the direct oxidation of dibenzothiophene (DBT), a well-known recalcitrant organosulfur compound. In the catalytic assays, the oxidation of DBT with dioxygen was performed in decalin as model fuel, under water-free conditions. The authors found that the catalytic activity of the Fe(III) Pcs decreases in the order Fe(III)Pc(NO2)4 > Fe(III)Pc(NO2)3NH2 > Fe(III)Pc(NH2)4, indicating that the presence of the electron-donating group has a negative effect on the catalytic performance. The aerobic oxidation of DBT into the corresponding sulfone in the presence of Fe(III)Pc(NO2)4 (1 wt%) at 100 °C and at O2 initial pressure of 0.3 MPa exhibited the highest conversion (98.7%) after 2 h of reaction, whereas the conversion of DBT catalyzed by Fe(III)Pc(NO2)3NH2 and Fe(III)Pc(NH2)4 was 87.8 and 64.1%, respectively. The Fe(III)Pc(NO2)4 efficiency was maintained after five runs (98.4%) and the inferior performance of Fe(III)Pc(NH2)4 was associated to its decomposition during the oxidation reactions (23.9% in the fifth run). However, when the catalyst Fe(III)Pc(NO2)3NH3 + was immobilized on resin D-113 (a microporous week acid polyacrylic cationic exchange resin), Figure 6, its activity was raised to the level of the best non-immobilized catalyst FePc(NO2)4.

(1)
Under the context of catalytic oxidative desulfurization (ODS), Zhou and coworkers [55] compared the efficiency of the three Fe(III) phthalocyanine catalysts, Fe(III)Pc(NO 2 ) 4 , Fe(III)Pc(NO 2 ) 3 NH 2 and Fe(III)Pc(NH 2 ) 4 , bearing nitro and amine substituents ( Figure 6) for the direct oxidation of dibenzothiophene (DBT), a well-known recalcitrant organosulfur compound. In the catalytic assays, the oxidation of DBT with dioxygen was performed in decalin as model fuel, under water-free conditions. The authors found that the catalytic activity of the Fe(III) Pcs decreases in the order Fe(III)Pc(NO 2 ) 4 > Fe(III)Pc(NO 2 ) 3 NH 2 > Fe(III)Pc(NH 2 ) 4 , indicating that the presence of the electron-donating group has a negative effect on the catalytic performance. The aerobic oxidation of DBT into the corresponding sulfone in the presence of Fe(III)Pc(NO 2 ) 4 (1 wt%) at 100 • C and at O 2 initial pressure of 0.3 MPa exhibited the highest conversion (98.7%) after 2 h of reaction, whereas the conversion of DBT catalyzed by Fe(III)Pc(NO 2 ) 3 NH 2 and Fe(III)Pc(NH 2 ) 4 was 87.8 and 64.1%, respectively. The Fe(III)Pc(NO 2 ) 4 efficiency was maintained after five runs (98.4%) and the inferior performance of Fe(III)Pc(NH 2 ) 4 was associated to its decomposition during the oxidation reactions (23.9% in the fifth run). However, when the catalyst Fe(III)Pc(NO 2 ) 3 NH 3 + was immobilized on resin D-113 (a microporous week acid polyacrylic cationic exchange resin), Figure 6, its activity was raised to the level of the best non-immobilized catalyst FePc(NO 2 ) 4 .
Catalysts 2021, 11, 122 9 of 36 version of DBT catalyzed by Fe(III)Pc(NO2)3NH2 and Fe(III)Pc(NH2)4 was 87.8 and 64.1%, respectively. The Fe(III)Pc(NO2)4 efficiency was maintained after five runs (98.4%) and the inferior performance of Fe(III)Pc(NH2)4 was associated to its decomposition during the oxidation reactions (23.9% in the fifth run). However, when the catalyst Fe(III)Pc(NO2)3NH3 + was immobilized on resin D-113 (a microporous week acid polyacrylic cationic exchange resin), Figure 6, its activity was raised to the level of the best non-immobilized catalyst FePc(NO2)4. Chen and coworkers [56] selected Fe(III)Pc(NO2)3NH2 to be covalently immobilized onto Carbon Fiber (Single-Walled Nanotubes, SWNT) and evaluated the catalytic efficiency of this heterogeneous catalytic system in the direct oxidation of DBT in tridecane with O2. The grafting of Fe(III)Pc(NO2)3NH2 in SWNT ( Figure 7) was performed using isoamyl nitrite as oxidizing agent in DMSO according with a modified literature method [57] that gave rise to a final load of 0.23 wt% of the Fe(III)Pc based on the iron content determined by atomic absorption spectroscopy. Chen and coworkers [56] selected Fe(III)Pc(NO 2 ) 3 NH 2 to be covalently immobilized onto Carbon Fiber (Single-Walled Nanotubes, SWNT) and evaluated the catalytic efficiency of this heterogeneous catalytic system in the direct oxidation of DBT in tridecane with O 2 . The grafting of Fe(III)Pc(NO 2 ) 3 NH 2 in SWNT ( Figure 7) was performed using isoamyl nitrite as oxidizing agent in DMSO according with a modified literature method [57] that gave rise to a final load of 0.23 wt% of the Fe(III)Pc based on the iron content determined by atomic absorption spectroscopy.  The new Fe(III)Pc(NO2)3@SWNT catalytic system exhibited a good catalytic performance with a conversion of DBT reaching 92% (vs. ~85% for FePc(NO2)4 and ~80% for Fe(III)Pc(NO2)3NH2) at 130 °C, 10 g/L of catalyst, under an initial O2 pressure of 0.2 MPa and after 3 h of reaction. The assays concerning the recyclability and reusability of the catalytic material showed a moderate decrease in DBT conversion from 92% (first cycle) into 78% (fourth cycle). In the catalytic oxidation of DBT to DBTO2 with O2 as oxidant, mediated by Fe(III)Pc(NO2)3@SWNT, the authors proposed the free radical high valent iron-oxo mechanism summarized in Figure 8; this proposal was supported by the absence of oxidized products (only traces of DBTO2 were detected) in reactions performed in the presence of a radical inhibitor, hydroquinone. The new Fe(III)Pc(NO 2 ) 3 @SWNT catalytic system exhibited a good catalytic performance with a conversion of DBT reaching 92% (vs.~85% for FePc(NO 2 ) 4 and~80% for Fe(III)Pc(NO 2 ) 3 NH 2 ) at 130 • C, 10 g/L of catalyst, under an initial O 2 pressure of 0.2 MPa and after 3 h of reaction. The assays concerning the recyclability and reusability of the catalytic material showed a moderate decrease in DBT conversion from 92% (first cycle) into 78% (fourth cycle). In the catalytic oxidation of DBT to DBTO 2 with O 2 as oxidant, mediated by Fe(III)Pc(NO 2 ) 3 @SWNT, the authors proposed the free radical high valent iron-oxo mechanism summarized in Figure 8; this proposal was supported by the absence of oxidized products (only traces of DBTO 2 were detected) in reactions performed in the presence of a radical inhibitor, hydroquinone.  Dibenzothiophene was also selected by Zhang and coworkers [58] as model compound to compare the catalytic activity of four cobalt phthalocyanines with 4, 8, 12, and 16 chlorine atoms present in the Co(II)Pc periphery. The results obtained in the presence of air, at room temperature, and using the 1-propylpyridinium tetrafluoroborate ((ProPy)(BF4)) ionic liquid as solvent showed that the catalytic activity increases in proportion to the number of chlorine atoms: Co(II)Pc(Cl)4 < Co(II)Pc(Cl)8 < Co(II)Pc(Cl)12 < Co(II)Pc(Cl)16. The 90.4% removal of DBT from the octane model fuel (vs. 18% for CoPc(Cl)4) in the presence of the most active catalyst CoPc(Cl)16 (Figure 9), after 2 h of reaction, merits to be emphasized since the reactions were performed at room temperature and at atmospheric pressure. These results indicated that the presence of electron-withdrawing group substituents has a positive impact on the Co(II)Pc catalytic performance. The study showed also that CoPc(Cl)16/(PorPy)(BF4) was able to be used five times without loss of activity (90.2% of DBT removal in the fifth run). The removal of other organosulfur compounds, namely thiophene (T), methylthiophene (MT), benzothiophene (BT), and 4,6-dimethyldibenzothiophene (4,6-DMDBT) by Co(II)Pc(Cl) 16 with air was also studied and the removal ratio decreases in the order T (100.0%) > DBT (90.4%) > BT (89.1%) > MT (81.9%) > 4,6-DMDBT (80%) at room temperature after 2 h. Another significant achievement for this desulfurization system was the decrease observed in the sulfur content from 1000 ppm to 30 ppm in the oxidation assays performed with CoPc(Cl)16 in a real matrix (gasoline). Dibenzothiophene was also selected by Zhang and coworkers [58] as model compound to compare the catalytic activity of four cobalt phthalocyanines with 4, 8, 12, and 16 chlorine atoms present in the Co(II)Pc periphery. The results obtained in the presence of air, at room temperature, and using the 1-propylpyridinium tetrafluoroborate ((ProPy)(BF 4 )) ionic liquid as solvent showed that the catalytic activity increases in proportion to the number of chlorine atoms: Co(II)Pc(Cl) 4 < Co(II)Pc(Cl) 8 < Co(II)Pc(Cl) 12 < Co(II)Pc(Cl) 16 . The 90.4% removal of DBT from the octane model fuel (vs. 18% for CoPc(Cl) 4 ) in the presence of the most active catalyst CoPc(Cl) 16 (Figure 9), after 2 h of reaction, merits to be emphasized since the reactions were performed at room temperature and at atmospheric pressure. These results indicated that the presence of electron-withdrawing group substituents has a positive impact on the Co(II)Pc catalytic performance. The study showed also that CoPc(Cl) 16 /(PorPy)(BF 4 ) was able to be used five times without loss of activity (90.2% of DBT removal in the fifth run). The removal of other organosulfur compounds, namely thiophene (T), methylthiophene (MT), benzothiophene (BT), and 4,6-dimethyldibenzothiophene (4,6-DMDBT) by Co(II)Pc(Cl) 16 with air was also studied and the removal ratio decreases in the order T (100.0%) > DBT (90.4%) > BT (89.1%) > MT (81.9%) > 4,6-DMDBT (80%) at room temperature after 2 h. Another significant achievement for this desulfurization system was the decrease observed in the sulfur content from 1000 ppm to 30 ppm in the oxidation assays performed with CoPc(Cl) 16 in a real matrix (gasoline).  Jain and coworkers [59] reported the preparation of the hybrid material Co(II)Pc(SO2Cl)3SO2NH@CF, obtained from poultry waste chicken feathers (CF) enriched with NH2 functionalities (NH2@CF) and the tetrasulfonylchloride cobalt(II) phthalocyanine (Co(II)Pc(SO2Cl)4), that was further evaluated as catalyst in the aerobic oxidation of a series of aliphatic and aromatic mercaptans under non alkaline conditions ( Figure  10; Table 1). Jain and coworkers [59] reported the preparation of the hybrid material Co(II)Pc(SO 2 Cl) 3 SO 2 NH@CF, obtained from poultry waste chicken feathers (CF) enriched with NH 2 functionalities (NH 2 @CF) and the tetrasulfonylchloride cobalt(II) phthalocyanine (Co(II)Pc(SO 2 Cl) 4 ), that was further evaluated as catalyst in the aerobic oxidation of a series of aliphatic and aromatic mercaptans under non alkaline conditions ( Figure 10; Table 1). The amino functionalities were introduced by reacting the powered poultry waste chicken feathers with 3-aminopropyltriethoxysilane (APTES) that, after reaction with the Co(II)Pc(SO2Cl)4 bearing sulfonyl chloride substituents, afforded the desired catalyst material. The authors verified that this material is able to selectively oxidize thiols to the corresponding disulfides (no evidence for the formation of the corresponding sulphonic acids) in yields ranging from 68-96%, using O2 atmosphere and ultrasonic irradiation at room temperature in DMF and in the absence of bases (Equation (2)). ( The results showed that the aromatic mercaptans were, in general, less reactive than the aliphatic ones and, among the aliphatic series, the reaction time was higher for those with longer chains. The study showed also that the immobilized catalyst presents a significantly higher catalytic activity towards thiophenol than the homogeneous counterpart (96 vs. 80% after 35 min) which was attributed to the synergistic effect of the support matrix. In addition, the authors demonstrated that the heterogeneous catalyst was easily recovered and recycled for five runs without loss of activity, since no leaching of the active Co(II)Pc catalyst was detected during the reactions.
The influence of fluorine atoms on the catalytic activity of CoPcs, towards mercaptans aerobic oxidation into disulfides in alkaline medium, was evaluated by Reid and Barat [60] in 2016. The experimental and kinetic studies were carried out in THF using 2-mercaptoethanol (2-ME) and 4-fluorobenzenethiol (4-FBT) as sulfur model substrates and The amino functionalities were introduced by reacting the powered poultry waste chicken feathers with 3-aminopropyltriethoxysilane (APTES) that, after reaction with the Co(II)Pc(SO 2 Cl) 4 bearing sulfonyl chloride substituents, afforded the desired catalyst material. The authors verified that this material is able to selectively oxidize thiols to the corresponding disulfides (no evidence for the formation of the corresponding sulphonic acids) in yields ranging from 68-96%, using O 2 atmosphere and ultrasonic irradiation at room temperature in DMF and in the absence of bases (Equation (2)). The amino functionalities were introduced by reacting the powered poultry waste chicken feathers with 3-aminopropyltriethoxysilane (APTES) that, after reaction with the Co(II)Pc(SO2Cl)4 bearing sulfonyl chloride substituents, afforded the desired catalyst material. The authors verified that this material is able to selectively oxidize thiols to the corresponding disulfides (no evidence for the formation of the corresponding sulphonic acids) in yields ranging from 68-96%, using O2 atmosphere and ultrasonic irradiation at room temperature in DMF and in the absence of bases (Equation (2)). ( The results showed that the aromatic mercaptans were, in general, less reactive than the aliphatic ones and, among the aliphatic series, the reaction time was higher for those with longer chains. The study showed also that the immobilized catalyst presents a significantly higher catalytic activity towards thiophenol than the homogeneous counterpart (96 vs. 80% after 35 min) which was attributed to the synergistic effect of the support matrix. In addition, the authors demonstrated that the heterogeneous catalyst was easily recovered and recycled for five runs without loss of activity, since no leaching of the active Co(II)Pc catalyst was detected during the reactions.
The influence of fluorine atoms on the catalytic activity of CoPcs, towards mercaptans aerobic oxidation into disulfides in alkaline medium, was evaluated by Reid and Barat [60] in 2016. The experimental and kinetic studies were carried out in THF using 2-mercaptoethanol (2-ME) and 4-fluorobenzenethiol (4-FBT) as sulfur model substrates and the cobalt(II) phthalocyanines Co(II)PcF16 and Co(II)PcF64 as the fluorinated homogeneous catalysts at 22 °C. The non-fluorinated Co(II)Pc was used for comparison ( Figure 11). The (2) The results showed that the aromatic mercaptans were, in general, less reactive than the aliphatic ones and, among the aliphatic series, the reaction time was higher for those with longer chains. The study showed also that the immobilized catalyst presents a significantly higher catalytic activity towards thiophenol than the homogeneous counterpart (96 vs. 80% after 35 min) which was attributed to the synergistic effect of the support matrix. In addition, the authors demonstrated that the heterogeneous catalyst was easily recovered and recycled for five runs without loss of activity, since no leaching of the active Co(II)Pc catalyst was detected during the reactions.
The influence of fluorine atoms on the catalytic activity of CoPcs, towards mercaptans aerobic oxidation into disulfides in alkaline medium, was evaluated by Reid and Barat [60] in 2016. The experimental and kinetic studies were carried out in THF using 2-mercaptoethanol (2-ME) and 4-fluorobenzenethiol (4-FBT) as sulfur model substrates and the cobalt(II) phthalocyanines Co(II)PcF 16 and Co(II)PcF 64 as the fluorinated homogeneous catalysts at 22 • C. The non-fluorinated Co(II)Pc was used for comparison ( Figure 11). The best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF 64 showing the fastest conversion, followed by Co(II)PcF 16 , and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF 64 catalyst, is also an important feature for its higher catalytic activity and stability. best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.   best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability. best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.   best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability. best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.   best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability. best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.   best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability. best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.   best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.  best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.  best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.   the cobalt(II) phthalocyanines Co(II)PcF16 and Co(II)PcF64 as the fluorinated homogeneous catalysts at 22 °C. The non-fluorinated Co(II)Pc was used for comparison ( Figure 11). The best performance, in terms of kinetic parameters and catalyst stability, was found for the fluorinated Co(II)PcF64 showing the fastest conversion, followed by Co(II)PcF16, and then by the non-substituted Co(II)Pc, thus confirming the positive effect driven by a higher Lewis acidity imposed by the fluorine atoms. The authors highlighted that the catalyst protection, imposed by the peripheral bulky isopropyl groups in the perfluorinated Co(II)PcF64 catalyst, is also an important feature for its higher catalytic activity and stability.   Vashurin and coworkers [61] compared the catalytic activity of several cobalt(II) phthalocyanines Co(II)Pc(XC 6 H 4 CO 2 H) 4 R 4 ( Figure 12) on the oxidation of sodium N,Ndiethyldithiocarbamate (DTC) at pH 11 and 25 • C (Equation (3)). Vashurin and coworkers [61] compared the catalytic activity of several cobalt(II) phthalocyanines Co(II)Pc(XC6H4CO2H)4R4 ( Figure 12) on the oxidation of sodium N,Ndiethyldithiocarbamate (DTC) at pH 11 and 25 °C (Equation (3)).

(3)
The kinetic studies of the difunctional CoPcs, a) bearing nitro groups combined with 4amino, 4-hydroxyl and 4-sulfanyl benzoic acid substituents (Co(II)Pc(XC6H4CO2H)4(NO2)4, X=O,S,NH), or b) containing just the 4-substituted benzoic acid as substituents (Co(II)Pc(XC6H4CO2H)4(XABz)4, X=O,S,NH) for DTC oxidation revealed a structure-activity relationship. The differences observed on the catalytic activity were attributed to the nature of the heteroatom (NH; S; O) on the phthalocyanine peripheral substituents. The introduction of electron-acceptor groups in the periphery of the phthalocyanine molecule led to an increase in catalytic activity. Following an analogous approach, the same research group [62] prepared the sulfonated water soluble complexes Co(II)PcS4(NO2)4 or Co(II)PcS8 and Cu(II)PcS4(NO2)4 or Cu(II)PcS8 ( Figure 13) and evaluated their catalytic activity, with O2 as oxidant, and sodium N,N-diethyldithiocarbamate (DTC) as substrate (Equation (3)). The highest activity was achieved for Co(II) complexes, particularly the octasulfonic phthalocyanine Co(II)PcS8, that was the most active catalyst. The authors explained this difference with sterical effects of peripheral substituents and aggregation phenomena. The octasulfonated bulky substituents present in both peripheric positions of Co(II)PcS8 reduces the aggregation that will be higher on the tetrasulfonated counterpart (Co(II)PcS4(NO2)4).  The kinetic studies of the difunctional CoPcs, (a) bearing nitro groups combined with 4amino, 4-hydroxyl and 4-sulfanyl benzoic acid substituents (Co(II)Pc(XC 6 H 4 CO 2 H) 4 (NO 2 ) 4 , X=O,S,NH), or (b) containing just the 4-substituted benzoic acid as substituents (Co(II)Pc (XC 6 H 4 CO 2 H) 4 (XABz) 4, X=O,S,NH) for DTC oxidation revealed a structure-activity relationship. The differences observed on the catalytic activity were attributed to the nature of the heteroatom (NH; S; O) on the phthalocyanine peripheral substituents. The introduction of electron-acceptor groups in the periphery of the phthalocyanine molecule led to an increase in catalytic activity. Vashurin and coworkers [61] compared the catalytic activity of several cobalt(II) phthalocyanines Co(II)Pc(XC6H4CO2H)4R4 ( Figure 12) on the oxidation of sodium N,Ndiethyldithiocarbamate (DTC) at pH 11 and 25 °C (Equation (3)).

(3)
The kinetic studies of the difunctional CoPcs, a) bearing nitro groups combined with 4amino, 4-hydroxyl and 4-sulfanyl benzoic acid substituents (Co(II)Pc(XC6H4CO2H)4(NO2)4, X=O,S,NH), or b) containing just the 4-substituted benzoic acid as substituents (Co(II)Pc(XC6H4CO2H)4(XABz)4, X=O,S,NH) for DTC oxidation revealed a structure-activity relationship. The differences observed on the catalytic activity were attributed to the nature of the heteroatom (NH; S; O) on the phthalocyanine peripheral substituents. The introduction of electron-acceptor groups in the periphery of the phthalocyanine molecule led to an increase in catalytic activity.  Following an analogous approach, the same research group [62] prepared the sulfonated water soluble complexes Co(II)PcS4(NO2)4 or Co(II)PcS8 and Cu(II)PcS4(NO2)4 or Cu(II)PcS8 ( Figure 13) and evaluated their catalytic activity, with O2 as oxidant, and sodium N,N-diethyldithiocarbamate (DTC) as substrate (Equation (3)). The highest activity was achieved for Co(II) complexes, particularly the octasulfonic phthalocyanine Co(II)PcS8, that was the most active catalyst. The authors explained this difference with sterical effects of peripheral substituents and aggregation phenomena. The octasulfonated bulky substituents present in both peripheric positions of Co(II)PcS8 reduces the aggregation that will be higher on the tetrasulfonated counterpart (Co(II)PcS4(NO2)4). Following an analogous approach, the same research group [62] prepared the sulfonated water soluble complexes Co(II)PcS 4 (NO 2 ) 4 or Co(II)PcS 8 and Cu(II)PcS 4 (NO 2 ) 4 or Cu(II)PcS 8 ( Figure 13) and evaluated their catalytic activity, with O 2 as oxidant, and sodium N,N-diethyldithiocarbamate (DTC) as substrate (Equation (3)). The highest activity was achieved for Co(II) complexes, particularly the octasulfonic phthalocyanine Co(II)PcS 8 , that was the most active catalyst. The authors explained this difference with sterical effects of peripheral substituents and aggregation phenomena. The octasulfonated bulky substituents present in both peripheric positions of Co(II)PcS 8 reduces the aggregation that will be higher on the tetrasulfonated counterpart (Co(II)PcS 4 (NO 2 ) 4 ).  In 2017, Kimura and coworkers [63] reported the synthetic access to the two 3D network polymers Zn(II)PcPoly1,2 and Co(II)PcPoly1,2 ( Figure 14) containing Zn(II) or Co(II) phthalocyanines interconnected with twisted 9,9 -spirobifluorene linkers and evaluated their catalytical performance in the aerobic oxidation of thiols. The results obtained in the polymers characterization were compared with those obtained from M(II)Pc-dimer1 and M(II)Pc-dimer2 used as prototypes of component units of M(II)Pc network ( Figure 15).  For instance, from XRD and N2 adsorption and desorption techniques it was disclosed that the condensation of the twisted 9,9′-spirobifluorene linkers in the presence of zinc or cobalt ions established smaller cavities in the new polymeric materials, that showed to be important on their catalytic activities towards RSH oxidations. Although both polymers exhibited catalytic activity for RSH oxidations, the catalytic activity of polymer M(II)PcPoly-1, containing rigid and small cavities, was higher than that of M(II)PcPoly-2 having larger cavities. This higher catalytic activity was associated to an easier substrate diffusion in M(II)PcPoly-1 when compared with M(II)PcPoly-2. It would be also interesting and insightful to compare the catalytic activities of polymer networks M(II)PcPoly-1 and M(II)PcPoly-2 with the corresponding M(II)Pc-dimer-1 and M(II)Pc-dimer-2, however the authors did not accomplish further comparative studies.

Co(II)Pc(OC 6 H 4 CO 2 H) 4 (OABz) 4 ; X = O Co(II)Pc(SC 6 H 4 CO 2 H) 4 (SABz) 4 ; X = S Co(II)Pc(NHC 6 H 4 CO 2 H) 4 (NHABz) 4 ; X = NH
Kang and coworkers [64] reported that the Fe(II)Pc ( Figure 2) under optimized conditions (THF, room temperature, atmospheric O2) is able to oxidize efficiently a series of thiols to the corresponding disulfides (Equation (2)). Under the context of the oxidation of For instance, from XRD and N 2 adsorption and desorption techniques it was disclosed that the condensation of the twisted 9,9 -spirobifluorene linkers in the presence of zinc or cobalt ions established smaller cavities in the new polymeric materials, that showed to be important on their catalytic activities towards RSH oxidations. Although both polymers exhibited catalytic activity for RSH oxidations, the catalytic activity of polymer M(II)PcPoly-1, containing rigid and small cavities, was higher than that of M(II)PcPoly-2 having larger cavities. This higher catalytic activity was associated to an easier substrate dif-fusion in M(II)PcPoly-1 when compared with M(II)PcPoly-2. It would be also interesting and insightful to compare the catalytic activities of polymer networks M(II)PcPoly-1 and M(II)PcPoly-2 with the corresponding M(II)Pc-dimer-1 and M(II)Pc-dimer-2, however the authors did not accomplish further comparative studies.
Kang and coworkers [64] reported that the Fe(II)Pc ( Figure 2) under optimized conditions (THF, room temperature, atmospheric O 2 ) is able to oxidize efficiently a series of thiols to the corresponding disulfides (Equation (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (  thiols to the corresponding disulfides (Equation (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B).  (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B). thiols to the corresponding disulfides (Equation (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B).  (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B). thiols to the corresponding disulfides (Equation (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B).  (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B). thiols to the corresponding disulfides (Equation (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B).  (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B). thiols to the corresponding disulfides (Equation (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B).  (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents (  (4)).

(4)
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B).       The same complex Fe(II)Pc have been also explored on cross-dehydrogenative coupling (CDC) with H-phosphonates and H-phoshine oxides (Equation (4)).
Kang and coworkers [64] reported that the Fe(II)Pc (Figure 2) under optimized conditions (THF, room temperature, atmospheric O2) is able to oxidize efficiently a series of thiols to the corresponding disulfides (Equation (2)). Under the context of the oxidation of thiols to disulfides, the results showed that the efficiency was not affected by the presence of electron-donating or electron-deficient substituents either in benzyl (Table 2, Entries 1, 2 and 3) or in aromatic mercaptans (Table 2, Entries 4, 5 and 6). Moreover, excellent conversions were obtained with mercaptans bearing bulky substituents ( Table 2, entry 7) and with aliphatic mercaptans ( Table 2, entry 8).
The same complex Fe(II)Pc have been also explored on cross-dehydrogenative coupling (CDC) with H-phosphonates and H-phoshine oxides (Equation (4)).
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 °C in the presence of a base (e.g., NH3; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B).
The cross-dehydrogenative coupling (CDC) of thiols with H-phosphonates (Equation (4)), mediated by the same catalyst, was performed at 60 • C in the presence of a base (e.g., NH 3 ; 1,8-diazabicyclo [5.4.0]undec-7-ene, DBU or diisopropylamine, DIPA). The best base for these cross-coupling reactions was DIPA (yields between 45 and 90%, Table 3) and the control experiments revealed that this oxidative coupling seems to follow the free radical pathway indicated in Figure 16 (Path A and B).                              Solid base catalysts obtained from the noncovalent attachment of the tetrasulfonated cobalt(II) phthalocyanine Co(II)Pc(SO 3 H) 4 to graphene oxide (GO) functionalized with different amines, namely propylamine (PA), butylamine (BA), ethylenediamine (EDA) and tetramethylenediamine (TMD) (Figure 17) were evaluated and compared in the oxidation of various thiols [65]. The catalytic performance in the oxidation of various thiols was evaluated in heptane without base addition. The catalytic efficiency was dependent on the functionalized amine GO (Co(II)Pc@GOEDA > Co(II)Pc@GOTMD > Co(II)Pc@GOPA > Co(II)Pc@GOBA) and the potentiality of the best material Co(II)Pc@GOEDA was investigated in the oxidation of thiols present in a real matrix like gasoline. The results were really promising with the removal of 96.6% of the thiols and after eight runs no significant change was observed in the Co(II)Pc@GOEDA activity used in real context.  (Figure 17) were evaluated and compared in the oxidation of various thiols [65]. The catalytic performance in the oxidation of various thiols was evaluated in heptane without base addition. The catalytic efficiency was dependent on the functionalized amine GO (Co(II)Pc@GOEDA > Co(II)Pc@GOTMD > Co(II)Pc@GOPA > Co(II)Pc@GOBA) and the potentiality of the best material Co(II)Pc@GOEDA was investigated in the oxidation of thiols present in a real matrix like gasoline. The results were really promising with the removal of 96.6% of the thiols and after eight runs no significant change was observed in the Co(II)Pc@GOEDA activity used in real context. Considering the importance of developing alternatives to the drastic conditions used in Merox ® process (high pressure and temperature, presence of caustic soda), Omadoko and coworkers [66] found that Co(II) complex of the sodium salt of tetrasulfonated phthalocyanine (Co(II)Pc(SO3Na)4) ( Figure 18) is able to fully oxidize ethanethiol to diethyl disulfide, under base free conditions, in O2 saturated dimethylformamide (DMF) after 10 min at 40 °C with a turnover number (TON) of 72 and turnover frequency (TOF) of 8.1 min −1 . Considering the importance of developing alternatives to the drastic conditions used in Merox ® process (high pressure and temperature, presence of caustic soda), Omadoko and coworkers [66] found that Co(II) complex of the sodium salt of tetrasulfonated phthalocyanine (Co(II)Pc(SO 3 Na) 4 ) ( Figure 18) is able to fully oxidize ethanethiol to diethyl disulfide, under base free conditions, in O 2 saturated dimethylformamide (DMF) after 10 min at 40 • C with a turnover number (TON) of 72 and turnover frequency (TOF) of 8.1 min −1 .  Figure 18) and the non-substituted Co(II)Pc ( Figure 2) were also evaluated. The results showed that Cu(II)Pc(SO3Na)4 has no catalytic activity, while Co(II)Pc(SO3Na)4, had the highest turnover number (8.1 min −1 ), followed by Co(II)Pc and Fe(II)Pc(SO3Na)4. These results demonstrated that the metal centers showed a higher impact on catalytic activity than peripheral substituents.

In addition to Co(II)Pc(SO3Na)4, in this study the efficiency of the analogues Fe(II)Pc(SO3Na)4 and Cu(II)Pc(SO3Na)4 (
The monitorization of the reaction by UV-Vis spectroscopy suggested that the oxidation step occurs with both thiol units coordinated to the M(II)Pc, followed by the disulfide dissociation from the catalyst, mediated by DMF.
Another interesting contribution concerning the desulfurization of real fuel matrixes such as gasoline and diesel was reported in 2019 by Li and coworkers [67]. The authors found that the hybrid assembly constituted by the tetramer (Co(II)Pc)4 ( Figure 19) and the polyoxometalate (NH4)5H6PV8Mo4O40 (PMoV) is an efficient hybrid to perform the oxidative desulfurization of model oils containing dibenzothiophene (DBT), 4,6-dimethyldibenzothiophene (4,6-DMDBT), benzothiophene (BT) and thiophene (T) to the sulphones under aerobic conditions. Conversions of almost 100% were found for DBT and 4,6-DMDBT and 97.6% for T with TOFs of 24.31, 48.89, 34.83, 23.77 h −1 , respectively. The solubility features of the hybrid assembly obtained by mixing both components, the (Co(II)Pc)4 and the polyoxometalate in THF showed to be dependent on the molar ratio used; a 1:7 ratio (Co(II)Pc)4:PMoV gave rise to a solid insoluble in water and decaline hybrid (I), while a ratio 4:1 (Co(II)Pc)4:PMoV afforded a hybrid soluble in water hybrid (II). The efficiency of the hybrid (I) was maintained in the desulfurization of real matrix such as gasoline and diesel affording sulfur contents (2.73 and 8.01 ppm at 7 h, respectively) on line with the required European level of 10 ppm.
In addition to Co(II)Pc(SO 3 Na) 4 , in this study the efficiency of the analogues Fe(II)Pc (SO 3 Na) 4 and Cu(II)Pc(SO 3 Na) 4 ( Figure 18) and the non-substituted Co(II)Pc ( Figure 2) were also evaluated. The results showed that Cu(II)Pc(SO 3 Na) 4 has no catalytic activity, while Co(II)Pc(SO 3 Na) 4 , had the highest turnover number (8.1 min −1 ), followed by Co(II)Pc and Fe(II)Pc(SO 3 Na) 4 . These results demonstrated that the metal centers showed a higher impact on catalytic activity than peripheral substituents.
The monitorization of the reaction by UV-Vis spectroscopy suggested that the oxidation step occurs with both thiol units coordinated to the M(II)Pc, followed by the disulfide dissociation from the catalyst, mediated by DMF.
Another interesting contribution concerning the desulfurization of real fuel matrixes such as gasoline and diesel was reported in 2019 by Li and coworkers [67]. The authors found that the hybrid assembly constituted by the tetramer (Co(II)Pc) 4 ( Figure 19) and the polyoxometalate (NH 4 ) 5 H 6 PV 8 Mo 4 O 40 (PMoV) is an efficient hybrid to perform the oxidative desulfurization of model oils containing dibenzothiophene (DBT), 4,6-dimethyldibenzothiophene (4,6-DMDBT), benzothiophene (BT) and thiophene (T) to the sulphones under aerobic conditions. Conversions of almost 100% were found for DBT and 4,6-DMDBT and 97.6% for T with TOFs of 24.31, 48.89, 34.83, 23.77 h −1 , respectively. The solubility features of the hybrid assembly obtained by mixing both components, the (Co(II)Pc) 4 and the polyoxometalate in THF showed to be dependent on the molar ratio used; a 1:7 ratio (Co(II)Pc) 4 :PMoV gave rise to a solid insoluble in water and decaline hybrid (I), while a ratio 4:1 (Co(II)Pc) 4 :PMoV afforded a hybrid soluble in water hybrid (II). The efficiency of the hybrid (I) was maintained in the desulfurization of real matrix such as gasoline and diesel affording sulfur contents (2.73 and 8.01 ppm at 7 h, respectively) on line with the required European level of 10 ppm.  The stability of hybrid (I), associated with the possibility of being reused, at least nine times in organic solvent or in aqueous solutions, without significant loss of activity and no leaching of active sites confirmed the heterogeneous features of the assembly. The authors pointed out that the collaboration of multiple active sites in one combined unit can achieve high efficiency in aerobic heterogeneous catalysis.
Under the context of thiol oxidation in fuels, Makarov, Wörhle, and coworkers [68] developed a catalyst with high catalytic activity and stability, based on a new binuclear Co(II) phthalocyanine bisCo(II)Pc-2 with an extended π-system and functionalized with 2,6-dimethylphenoxy groups ( Figure 20). For comparison, the study was extended to the mononuclear Co(II) phthalocyanine Co(II)Pc-1 ( Figure 20) also with electron donating phenoxy groups. The binuclear (bisZn(II)Pc-2) and mononuclear (Zn(II)Pc-1) Zn(II) phthalocyanine were also considered for these studies as redox-inactive complexes.
The catalytic studies, using 2-mercaptoethanol (2-ME) as the substrate at 25 °C under O2 demonstrated a remarkable increase in the efficiency of the oxidative process going from the mononuclear Co(II)Pc-1 to the binuclear bisCo(II)Pc-2 Co(II) phthalocyanine complexes; an extremely high value for TOF of ~9000 min −1 was provided by the binuclear complex bisCo(II)Pc-2 versus 250 min −1 for the mononuclear Co(II)Pc-1. On the other hand, authors found negligible catalytic activities of Zn(II)Pc-1 and bisZn(II)Pc-2. The result was expected since Zn(II) is a closed-shell transition metal. Considering the mechanism of thiol oxidation mediated by a mononuclear Co(II)Pc-1 (Figure 20), an explanation for the high activity of the binuclear Co(II)-complex (bisCo(II)Pc-2) relies on a favorable electronic contact between the two cobalt centres through the extended π-electron system that facilitates the electron transfer from thiolate to oxygen. The stability of hybrid (I), associated with the possibility of being reused, at least nine times in organic solvent or in aqueous solutions, without significant loss of activity and no leaching of active sites confirmed the heterogeneous features of the assembly. The authors pointed out that the collaboration of multiple active sites in one combined unit can achieve high efficiency in aerobic heterogeneous catalysis.
Under the context of thiol oxidation in fuels, Makarov, Wörhle, and coworkers [68] developed a catalyst with high catalytic activity and stability, based on a new binuclear Co(II) phthalocyanine bisCo(II)Pc-2 with an extended π-system and functionalized with 2,6-dimethylphenoxy groups ( Figure 20). For comparison, the study was extended to the mononuclear Co(II) phthalocyanine Co(II)Pc-1 ( Figure 20) also with electron donating phenoxy groups. The binuclear (bisZn(II)Pc-2) and mononuclear (Zn(II)Pc-1) Zn(II) phthalocyanine were also considered for these studies as redox-inactive complexes.

Alkyl Arenes and Alcohols
The oxidation of alkyl arenes and alcohols to their corresponding carbonyl compounds is of significant importance in organic chemistry [69]. The manufacturing of bulk carbonyl compounds, such as benzoic acid, terephthalic acid, and isophthalic acid, comprises the aerobic oxidation of alkyl arenes and alcohols. These processes are usually conducted under harsh reaction conditions: high temperatures (175-225 °C) and high air pressures (15-30 atm) in the presence of metal catalysts such as Co(OAc)2/Mn(OAc)2 and bromine, typically in the form of HBr, NaBr or tetrabromoethane in acetic acid [70].
Over the last years, research efforts have been devoted to the development of smooth oxidation reaction conditions. In this context, MPcs have emerged as an attractive and powerful alternative as efficient catalytic materials since they play a unique role in the catalytic activation of O2 as was demonstrated above [7]. In addition, and as mentioned above, MPcs are remarkable versatile and robust compounds with improved thermal and chemical stability, which allied with the low cost and availability become their use very attractive [71].
Shaabani and coworkers [72] compared the efficiency of a series of MPc: Co(II)Pc, Cu(II)Pc, Ni(II)Pc, Ru(II)Pc, Pd(II)Pc, Zn(II)Pc (Figure 2), in the aerobic conversion of fluorene to 9-fluorenone and benzoin to benzil (Figure 21) in different ionic liquids (ILs). In both cases the best results were obtained with Co(II)Pc in the presence of 1-butyl-3methylimidazolium bromide (bmim)Br but different temperatures were required; the optimal temperature for the oxidation of fluorenone was 100 °C (91% yield, 6 h of reaction) The catalytic studies, using 2-mercaptoethanol (2-ME) as the substrate at 25 • C under O 2 demonstrated a remarkable increase in the efficiency of the oxidative process going from the mononuclear Co(II)Pc-1 to the binuclear bisCo(II)Pc-2 Co(II) phthalocyanine complexes; an extremely high value for TOF of~9000 min −1 was provided by the binuclear complex bisCo(II)Pc-2 versus 250 min −1 for the mononuclear Co(II)Pc-1. On the other hand, authors found negligible catalytic activities of Zn(II)Pc-1 and bisZn(II)Pc-2. The result was expected since Zn(II) is a closed-shell transition metal. Considering the mechanism of thiol oxidation mediated by a mononuclear Co(II)Pc-1 (Figure 20), an explanation for the high activity of the binuclear Co(II)-complex (bisCo(II)Pc-2) relies on a favorable electronic contact between the two cobalt centres through the extended π-electron system that facilitates the electron transfer from thiolate to oxygen.

Alkyl Arenes and Alcohols
The oxidation of alkyl arenes and alcohols to their corresponding carbonyl compounds is of significant importance in organic chemistry [69]. The manufacturing of bulk carbonyl compounds, such as benzoic acid, terephthalic acid, and isophthalic acid, comprises the aerobic oxidation of alkyl arenes and alcohols. These processes are usually conducted under harsh reaction conditions: high temperatures (175-225 • C) and high air pressures (15-30 atm) in the presence of metal catalysts such as Co(OAc) 2 /Mn(OAc) 2 and bromine, typically in the form of HBr, NaBr or tetrabromoethane in acetic acid [70].
Over the last years, research efforts have been devoted to the development of smooth oxidation reaction conditions. In this context, MPcs have emerged as an attractive and powerful alternative as efficient catalytic materials since they play a unique role in the catalytic activation of O 2 as was demonstrated above [7]. In addition, and as mentioned above, MPcs are remarkable versatile and robust compounds with improved thermal and chemical stability, which allied with the low cost and availability become their use very attractive [71].
Shaabani and coworkers [72] compared the efficiency of a series of MPc: Co(II)Pc, Cu(II)Pc, Ni(II)Pc, Ru(II)Pc, Pd(II)Pc, Zn(II)Pc (Figure 2), in the aerobic conversion of fluorene to 9-fluorenone and benzoin to benzil ( Figure 21) in different ionic liquids (ILs). In both cases the best results were obtained with Co(II)Pc in the presence of 1-butyl-3-methylimidazolium bromide (bmim)Br but different temperatures were required; the optimal temperature for the oxidation of fluorenone was 100 • C (91% yield, 6 h of reaction) and for benzoin was 70 • C (92% yield, 1 h of reaction). The scope of this approach was extended to other primary and secondary benzylic hydrocarbons and alcohols affording the expected carbonyl products in excellent yields (between ca. 80 and 93%) confirming the versatility and the efficiency of the combination. under mild conditions. Interestingly, the oxidation of the primary alcohols gave rise to aldehydes and not to carboxylic acids. The study showed also that both the (bmim)Br and the Co(II)Pc could be reused at least six times in consecutive runs without affecting the yield of the products.  The authors suggest that the reaction occurs trough the removal of hydrogen from the carbon attached to the hydroxyl group in alcohols, and from the benzylic position in the alkyl arenes by the superoxocobalt(III) species as summarized in Figure 22.
The efficiency of the heterogeneous catalyst Co(II)Pc(NH2)3NH@Cel ( Figure 23) obtained from cellulose and the cobalt(II) complex of the tetraaminophthalocyanine derivative Co(II)Pc(NH2)4 was also considered by the same group [73] in the aerobic oxidation of alkyl arenes and alcohols.
The immobilization of Co(II)Pc(NH2)4 via amino groups required the previous activation of the cellulose primary hydroxyl groups with tosyl chloride (TosCl) and a metallophthalocyanine loading of 0.36 wt% was attained. The oxidation of the alkyl arenes mediated by Co(II)Pc(NH2)3NH@Cel was performed in refluxing o-xylene under an O2 atmosphere and in the presence of KOH and N-hydroxyphthalimide (NHPI). Under these conditions, the expected ketones were obtained in excellent yields (82 to 91%). The oxidation of aliphatic, aromatic and allylic primary and secondary alcohols was also performed in o-xylene but, in this case, at room temperature and in the absence of NHPI; the corresponding aldehydes and ketones were obtained in yields ranging from 78 to 90%. The studies showed that the catalyst can be readily recovered from the reaction mixture and reused for several runs without a significant decrease in its catalytic activity. The authors suggest that the reaction occurs trough the removal of hydrogen from the carbon attached to the hydroxyl group in alcohols, and from the benzylic position in the alkyl arenes by the superoxocobalt(III) species as summarized in Figure 22.
The efficiency of the heterogeneous catalyst Co(II)Pc(NH 2 ) 3 NH@Cel (Figure 23) obtained from cellulose and the cobalt(II) complex of the tetraaminophthalocyanine derivative Co(II)Pc(NH 2 ) 4 was also considered by the same group [73] in the aerobic oxidation of alkyl arenes and alcohols.
The immobilization of Co(II)Pc(NH 2 ) 4 via amino groups required the previous activation of the cellulose primary hydroxyl groups with tosyl chloride (TosCl) and a metallophthalocyanine loading of 0.36 wt% was attained. The oxidation of the alkyl arenes mediated by Co(II)Pc(NH 2 ) 3 NH@Cel was performed in refluxing o-xylene under an O 2 atmosphere and in the presence of KOH and N-hydroxyphthalimide (NHPI). Under these conditions, the expected ketones were obtained in excellent yields (82 to 91%). The oxidation of aliphatic, aromatic and allylic primary and secondary alcohols was also performed in o-xylene but, in this case, at room temperature and in the absence of NHPI; the corresponding aldehydes and ketones were obtained in yields ranging from 78 to 90%. The studies showed that the catalyst can be readily recovered from the reaction mixture and reused for several runs without a significant decrease in its catalytic activity. Proposed mechanism for akyl arenes and alcohols aerobic oxidation (adapted from [72]). Figure 22. Proposed mechanism for akyl arenes and alcohols aerobic oxidation (adapted from [72]).  The catalyst containing 12% w/w of M(II)Pc immobilized in GO (Fe(II)Pc(NO2)3S@GO) was evaluated in the oxidation of benzyl alcohol into benzaldehyde (97% of conversion; selectivity > 99%) in water and at 60 °C throughout 3 h in the presence of 0.4 mmol% of the catalyst and 50 mmol% of K2CO3. High conversion (90-97%) and high selectivity (96-99%) towards the carbonyl compounds (aldehydes or ketones) were also attained when the scope of the reaction, under the same conditions, was extended to a variety of primary and secondary aliphatic and aromatic alcohols. Moreover, after six runs no significant loss of activity and selectivity was found for the Fe(II)Pc(NO2)3S@GO catalyst. The catalyst containing 12% w/w of M(II)Pc immobilized in GO (Fe(II)Pc(NO 2 ) 3 S@GO) was evaluated in the oxidation of benzyl alcohol into benzaldehyde (97% of conversion; selectivity > 99%) in water and at 60 • C throughout 3 h in the presence of 0.4 mmol% of the catalyst and 50 mmol% of K 2 CO 3 . High conversion (90-97%) and high selectivity (96-99%) towards the carbonyl compounds (aldehydes or ketones) were also attained when the scope of the reaction, under the same conditions, was extended to a variety of primary and secondary aliphatic and aromatic alcohols. Moreover, after six runs no significant loss of activity and selectivity was found for the Fe(II)Pc(NO 2 ) 3 S@GO catalyst. Chauhan and Yan [75] reported the preparation and evaluation of an efficient catalyst, a copper tetrasulfonate phthalocyanine (tetrasodium salt) Cu(II)Pc(SO3Na)4 immobilized through electrostatic interaction on a quaternary amine functionalized nanocrystalline cellulose (NCCel) (Figure 26). Chauhan and Yan [75] reported the preparation and evaluation of an efficient catalyst, a copper tetrasulfonate phthalocyanine (tetrasodium salt) Cu(II)Pc(SO 3 Na) 4 immobilized through electrostatic interaction on a quaternary amine functionalized nanocrystalline cellulose (NCCel) (Figure 26). The hybrid material Cu(II)Pc(SO3 -)4@NCCel has been employed as catalyst in the aerobic oxidation of alcohols and alkyl arenes in water. Under optimal catalytic conditions (0.004 mol% Cu(II) content, at room temperature), conversions of 99% for benzyl alcohol and 92% for tetralin were attained with excellent selectivity in both cases (selectivity > 99%) for the expected carbonyl derivatives (benzaldehyde and tetralone). After 7 cycles, a minor decrease in product yield was observed, thus indicating high stability of the catalyst. Jain and collaborators [76] selected polyaniline (PANI) to covalently graft the Co(II)Pc(SO2Cl)4 catalyst through the activated sulfonyl chloride units ( Figure 27) and the efficiency of the obtained hybrid Co(II)Pc(SO2Cl)3SO2@PANI was assessed in the aerobic oxidation of alcohols.
The best performance for the oxidation of benzhydrol (diphenylmethanol), selected as the model substrate, was found in the assays taken in acetonitrile at 65 °C and in the presence isobutyraldehyde as sacrificial agent. After 3.5 h, benzophenone was obtained with the best yield (76%) and the best TOF (21.7 h −1 ). This efficiency was maintained or even increased when the reaction scope was enlarged to the oxidation of a variety of primary and secondary alcohols (e.g., furfuryl alcohol, cyclohexanol, benzyl alcohol substituted with electron-donating or electron-withdrawing substituents, 1-phenylethanol, octan-1-ol), selectively affording the corresponding carbonyl compounds in good yields (72-88%) without any overoxidation product. The catalyst was found to be highly stable and could be reused for several runs (six times) without any significant loss in its catalytic activity. The hybrid material Cu(II)Pc(SO 3 − ) 4 @NCCel has been employed as catalyst in the aerobic oxidation of alcohols and alkyl arenes in water. Under optimal catalytic conditions (0.004 mol% Cu(II) content, at room temperature), conversions of 99% for benzyl alcohol and 92% for tetralin were attained with excellent selectivity in both cases (selectivity > 99%) for the expected carbonyl derivatives (benzaldehyde and tetralone). After 7 cycles, a minor decrease in product yield was observed, thus indicating high stability of the catalyst. Jain and collaborators [76] selected polyaniline (PANI) to covalently graft the Co(II)Pc (SO 2 Cl) 4 catalyst through the activated sulfonyl chloride units ( Figure 27) and the efficiency of the obtained hybrid Co(II)Pc(SO 2 Cl) 3 SO 2 @PANI was assessed in the aerobic oxidation of alcohols.
The best performance for the oxidation of benzhydrol (diphenylmethanol), selected as the model substrate, was found in the assays taken in acetonitrile at 65 • C and in the presence isobutyraldehyde as sacrificial agent. After 3.5 h, benzophenone was obtained with the best yield (76%) and the best TOF (21.7 h −1 ). This efficiency was maintained or even increased when the reaction scope was enlarged to the oxidation of a variety of primary and secondary alcohols (e.g., furfuryl alcohol, cyclohexanol, benzyl alcohol substituted with electron-donating or electron-withdrawing substituents, 1-phenylethanol, octan-1-ol), selectively affording the corresponding carbonyl compounds in good yields (72-88%) without any overoxidation product. The catalyst was found to be highly stable and could be reused for several runs (six times) without any significant loss in its catalytic activity.  [77] in order to evaluate its eficiency in toluene oxidation assisted by dioxygen and N-hydroxyphthalimide (NHPI). APTES was used to introduce the amino functions onto the support surface before the coupling with Fe(II)Pc(CO2H)4. Further insights on the relationship between catalytic selectivity and catalyst composition have been assessed by preparing catalysts with different amounts of Fe(II)Pc(CO2H)4 supported on NH2-SBA-15. The study disclosed that toluene conversion in the oxidative process mediated by the catalyst with the highest Fe(II)Pc(CO2H)4 load (20 wt% on Fe(II)Pc(CO2H)3CONH@NH2SBA-15) attained a maximum of 35.3% with a selectivity of 71.8% for benzoic acid, whereas with the catalyst with lower MPc content (11 wt%) the toluene conversion attained 23.7 with 56.4% selectivity for benzaldehyde. The authors stated that the catalytic system is suitable for oxidizing both electron-donating and electron-withdrawing substituted toluene derivatives and no significant loss of catalytic activity and selectivity was observed during the reusability and recyclability assays.  [77] in order to evaluate its eficiency in toluene oxidation assisted by dioxygen and N-hydroxyphthalimide (NHPI). APTES was used to introduce the amino functions onto the support surface before the coupling with Fe(II)Pc(CO 2 H) 4 . Further insights on the relationship between catalytic selectivity and catalyst composition have been assessed by preparing catalysts with different amounts of Fe(II)Pc(CO 2 H) 4 supported on NH 2 -SBA-15. The study disclosed that toluene conversion in the oxidative process mediated by the catalyst with the highest Fe(II)Pc(CO 2 H) 4 load (20 wt% on Fe(II)Pc(CO 2 H) 3 CONH@NH 2 SBA-15) attained a maximum of 35.3% with a selectivity of 71.8% for benzoic acid, whereas with the catalyst with lower MPc content (11 wt%) the toluene conversion attained 23.7 with 56.4% selectivity for benzaldehyde. The authors stated that the catalytic system is suitable for oxidizing both electron-donating and electron-withdrawing substituted toluene derivatives and no significant loss of catalytic activity and selectivity was observed during the reusability and recyclability assays. The importance of developing sustainable conditions to obtain the 2-nitro-4-methylsulfonylbenzoic acid (NMSBA), a key intermediate in the synthesis of the cornfield herbicide mesotrione, prompted Liu and Zhu [78] to evaluate the efficiency of the Fe(II) and Cu(II) complexes of phthalocyanine, Fe(II)Pc and Cu(II)Pc (Figure 2) in the aerobic oxidation of the precursor 2-nitro-4-methylsulfonyltoluene (NMST) (Figure 29).
The efficiency of the catalysts was evaluated first by using toluene derivatives with electron-withdrawing substituents in the presence of air or oxygen and the results showed that the highest yields were obtained under pure oxygen. The results showed that the catalytic activity in the oxidation of NMST was greatly affected by phthalocyanine metal ion, reaction time, reaction temperature, oxygen pressure and concentrations of phthalocyanine and NaOH. The best performance (NMSBA yield up to 53%; 89.3% of NMST conversion; 8 h of reaction) was found in the reactions carried out in methanol, at 55 °C, in the presence of the Fe(II) phthalocyanine (1.0 × 10 −4 mol L −1 ), O2 atmosphere (2.0 MPa) and NaOH (0.6 mol L −1 ). A plausible mechanism for this catalytic process was proposed, which involved deprotonation and radical pathways.  (Figure 29).
The efficiency of the catalysts was evaluated first by using toluene derivatives with electron-withdrawing substituents in the presence of air or oxygen and the results showed that the highest yields were obtained under pure oxygen. The results showed that the catalytic activity in the oxidation of NMST was greatly affected by phthalocyanine metal ion, reaction time, reaction temperature, oxygen pressure and concentrations of phthalocyanine and NaOH. The best performance (NMSBA yield up to 53%; 89.3% of NMST conversion; 8 h of reaction) was found in the reactions carried out in methanol, at 55 • C, in the presence of the Fe(II) phthalocyanine (1.0 × 10 −4 mol L −1 ), O 2 atmosphere (2.0 MPa) and NaOH (0.6 mol L −1 ). A plausible mechanism for this catalytic process was proposed, which involved deprotonation and radical pathways. Chen and collaborators [79] found that the hybrid materials M(II)Pc(SO3 -)4@-Zn2Al-LDH (M = Co(II), Cu(II), Mn(II), and Fe(II)), obtained from the coprecipitation method of the metal complexes of the anionic tetrasulfonic phthalocyanine M(II)Pc(SO3H)4 ( Figure  17) with zinc and aluminum layered double hydroxides (LDHs) showed an excellent catalytic performance in the oxidation of different olefins in the presence of O2/isobutyraldehyde, IBA [80] and are also efficient catalysts for the selective oxidation of ethylbenzene to acetophenone in the presence of O2/NHPI (N-hydroxyphthalimide), using benzonitrile as solvent at 120 °C. The best results were observed for the hybrid M = Co(II) (90% of conversion and selectivity higher than 99%) with no appreciable reduction on its activity or selectivity even after five runs. Under the optimized reaction conditions, M(II)Pc(SO3 − )4@-Zn2Al-LDH was also able to catalyze the aerobic oxidation of other alkyl arenes (Table 4) and a series of controlled experiments suggested that a synergistic effect might exist between the basicity of the support and the activity of M(II)Pc during the oxidation.  Chen and collaborators [79] found that the hybrid materials M(II)Pc(SO 3 − ) 4 @-Zn 2 Al-LDH (M = Co(II), Cu(II), Mn(II), and Fe(II)), obtained from the coprecipitation method of the metal complexes of the anionic tetrasulfonic phthalocyanine M(II)Pc(SO 3 H) 4 ( Figure 17) with zinc and aluminum layered double hydroxides (LDHs) showed an excellent catalytic performance in the oxidation of different olefins in the presence of O 2 /isobutyraldehyde, IBA [80] and are also efficient catalysts for the selective oxidation of ethylbenzene to acetophenone in the presence of O 2 /NHPI (N-hydroxyphthalimide), using benzonitrile as solvent at 120 • C. The best results were observed for the hybrid M = Co(II) (90% of conversion and selectivity higher than 99%) with no appreciable reduction on its activity or selectivity even after five runs. Under the optimized reaction conditions, M(II)Pc(SO 3 − ) 4 @-Zn 2 Al-LDH was also able to catalyze the aerobic oxidation of other alkyl arenes (Table 4) and a series of controlled experiments suggested that a synergistic effect might exist between the basicity of the support and the activity of M(II)Pc during the oxidation. series of controlled experiments suggested that a synergistic effect might exist between the basicity of the support and the activity of M(II)Pc during the oxidation.       series of controlled experiments suggested that a synergistic effect might exist between the basicity of the support and the activity of M(II)Pc during the oxidation.                 series of controlled experiments suggested that a synergistic effect might exist between the basicity of the support and the activity of M(II)Pc during the oxidation.       Based on the obtained results a possible mechanism for the oxidation of ethylbenzene in the presence of O 2 /NHPI has been proposed ( Figure 30). It was suggested that phthalimido-N-oxyl radical (PINO) generated from NHPI through the catalytic action of Co(II)Pc(SO 3 − ) 4 @-Zn 2 Al-LDH, or through autoxidation, promotes the formation of the benzylic radical that, after reaction with O 2 , affords the acylperoxy radical. This acylperoxy radical can abstract hydrogen from ethylbenzene or NHPI leading to the hydroperoxide, which can be decomposed in acetophenone and 1-phenylethanol by Co(II)Pc(SO 3 − ) 4 @-Zn 2 Al-LDH. Based on the obtained results a possible mechanism for the oxidation of ethylbenzene in the presence of O2/NHPI has been proposed ( Figure 30). It was suggested that phthalimido-N-oxyl radical (PINO) generated from NHPI through the catalytic action of Co(II)Pc(SO3 − )4@-Zn2Al-LDH, or through autoxidation, promotes the formation of the benzylic radical that, after reaction with O2, affords the acylperoxy radical. This acylperoxy radical can abstract hydrogen from ethylbenzene or NHPI leading to the hydroperoxide, which can be decomposed in acetophenone and 1-phenylethanol by Co(II)Pc(SO3 − )4@-Zn2Al-LDH.  Shaabani, Amini and coworkers [81] studied the efficiency of the metal-organic framework (MOF)MIL-101(Cr)-NH 2 decorated with a Co(II) phthalocyanine, Co(II)Pc(CO 2 H) 4 to catalyze the one-pot tandem oxidative A 3 coupling reactions of alcohols (through the aldehyde intermediates) with amines and alkynes ( Figure 31). The covalent immobilization of Co(II)Pc(CO 2 H) 4 in MIL-101(Cr)-NH 2 mediated by amide bonds was performed after activation of the carboxylic acid groups as acyl chlorides. An optimization of the reaction conditions using the tandem oxidative reaction between benzyl alcohol (1), piperidine The possibility of NHPI to replace isobutyraldehyde, benzaldehyde, or t-butylhydroperoxide as co-oxidant in aerobic oxidation reactions catalyzed by MPc prompted Sun and collaborators [82] to test the Co(II) tetraamide phthalocyanine Co(II)Pc(CONH2)4 ( Figure 32) efficiency in the oxidation of hydrocarbons and alcohols with O2, in the presence of NHPI. The optimization of the reaction parameters with α-methylstyrene (affording acetophenone by C-C double bond cleavage) allowed the establishment of a synergistic catalytic system based on NHPI (20 mol%) and Co(II)Pc(CONH2)4 (8 mol%) to perform the aerobic oxidation of alcohols and α-alkylaryl groups in acetonitrile (15 mL) at 75 °C under O2 (1 atm) for 24 h. This study reported also the use of the catalytic system in the oxidation of other substrates (alkyl arenes and alcohols) affording the carbonyl (or carboxylic) products with reasonable to very high yields. The possibility of NHPI to replace isobutyraldehyde, benzaldehyde, or t-butylhydroperoxide as co-oxidant in aerobic oxidation reactions catalyzed by MPc prompted Sun and collaborators [82] to test the Co(II) tetraamide phthalocyanine Co(II)Pc(CONH 2 ) 4 ( Figure 32) efficiency in the oxidation of hydrocarbons and alcohols with O 2 , in the presence of NHPI. The optimization of the reaction parameters with α-methylstyrene (affording acetophenone by C-C double bond cleavage) allowed the establishment of a synergistic catalytic system based on NHPI (20 mol%) and Co(II)Pc(CONH 2 ) 4 (8 mol%) to perform the aerobic oxidation of alcohols and α-alkylaryl groups in acetonitrile (15 mL) at 75 • C under O 2 (1 atm) for 24 h. This study reported also the use of the catalytic system in the oxidation of other substrates (alkyl arenes and alcohols) affording the carbonyl (or carboxylic) products with reasonable to very high yields.

Olefins
The oxidation of olefins is of considerable interest in industrial organic synthesis, because derivatives containing an oxygen substituent are highly valuable as synthetic intermediates in bulk industrial processes or as crucial intermediates in the synthesis of fine chemicals. Selective oxidation of double bonds provides epoxides and diols, whereas the oxidation of allylic positions leads to the formation of allylic alcohols and ketones. Thus, the development of effective methods for the selective oxidation of olefins has drawn much attention over the years.
Considering that inexpensive and robust layered double hydroxides (LDHs) He, Xu and coworkers [80]

Olefins
The oxidation of olefins is of considerable interest in industrial organic synthesis, because derivatives containing an oxygen substituent are highly valuable as synthetic intermediates in bulk industrial processes or as crucial intermediates in the synthesis of fine chemicals. Selective oxidation of double bonds provides epoxides and diols, whereas the oxidation of allylic positions leads to the formation of allylic alcohols and ketones. Thus, the development of effective methods for the selective oxidation of olefins has drawn much attention over the years.
Considering that inexpensive and robust layered double hydroxides (LDHs) He, Xu and coworkers [80] extended the study of the hybrid materials M(II)Pc(SO 3 − ) 4 @-Zn 2 Al-LDH based on the intercalation of the anionic M(II)Pc(SO 3 H) 4 coordinated with Co, Cu, Mn, and Fe into Zn 2 Al-LDH. The catalytic activity of these hybrids (M(II)Pc(SO 3 − ) 4 @-Zn 2 Al-LDH) was initially evaluated in the aerobic epoxidation of styrene in the presence of isobutyraldehyde (IBA). After a systematic evaluation of the reaction conditions, it was found that the hybrid based on the Co(II) complex also gave the highest yield of styrene oxide (Table 5), followed by Cu(II) > Mn(II) > Fe(II). The authors related this order with the redox potentials of the MPc and with the different accelerating activity in the production of the isobutyryl radical ( Figure 33). Extra experiments allowed to conclude that the predominant pathway to the formation of styrene oxide (acylperoxy radical vs. peroxyacid) is radical (a) (Figure 33).     After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity 4 58 98 10  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity  After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO3 -)4@-Zn2Al-LDH or through autoxidation, this species reacts with O2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity After the formation of isobutyryl radical (a) from isobutyraldehyde, mediated by Co(II)Pc(SO 3 − ) 4 @-Zn 2 Al-LDH or through autoxidation, this species reacts with O 2 affording acylperoxy radical (b). This radical can then react with styrene, thus affording the epoxide or benzaldehyde, this one through the dioxetane intermediate (g). Additionally, radical (b) can abstract a hydrogen from IBA leading to the peroxyacid (d), that after reaction with styrene affords the epoxide. Other assays allowed to conclude that the active site for the epoxidation are the Co(II)Pc molecules in the interlayer of the hybrid and the basicity of the intercalated LDHs is an important feature to improve epoxide selectivity by restraining the transformation of radical (c) into the dioxetane (g) (Figure 33). These studies were extended to other olefins (Table 5), demonstrating that Co(II)Pc(SO 3 − ) 4 @-Zn 2 Al-LDH in the presence of O 2 /IBA is an excellent bifunctional catalyst to selectively epoxidize alkenes.
Inspired on Wacker-type processes, Knölker and Puls [83] reported a simple procedure for the oxidation of olefins into ketones under mild reaction conditions using an iron phthalocyanine complex. In the optimization of the reaction conditions using 2-vinylnaphthalene as model substrate (Figure 34), the authors found that the best achievements (2-acetonaphthone in 82% yield after 6 h of reaction) were obtained in reactions mediated by the already studied Fe(II)PcF 16 (Figure 11). These reactions, in the presence of O 2 and using triethylsilane (Et 3 SiH) as additive, were performed in ethanol, at room temperature. Reactions in solvents other than ethanol (methanol, isopropanol, 2,2,2-trifluoroethanol, dichloromethane, diethylether, tetrahydrofuran, diglyme, acetone, acetonitrile) gave lower yields.
The scope of this iron-catalyzed Wacker-type oxidation was evaluated using other substituted styrene derivatives, which provided the corresponding ketones in yields ranging from 65 to 95%, confirming the high functional group tolerance of this approach. However, the oxidation of aliphatic olefins was found to be more problematic, since the oxidation of octadec-1-ene with 10 mol% of Fe(II)PcF 16 , 6 equiv. of PMHS (poly(methylhydrosiloxane)) in ethanol afforded octadecan-2-one in only 30% yield after four days of reaction at reflux. already studied Fe(II)PcF16 ( Figure 11). These reactions, in the presence of O2 and using triethylsilane (Et3SiH) as additive, were performed in ethanol, at room temperature. Reactions in solvents other than ethanol (methanol, isopropanol, 2,2,2-trifluoroethanol, dichloromethane, diethylether, tetrahydrofuran, diglyme, acetone, acetonitrile) gave lower yields. The scope of this iron-catalyzed Wacker-type oxidation was evaluated using other substituted styrene derivatives, which provided the corresponding ketones in yields ranging from 65 to 95%, confirming the high functional group tolerance of this approach. However, the oxidation of aliphatic olefins was found to be more problematic, since the oxidation of octadec-1-ene with 10 mol% of Fe(II)PcF16, 6 equiv. of PMHS (poly(methylhydrosiloxane)) in ethanol afforded octadecan-2-one in only 30% yield after four days of reaction at reflux.

Miscellaneous Substrates
Recently, Castro at al [84] reported the preparation of a Pc coordination polymer, Cu(II)Pc(SPyCu)4, and its corresponding homogeneous precursor Cu(II)Pc(SPy)4 ( Figure  35), which were used as catalysts in the aerobic oxidation of 3,5-di-tert-butylcatechol (3,5-DTBC) into 3,5-di-tert-butyl-o-benzoquinone (3,5-DTBQ), using dioxygen from air, in the absence or in the presence of hydrogen peroxide. Parameters such as reaction time, pH, oxidant, and catalyst amount have been studied in the catechol oxidase-like activity of both systems. The best performance (82.2% conversion) of Cu(II)Pc(SPyCu)4 vs. Cu(II)Pc(SPy) 4 was justified considering that the supramolecular structure is able to minimize the aggregation and the autooxidative degradation of the catalyst, both common in homogeneous catalysts based on Pcs. The turnover rate estimated for Cu(II)Pc(SPyCu)4 (27.5 h −1 ) is almost seven times higher than that observed for Cu(II)Pc(SPy)4 (4.2 h −1 ) in the presence of H2O2. The activity of the new material was maintained nearly unchanged during four catalytic cycles, an important feature for future applications.
An oxidative system based on heterogeneous N-heterocyclic carbene (NHC) catalysis, which is composed by a polystyrene-supported triazolium pre-catalyst (using DBU (50 mol%) as the optimal base to produce the carbene species), Fe(II) phthalocyanine (Fe(II)Pc, Figure 2) and air as the terminal oxidant was described by Massi and collaborators [85] for the selective conversion of 5-hydroxymethylfurfural (HMF) into the addedvalue 5-hydroxymethyl-2-furancarboxylic acid (HMFCA). The reported one-pot two-step procedure involves sequential oxidative esterification of HMF to produce a polyester oligomer, at room temperature, possessing both hydroxyl and carboxyl terminal groups. The Fe(II)Pc is able to mediate the aerobic oxidative esterification of HMF, the polyester being hydrolyzed in the presence of a ionic supported base to give HMFCA in 87% overall yield. The same strategy was adopted for the effective synthesis of ester and amide derivatives of HMFCA by nucleophilic depolymerization of the oligomeric intermediate with methanol and butylamine, respectively. Moreover, the utilization of this oxidative system for the direct conversion of HMF and furfural into their corresponding ester, amide, and thioester derivatives was also reported.

Miscellaneous Substrates
Recently, Castro at al [84] reported the preparation of a Pc coordination polymer, Cu(II)Pc(SPyCu) 4 , and its corresponding homogeneous precursor Cu(II)Pc(SPy) 4 (Figure 35), which were used as catalysts in the aerobic oxidation of 3,5-di-tert-butylcatechol (3,5-DTBC) into 3,5-di-tert-butyl-o-benzoquinone (3,5-DTBQ), using dioxygen from air, in the absence or in the presence of hydrogen peroxide. Parameters such as reaction time, pH, oxidant, and catalyst amount have been studied in the catechol oxidase-like activity of both systems. The best performance (82.2% conversion) of Cu(II)Pc(SPyCu) 4 vs. Cu(II)Pc(SPy) 4 was justified considering that the supramolecular structure is able to minimize the aggregation and the autooxidative degradation of the catalyst, both common in homogeneous catalysts based on Pcs. The turnover rate estimated for Cu(II)Pc(SPyCu) 4 (27.5 h −1 ) is almost seven times higher than that observed for Cu(II)Pc(SPy) 4 (4.2 h −1 ) in the presence of H 2 O 2 . The activity of the new material was maintained nearly unchanged during four catalytic cycles, an important feature for future applications.
An oxidative system based on heterogeneous N-heterocyclic carbene (NHC) catalysis, which is composed by a polystyrene-supported triazolium pre-catalyst (using DBU (50 mol%) as the optimal base to produce the carbene species), Fe(II) phthalocyanine (Fe(II)Pc, Figure 2) and air as the terminal oxidant was described by Massi and collaborators [85] for the selective conversion of 5-hydroxymethylfurfural (HMF) into the addedvalue 5-hydroxymethyl-2-furancarboxylic acid (HMFCA). The reported one-pot two-step procedure involves sequential oxidative esterification of HMF to produce a polyester oligomer, at room temperature, possessing both hydroxyl and carboxyl terminal groups. The Fe(II)Pc is able to mediate the aerobic oxidative esterification of HMF, the polyester being hydrolyzed in the presence of a ionic supported base to give HMFCA in 87% overall yield. The same strategy was adopted for the effective synthesis of ester and amide deriva-tives of HMFCA by nucleophilic depolymerization of the oligomeric intermediate with methanol and butylamine, respectively. Moreover, the utilization of this oxidative system for the direct conversion of HMF and furfural into their corresponding ester, amide, and thioester derivatives was also reported.

Conclusions
Since the serendipitous discovery of Pcs, at the beginning of the 20th century, a growing attention has been devoted to the ubiquitous catalytic properties and applications of Pcs and Pcs coordinated with metal ions, MPcs. In fact, these old synthetic dyes have been very attractive in the view of academic research, but mainly for industrial purposes as these dyes are easily accessible on a large scale, are robust under harsh reaction conditions, show high activity and can be recovered and recycled.
In this mini-review, we have provided the progresses, mainly gathered in the last decade, made with Pc complexes with transition metals as catalysts in the aerobic oxidation of thiols and thiophenes, and on the production of added-value fine chemicals resulting from the oxidation of alkyl arenes, alcohols, and olefins, among others. The success and diversity of MPcs as catalysts over different substrates is mostly attributed to their high structural flexibility in terms of metals and electronic properties of the phthalocyanine ligands. For each substrate and each catalyst, a careful evaluation of the reaction conditions is required for the best achievements. Sustained research efforts on the synthesis, and new insights on the understanding of MPcs reaction mechanisms should provide a great variety of novel and featured MPcs complexes with diverse properties, paving the way for new applications as selective and environmentally friendly catalysts for oxidation reactions.

Conclusions
Since the serendipitous discovery of Pcs, at the beginning of the 20th century, a growing attention has been devoted to the ubiquitous catalytic properties and applications of Pcs and Pcs coordinated with metal ions, MPcs. In fact, these old synthetic dyes have been very attractive in the view of academic research, but mainly for industrial purposes as these dyes are easily accessible on a large scale, are robust under harsh reaction conditions, show high activity and can be recovered and recycled.
In this mini-review, we have provided the progresses, mainly gathered in the last decade, made with Pc complexes with transition metals as catalysts in the aerobic oxidation of thiols and thiophenes, and on the production of added-value fine chemicals resulting from the oxidation of alkyl arenes, alcohols, and olefins, among others. The success and diversity of MPcs as catalysts over different substrates is mostly attributed to their high structural flexibility in terms of metals and electronic properties of the phthalocyanine ligands. For each substrate and each catalyst, a careful evaluation of the reaction conditions is required for the best achievements. Sustained research efforts on the synthesis, and new insights on the understanding of MPcs reaction mechanisms should provide a great variety of novel and featured MPcs complexes with diverse properties, paving the way for new applications as selective and environmentally friendly catalysts for oxidation reactions.