The Effect of Functional Group Polarity in Palladium Immobilized Multiwalled Carbon Nanotube Catalysis : Application in Carbon-Carbon Coupling Reaction

Carbon nanotubes (CNTs) are effective supports for nano metals and together they represent hybrids that combine unique properties of both. A microwave induced reaction was used to deposit nano palladium on carboxylated and octadecylamine functionalized multiwall CNTs, which were used to carry out C-C coupling reactions in DMF and toluene. These hybrids showed excellent catalytic activity with yield as high as 99.8% while its enhancement with respect to commercially available Pd/C catalyst reached as high as 109%, and the reactions times were significantly lower. Polarity of the functionalized form was found to be a significant factor with the polar carboxylated CNT showing better activity in DMF while the relatively nonpolar octadecyl amine was better in toluene. The results suggest the possibility of tailor making functionalized CNT when used as catalyst supports.

The pd-catalyzed reaction between aryl or alkenyl halides and olefins to deliver substituted olefins with high E-selectivity-known as the Heck reaction-is one of the most fundamental reactions in cross-coupling chemistry [34,35].Initially, soluble Pd/Pt containing organometallic compounds were used as catalysts [34,35].Later on, metal nanoparticle coated CNTs which represents the next generation of homogeneous catalyst were used to carry out these cross-coupling reactions.These have an advantage of easy separation of catalyst through centrifugation or precipitation [34][35][36].
In these typical reactions, the particle size, surface area, dispersion, and chemical nature of the support are important parameters [37][38][39].In the case of CNT-NM, the presence of functional groups can alter many of these properties, but its role is not well understood.An added advantage of CNTs is that covalently introducing functional groups such as carboxylic carboxylic (-COOH), and (-CONH 2 ) can make them dispersible in different solvents and can be made solvent dispersible for different liquid phase reactions [40][41][42].The synthesis of highly dispersed CNT-NM hybrids has been a challenge and is highly desirable for liquid phase reactions.We have reported the microwave induced synthesis CNT-Pt for catalytic hydrogenation of m-nitrochlorobenzene [19].The objective of this work is to study the effect of CNT functionalization in CNT-Pd hybrids as applied to the Heck reaction and to study the effect of parameters such as dispersibility and polarity.

Synthesis of CNT-Metal Nanohybrids
Carboxylated Multiwall Carbon Nanotubes (MWCNT-COOH) were synthesized following a previously published methodology [42].Briefly, the CNTs were functionalized in a Microwave Accelerated Reaction System (Mode: CEM Mars, CEM Corporation, 3100 Smith Farm Road, Matthews, NC, USA) fitted with internal temperature and pressure controls.Pre-weighed amounts of purified MWCNT were treated with a mixture of concentrated H 2 SO 4 and HNO 3 solution under microwave radiation at 140 • C for 20 min.This led to the formation of carboxylic groups on the surface leading to high aqueous dispersibility.The resulting solid was filtered through a 10 µm membrane filter, washed with water to a neutral pH and dried under vacuum at 80 • C to a constant weight.
The MWCNT-COOH was used as the starting material to synthesize organic dispersible MWCNTs [43].Pre-weighed amounts of MWCNT-COOH were mixed with thionylchloride (SOCl 2 ) and dimethylformamide (DMF) and were subjected to microwave radiation at 70 • C for 20 min leading to formation of MWCNT-COCl.The product was filtered and washed with THF till and was then dried in a vacuum oven at room temperature for 12 h.MWCNT-COCl was then reacted with octadecylamine (ODA) under microwave radiation at 120 • C for 10 min.The product was filtered and washed with hot ethanol and dichloromethane and dried at room temperature under vacuum to obtain MWCNT-ODA.The products MWCNT-COOH and MWCNT-ODA were used to synthesize the palladium loaded functionalized CNT nanohybrids: p-MWCNT-Pd and np-MWCNT-Pd respectively.The former was expected to be more polar.The p-MWCNT-Pd and np-MWCNT-Pd were synthesized by direct chemical reduction of metal salts as previously published by our group [19].Pre-weighed amounts of the selected CNTs (MWCNT-COOH or MWCNT-ODA) were added to the reaction chamber together with a palladium dichloride (PdCl 2 )-ethanol mixture.The reactions were carried out under microwave radiation at 190 • C for 10 min.After cooling, the products were filtered, washed with 0.5 N hydrochloric acid and MilliQ water to a neutral pH.The products (p-MWCNT-Pd or np-MWCNT-Pd) were dried at room temperature in a vacuum oven to constant weight.

Catalytic C-C Coupling
Heck reaction was carried out as follows.CNT-NM (p-MWCNT-Pd or np-MWCNT-Pd) (3 mg, 0.01 mol %), iodobenzene (496.8 µL, 4.44 mmol), styrene (765.1 µL, 6.69 mmol), tributylamine (TBA) (2.014 mL, 8.92 mmol) and 0.5 mg PPh 3 were mixed in 5 mL of dry solvent in a two necked round bottom flask.The resulting suspension was placed in a preheated rota-mantle at 140 • C with magnetic stirring.The course of the reaction was followed by periodically withdrawing aliquots (50 µL) from the reaction mixture and analyzing by GC.The reaction was carried out with triphenylphosphine (PPh 3 ) in dimethylformamide (DMF) and toluene.The same reaction was carried out with commercial Pd/C (24 mg, 0.01 mol %) and also with PdCl 2 (2 mg, 0.01 mol %) to compare the catalytic activity of the CNT-NMs.The reaction is shown in Scheme 1.

Catalytic C-C Coupling
Heck reaction was carried out as follows.CNT-NM (p-MWCNT-Pd or np-MWCNT-Pd) (3 mg, 0.01 mol %), iodobenzene (496.8 μL, 4.44 mmol), styrene (765.1 μL, 6.69 mmol), tributylamine (TBA) (2.014 mL, 8.92 mmol) and 0.5 mg PPh3 were mixed in 5 mL of dry solvent in a two necked round bottom flask.The resulting suspension was placed in a preheated rota-mantle at 140 °C with magnetic stirring.The course of the reaction was followed by periodically withdrawing aliquots (50 µ L) from the reaction mixture and analyzing by GC.The reaction was carried out with triphenylphosphine (PPh3) in dimethylformamide (DMF) and toluene.The same reaction was carried out with commercial Pd/C (24 mg, 0.01 mol %) and also with PdCl2 (2 mg, 0.01 mol %) to compare the catalytic activity of the CNT-NMs.The reaction is shown in scheme 1.

Scheme 1. General representation of reaction.
After 1 h reflux, the mixture was cooled for 15 min and extracted with diethyl ether.This was followed by washing with 2 N HCl and water to remove any base present.The ether layer was then dried over CaCl2.Finally, the solution was filtered and dried in vacuum desiccator to constant weight.The obtained product was recrystallized from absolute alcohol and its composition was confirmed by comparison with pure stilbene.The final product did not show the presence of any byproducts by thin layer chromatography (TLC) analysis.The melting point of the recrystallized product and UV-λmax were found to be 122.5 °C and 296 nm which was in line with what was expected for pure stilbene [44].GC analysis of the product also showed only the presence of stilbene.
The aforementioned reactions were also carried out in microwave conditions at 420 W [45].The amount of reactant, catalyst, and base (but no solvent) were maintained the same as done under reflux conditions.But, here the vessel was kept in microwave oven for 17 min where reaction went to completion with no reactant observed in the TLC analysis.

Nanohybrid Characterization.
Figure 1 shows the SEM images of MWCNT-COOH, p-MWCNT-Pd, np-MWCNT-Pd and Pd/C.The MWCNTs had diameter in the range of 20-40 nm and the length was about 10-30 μm.There was no detectable change in tube morphology after acid treatment or after hybrid formation, implying that there was minimal visible damage to the tube structure.It is quite evident from the SEM images that the CNTs were coated with the metal nanoparticles.The EDX data shows large amounts of metal particles on the surface of the CNTs which are around 41.02 and 36.78% for p-MWCNT-Pd and np-MWCNT-Pd, respectively.The size of Pd particles ranged from 1 to 10 nm on p-MWCNT-Pd and from 5 to 50 nm on np-MWCNT-Pd.This implied that the catalyst was nanostructured and this was expected to contribute towards enhanced activity [19].
The FTIR spectra shown in Figure 2 confirmed the presence of functional groups in MWCNT-COOH, MWCNT-ODA, p-MWCNT-Pd, and np-MWCNT-Pd hybrids.The carbonyl stretching frequency in MWCNT-COOH was seen at 1716 cm −1 (COOH).The 3440 cm −1 band (O-H) present in MWCNT-COOH spectrum was attributed to the hydroxyl vibration of the carboxylic acid group introduced through functionalization.In Figure 2b, the peaks around 1636 cm −1 and 1715 cm −1 were Scheme 1.General representation of reaction.
After 1 h reflux, the mixture was cooled for 15 min and extracted with diethyl ether.This was followed by washing with 2 N HCl and water to remove any base present.The ether layer was then dried over CaCl 2 .Finally, the solution was filtered and dried in vacuum desiccator to constant weight.The obtained product was recrystallized from absolute alcohol and its composition was confirmed by comparison with pure stilbene.The final product did not show the presence of any byproducts by thin layer chromatography (TLC) analysis.The melting point of the recrystallized product and UV-λ max were found to be 122.5 • C and 296 nm which was in line with what was expected for pure stilbene [44].GC analysis of the product also showed only the presence of stilbene.
The aforementioned reactions were also carried out in microwave conditions at 420 W [45].The amount of reactant, catalyst, and base (but no solvent) were maintained the same as done under reflux conditions.But, here the vessel was kept in microwave oven for 17 min where reaction went to completion with no reactant observed in the TLC analysis.

Nanohybrid Characterization
Figure 1 shows the SEM images of MWCNT-COOH, p-MWCNT-Pd, np-MWCNT-Pd and Pd/C.The MWCNTs had diameter in the range of 20-40 nm and the length was about 10-30 µm.There was no detectable change in tube morphology after acid treatment or after hybrid formation, implying that there was minimal visible damage to the tube structure.It is quite evident from the SEM images that the CNTs were coated with the metal nanoparticles.The EDX data shows large amounts of metal particles on the surface of the CNTs which are around 41.02% and 36.78% for p-MWCNT-Pd and np-MWCNT-Pd, respectively.The size of Pd particles ranged from 1 to 10 nm on p-MWCNT-Pd and from 5 to 50 nm on np-MWCNT-Pd.This implied that the catalyst was nanostructured and this was expected to contribute towards enhanced activity [19].
The FTIR spectra shown in Figure 2 confirmed the presence of functional groups in MWCNT-COOH, MWCNT-ODA, p-MWCNT-Pd, and np-MWCNT-Pd hybrids.The carbonyl stretching frequency in MWCNT-COOH was seen at 1716 cm −1 (COOH).The 3440 cm −1 band (O-H) present in MWCNT-COOH spectrum was attributed to the hydroxyl vibration of the carboxylic acid group introduced through functionalization.In Figure 2b, the peaks around 1636 cm −1 and 1715 cm −1 were attributed to stretching vibrations of the amide C=O group, the sharp peaks at 2921 cm −1 and 2847 cm −1 were attributed to the C-H stretching vibration of the alkyl chain from ODA, the peak at 3460 cm −1 was attributed to the N-H stretching vibration from ODA, and the peak at 1250 cm −1 was attributed to C-N stretching vibration.In all the samples, the peak around 1580 cm −1 was assigned to the C=C stretching of the carbon skeleton.The appearance of new bands at 993 cm −1 and 996 cm −1 in the spectra for the hybrids confirmed the presence of Pd [37][38][39].The broad peak centered around 3440 cm −1 in MWCNT-COOH was not prominent in the IR spectrum of p-MWCNT-Pd, and the shift in the carbonyl stretching frequency from 1716 cm −1 to 1721 cm −1 in the spectra for the hybrids indicated interaction of Pd with the COOH group.
Appl.Sci.2018, 8, x FOR PEER REVIEW 4 of 11 attributed to stretching vibrations of the amide C=O group, the sharp peaks at 2921 cm −1 and 2847 cm −1 were attributed to the C-H stretching vibration of the alkyl chain from ODA, the peak at 3460 cm −1 was attributed to the N-H stretching vibration from ODA, and the peak at 1250 cm −1 was attributed to C-N stretching vibration.In all the samples, the peak around 1580 cm −1 was assigned to the C=C stretching of the carbon skeleton.The appearance of new bands at 993 cm −1 and 996 cm −1 in the spectra for the hybrids confirmed the presence of Pd [37][38][39].The broad peak centered around 3440 cm −1 in MWCNT-COOH was not prominent in the IR spectrum of p-MWCNT-Pd, and the shift in the carbonyl stretching frequency from 1716 cm −1 to 1721cm −1 in the spectra for the hybrids indicated interaction of Pd with the COOH group.attributed to stretching vibrations of the amide C=O group, the sharp peaks at 2921 cm −1 and 2847 cm −1 were attributed to the C-H stretching vibration of the alkyl chain from ODA, the peak at 3460 cm −1 was attributed to the N-H stretching vibration from ODA, and the peak at 1250 cm −1 was attributed to C-N stretching vibration.In all the samples, the peak around 1580 cm −1 was assigned to the C=C stretching of the carbon skeleton.The appearance of new bands at 993 cm −1 and 996 cm −1 in the spectra for the hybrids confirmed the presence of Pd [37][38][39].The broad peak centered around 3440 cm −1 in MWCNT-COOH was not prominent in the IR spectrum of p-MWCNT-Pd, and the shift in the carbonyl stretching frequency from 1716 cm −1 to 1721cm −1 in the spectra for the hybrids indicated interaction of Pd with the COOH group.

Dispersibility
Figure 3a-f shows the dispersibility of p-MWCNT-Pd (5 mg), np-MWCNT-Pd (5 mg), and Pd/C (5 mg) in N,N-dimethylformamide (5 mL), and toluene (5 mL).It is evident that p-MWCNT-Pd, np-MWCNT-Pd, and Pd/C were significantly more dispersible in DMF than in toluene.The particle size of the dispersed CNT-NM is presented in Table 1.It shows that there is not much difference between p-MWCNT-Pd and np-MWCNT-Pd in toluene, but there was significant difference in DMF.The particle size of CNT-NM agglomerates in toluene were higher than those in DMF.As can be seen in Figure 3, there was significant precipitation of the MWCNT-Pd in toluene, so the particle size represents what remained dispersed.The colloidal dispersion in DMF and TBA remained homogeneously suspended for several weeks without need for mechanical stirring.

Dispersibility
Figure 3a-f shows the dispersibility of p-MWCNT-Pd (5 mg), np-MWCNT-Pd (5 mg), and Pd/C (5 mg) in N,N-dimethylformamide (5 mL), and toluene (5 mL).It is evident that p-MWCNT-Pd, np-MWCNT-Pd, and Pd/C were significantly more dispersible in DMF than in toluene.The particle size of the dispersed CNT-NM is presented in Table 1.It shows that there is not much difference between p-MWCNT-Pd and np-MWCNT-Pd in toluene, but there was significant difference in DMF.The particle size of CNT-NM agglomerates in toluene were higher than those in DMF.As can be seen in Figure 3, there was significant precipitation of the MWCNT-Pd in toluene, so the particle size represents what remained dispersed.The colloidal dispersion in DMF and TBA remained homogeneously suspended for several weeks without need for mechanical stirring.The metal nanoparticles loading in the hybrid materials were quantified using TGA as shown in

Dispersibility
Figure 3a-f shows the dispersibility of p-MWCNT-Pd (5 mg), np-MWCNT-Pd (5 mg), and Pd/C (5 mg) in N,N-dimethylformamide (5 mL), and toluene (5 mL).It is evident that p-MWCNT-Pd, np-MWCNT-Pd, and Pd/C were significantly more dispersible in DMF than in toluene.The particle size of the dispersed CNT-NM is presented in Table 1.It shows that there is not much difference between p-MWCNT-Pd and np-MWCNT-Pd in toluene, but there was significant difference in DMF.The particle size of CNT-NM agglomerates in toluene were higher than those in DMF.As can be seen in Figure 3, there was significant precipitation of the MWCNT-Pd in toluene, so the particle size represents what remained dispersed.The colloidal dispersion in DMF and TBA remained homogeneously suspended for several weeks without need for mechanical stirring.The metal nanoparticles loading in the hybrid materials were quantified using TGA as shown in Figure 4.The resulting weight above 600 °C was attributed to the weight of residual metal.The nanohybrids were found to contain 43.02 and 38.93 percent by weight of Pd in p-MWCNT-Pd and np-MWCNT-Pd, respectively, while Pd/C contained 5% by weight of Pd.

Effect of CNT Functionalization
The CNT-NM hybrids were used as catalysts in the Heck reaction of iodobenzene with styrene.All the reactions were carried out keeping substrate to Pd molar ratio constant at 0.01 mole percent.In all cases, trans-stilbene was the only product detected which was established by the single spot in the TLC analysis and confirmed by GC analysis.This was also confirmed by the melting point of 122.5 • C and UV max at 296 nm of the isolated product.
The mechanism of the reaction in presence of PPh 3 is shown in Figure 5.In general, the Pd from the CNT-NM desorbed to a soluble form to form a loose complex such as Pd(PPh 3 ) 4 .These complexes were more soluble than Pd and facilitated desorption of Pd from the catalyst.This may account for the high yield observed in the presence of PPh 3 .At the end of the reaction, the Pd readsorbed on the CNT phase.
The CNT-NM hybrids were used as catalysts in the Heck reaction of iodobenzene with styrene.All the reactions were carried out keeping substrate to Pd molar ratio constant at 0.01 mole percent.In all cases, trans-stilbene was the only product detected which was established by the single spot in the TLC analysis and confirmed by GC analysis.This was also confirmed by the melting point of 122.5 °C and UV max at 296 nm of the isolated product.
The mechanism of the reaction in presence of PPh3 is shown in Figure 5.In general, the Pd from the CNT-NM desorbed to a soluble form to form a loose complex such as Pd(PPh3)4.These complexes were more soluble than Pd and facilitated desorption of Pd from the catalyst.This may account for the high yield observed in the presence of PPh3.At the end of the reaction, the Pd readsorbed on the CNT phase.
Table 2 presents isolated yields of all the reactions after the completion of the reaction and recrystallization.The results of reaction at 150 °C are presented in Table 2 and Figure 6.In general, shorter reaction times and greater yields were obtained with p-MWCNT-Pd and np-MWCNT-Pd compared to Pd/C, demonstrating the superiority of these nanohybrids in the reaction.The time to completion for the reaction for both p-MWCNT-Pd and np-MWCNT-Pd were 60 min in DMF compared to 90 min for Pd/C.Similar results are also seen in Figure 6, where yield enhancement of CNT-NM hybrids with respect to Pd/C is also presented.Table 2 presents isolated yields of all the reactions after the completion of the reaction and recrystallization.The results of reaction at 150 • C are presented in Table 2 and Figure 6.In general, shorter reaction times and greater yields were obtained with p-MWCNT-Pd and np-MWCNT-Pd compared to Pd/C, demonstrating the superiority of these nanohybrids in the reaction.The time to completion for the reaction for both p-MWCNT-Pd and np-MWCNT-Pd were 60 min in DMF compared to 90 min for Pd/C.Similar results are also seen in Figure 6, where yield enhancement of CNT-NM hybrids with respect to Pd/C is also presented.carried out at a relatively higher temperature.Also, for catalysts containing polar groups (-COOH in this case), a polar aprotic solvent like DMF is a suitable solvent Heck reaction.
The reason for higher yields in DMF compared to the toluene (Boiling Point (B.P); 110.6 °C) is due to the better dispersibility of catalyst in addition to the higher boiling point of DMF (B.P; 153 °C).Nevertheless, when toluene was used as the solvent, np-MWCNT-Pd showed significantly higher catalytic activity than p-MWCNT-Pd, which was better than Pd/C.These were also attributed to dispersibility of catalyst (refer to Figure 6).Hence, it is evident that disparities in the polarity play an important role.

Active Metal Requirement and Reusability
Since DMF was the better solvent, the catalyst requirement for CNT-NM was calculated.Typical Heck reaction with conventional palladium salts requires 1-2 mol % catalyst [34,35].In the present work with MWCNT-Pd hybrids, significantly lower quantities of Pd (order of 0.01 mol % Pd) resulted in higher yield at shorter reaction times.Therefore, this study showed that nan palladium on functionalized CNTs is more effective than conventional palladium salts.The turnover frequency (TOF) of the two catalysts were calculated as follows: Under reflux conditions, the TOF of p-MWCNT-Pd and np-MWCNT-Pd in DMF were 9977 and 5863, respectively, and in toluene 1090 and 977, respectively, which shows that the polar p-MWCNT-Pd in polar solvent has higher catalytic activity.Under microwave conditions, the TOF of p-MWCNT- It is estimated that the ODA group will cause steric hindrance of the reactants.To test this hypothesis, the reactions were carried out under microwave conditions in absence of solvent.The reaction was complete in 17 min.During microwave heating, the CNT catalysts were seen to mix uniformly in the reaction mixture.The isolated yields for the reactions are shown in Table 2.The yield was much higher in the p-MWCNT-Pd than in np-MWCNT-Pd.The difference was attributed to steric effects, where the ODA group provided steric hindrances leading to lower yield.
In DMF, the p-MWCNT-Pd showed higher catalytic activity than np-MWCNT-Pd which was better than commercial Pd/C and PdCl 2 .The yield for p-MWCNT-Pd reached as high as 99.78% in DMF, whereas np-MWCNT-Pd, Pd/C, and PdCl 2 showed yields of 58.7%, 55.7%, and 45.7%, respectively.The catalytic activity of p-MWCNT-Pd with larger particle size was higher than np-MWCNT-Pd with smaller particle size (Table 1).The p-MWCNT-Pd was more polar than np-MWCNT-Pd and its interactions with DMF, which is a polar solvent, were better.Also, the long C 18 chain from octadecyl group in np-MWCNT-Pd may have provided some steric hindrance to the reactants.Thus, the polarity and functionalized forms of support material are important in the matter of catalytic activity.
In the case of toluene as solvent, the results were the opposite.The np-MWCNT-Pd showed significantly higher catalytic activity than p-MWCNT-Pd, which was better than Pd/C.Compared to Pd/C, the enhancement for np-MWCNT-Pd and p-MWCNT-Pd were 60% and 32% respectively.Therefore, the enhancement nearly doubled for the nonpolar np-MWCNT-Pd.In this case, the catalytic activity of p-MWCNT-Pd with larger particle size was lower than np-MWCNT-Pd with smaller particle size.The steric hindrance from the octadecyl group did not reduce yield.Therefore, the higher yield of np-MWCNT-Pd was attributed to the higher interactions of the nonpolar np-MWCNT-Pd with nonpolar toluene.Figure 6a,b show yield as a function of time in DMF and toluene, respectively.As already mentioned, DMF was the better solvent with these catalysts, with yield reaching as high as 99.78% in 60 min.Yields were relatively lower and reaction times were longer in toluene, which was in line with what has been reported before [34,35].In the case of DMF, the reactions were completed in 60 min with the nanohybrids and it took 90 min with Pd/C.On the other hand, when toluene was the solvent, the time taken for the same reactions were 90 min with the nanohybrids, and 105 min with Pd/C.Yield enhancement of CNT-NM hybrids with respect to Pd/C for the Heck reaction at 60 min reaction time in both DMF and toluene are shown in Figure 6c,d.In DMF, the enhancements were 79% and 5% for p-MWCN-Pd and np-MWCN-Pd, respectively, while the corresponding enhancements in toluene were 32% and 60% in toluene.It is evident that the polarities of the functionalized form of catalysts and solvents is the important factor for catalytic activity.DMF is a better solvent than toluene for Heck reaction due to the greater dispersibility of the catalyst in DMF and high boiling point.High boiling point of the solvent enables the reaction to be carried out at a relatively higher temperature.Also, for catalysts containing polar groups (-COOH in this case), a polar aprotic solvent like DMF is a suitable solvent for Heck reaction.
The reason for higher yields in DMF compared to the toluene (Boiling Point (B.P); 110.6 • C) is due to the better dispersibility of catalyst in addition to the higher boiling point of DMF (B.P; 153 • C).Nevertheless, when toluene was used as the solvent, np-MWCNT-Pd showed significantly higher catalytic activity than p-MWCNT-Pd, which was better than Pd/C.These were also attributed to dispersibility of catalyst (refer to Figure 6).Hence, it is evident that disparities in the polarity play an important role.

Active Metal Requirement and Reusability
Since DMF was the better solvent, the catalyst requirement for CNT-NM was calculated.Typical Heck reaction with conventional palladium salts requires 1-2 mol % catalyst [34,35].In the present work with MWCNT-Pd hybrids, significantly lower quantities of Pd (order of 0.01 mol % Pd) resulted in higher yield at shorter reaction times.Therefore, this study showed that nan palladium on functionalized CNTs is more effective than conventional palladium salts.The turnover frequency (TOF) of the two catalysts were calculated as follows: Under reflux conditions, the TOF of p-MWCNT-Pd and np-MWCNT-Pd in DMF were 9977 and 5863, respectively, and in toluene 1090 and 977, respectively, which shows that the polar p-MWCNT-Pd in polar solvent has higher catalytic activity.Under microwave conditions, the TOF of p-MWCNT-Pd and o-MWCNT-Pd were 9000 and 6681, respectively.
An important issue has been the reusability of the catalyst.In the case of p-MWCNT-Pd and np-MWCNT-Pd, leaching of Pd from MWCNT support to hot DMF was demonstrated by carrying out a reaction under the aforementioned conditions and filtering the solid catalyst after 30 min while the mixture was still hot (around 150 • C).The filtrate was allowed to reflux in the absence of solid catalyst and yield from the reaction was determined.The yields were found to remain the same in the presence of the p-MWCNT-Pd as well as np-MWCNT-Pd.This demonstrated that Pd desorbed from the CNT support had remained suspended into the liquid phase in hot condition.
Irreversible leaching is a major consideration while dealing with solid catalysts due to depletion in the metal content and subsequent loss in activity.In another set of experiments in DMF with p-MWCNT-Pd and np-MWCNT-Pd, the recovered catalysts obtained by filtration after one hour reaction and subsequent cooling to room temperature were reused for a three consecutive reactions.The yield obtained with recovered catalysts in each step was within 2% of the previous step yield.This showed that there was no significant decrease in the catalytic activity of the recovered catalyst.This can be explained by "boomerang effect" [45][46][47] where catalyst which is dispersed into the bulk solution under the hot condition from the solid support redeposits under cold conditions.In order to study this, the reaction mixture (after 1-h reaction) was filtered in the hot condition to recover the catalyst.Similarly, the reaction mixture (after 1 h) was filtered after cooling to room temperature.The catalysts were analyzed for Pd content.The weight percent of Pd from the hot and cold conditions in the p-MWCNT-Pd were 11.9 and 22.9, respectively, as determined by EDX.This supported the existence of boomerang effect.In the future, poison testing will be conducted for these catalysts to understand the nature of catalysis which assist in designing next generation catalysts.

Conclusions
p-MWCNT-Pd and np-MWCNT-Pd were synthesized using a microwave induced reaction and they showed high catalytic activity compared to commercially available Pd/C.The CNT-Pd needed a smaller amount of active catalyst but led to faster reactions and higher yields.The best reaction conditions were found to be with DMF as solvent, TBA as base, and triphenylphosphine as ligand.While p-MWCNT-Pd showed better performance in polar DMF, np-MWCNT-Pd was more effective in toluene.Matching the polarity of CNT functionalization with that of the solvent is clearly an effective way to maximize yield.

Table 1 .
Particle size of dispersible CNT-NM.loading in the hybrid materials were quantified using TGA as shown in Figure 4.The resulting weight above 600 °C was attributed to the weight of residual metal.The nanohybrids were found to contain 43.02 and 38.93 percent by weight of Pd in p-MWCNT-Pd and np-MWCNT-Pd, respectively, while Pd/C contained 5% by weight of Pd.

Figure 4 .
The resulting weight above 600 • C was attributed to the weight of residual metal.The nanohybrids were found to contain 43.02 and 38.93 percent by weight of Pd in p-MWCNT-Pd and np-MWCNT-Pd, respectively, while Pd/C contained 5% by weight of Pd.Appl.Sci.2018, 8, x FOR PEER REVIEW 5 of 11

Figure 5 .
Figure 5.The role of CNT-Pd in the in the Heck reaction.Figure 5.The role of CNT-Pd in the in the Heck reaction.

Figure 5 .
Figure 5.The role of CNT-Pd in the in the Heck reaction.Figure 5.The role of CNT-Pd in the in the Heck reaction.

Figure 6 .
Figure 6.Yields of the CNT-metal nanohybrids and Pd/C catalyzed reactions (a) in DMF and (b) in toluene from GC analysis (Tri-butyl amine as base, temp 150 °C ); (c) yield enhancement with respect to Pd/C in DMF; (d) enhancement with respect to Pd/C in toluene.

Figure 6 .
Figure 6.Yields of the CNT-metal nanohybrids and Pd/C catalyzed reactions (a) in DMF and (b) in toluene from GC analysis (Tri-butyl amine as base, temp 150 • C); (c) yield enhancement with respect to Pd/C in DMF; (d) enhancement with respect to Pd/C in toluene.

Table 2 .Table 2 .
Isolated yields of all the reactions at completion.Analysis was done after recrystallization.