Synthesis and Characterisation of Linear and Towards Cyclic Diferrocenes with Alkynyl Spacers

: Ferrocenediyl systems offer a motif that incorporates multiple functionality and redox-active centers, enabling these units to be used as molecular scaffolds in linear and cyclic compounds. Herein, we discuss a new modular methodology for the synthesis and incorporation of ferrocenediyl motifs within extended conjugated systems. We have synthesized a family of compounds featuring ferrocenediyl-ethynyl units with various para -substituted aromatic linkages. Extended linear, open-chain species have been isolated and understanding towards the analogous cyclic compounds gained. The new compounds have been probed using NMR, mass spectrometry, cyclic voltammetry and X-ray crystallography to gain further understanding of their structural and electronic properties. was at for 3 days. removed and on a silica 2 Cl 2 to


Introduction
The stability and redox activity of ferrocene has made it an attractive structural component and lead to the incorporation of the motif into many organometallic structures. Ferrocene units can also supply structural control and flexibility [1]. These are contributing factors that have led to its utilization in many applications including molecular wires [2][3][4], switches [5] and sensors [6].
In recent years, high density ferrocene-containing structures have become an important sub-section of ferrocene chemistry. Preliminary contributions were in the form of star and dendrimeric structures [7,8]. Such systems have now been developed to display remarkable electronic properties including exceptionally fast electron exchange properties and use in ion sensing [9,10].
Recently, there has been a drive to incorporate ferrocene motifs within macrocyclic structures. These systems offer the potential to study interference effects, redox behavior and conductance. Cyclic structures have been developed that contain closely bound ferrocene units and those which are separated by linker groups. Within these systems, phenyl linker groups have been used with both the ortho and meta substitution patterns but a para derivative has not yet been reported [11][12][13].
In our group, we have designed several macrocyclic structures which contain para-substituted phenyl rings connected to two ferrocene units. The paper discusses the progression in synthesizing components of multi-ferrocene containing macrocycles and the study of the linker groups between them, alongside their physical and electrochemical properties, and illustrates the difficulties in moving towards fully cyclic structures.

Synthesis and Characterisation
The designed route to the para-substituted open chained diferrocenediyl compounds is displayed in Figure 1. Each bridged diferrocenediyl species was synthesized through a Sonogashira coupling of 1,1 -diiodoferrocene with the arene linking units terminated with ethynyl ligands utilizing the widely reported Pd(P t Bu 3 ) 2 catalyst [14]. The linker groups were chosen due to their potential for π-stacking between the arene rings and their facile electronic communication, as noted in our previous work [15,16]. Compound 2 has an increased length in comparison to compound 1 which is expected to alter the communication between the ferrocene centers while compound 3 offers the potential for increased solubility.
The desired compounds were achieved as the most prevalent products from the respective reactions by using an excess of 1,1 -diiodoferrocene compared to the arene linker to reduce the potential for polymerization products. Compound 1 was synthesized in reasonable yields (43%) by a Sonogashira coupling of 1,1 -diiodoferrocene with the difunctionalised arene, and utilizing the Pd(0) catalyst Pd( t Bu 3 ) 2 , followed by purification via column chromatography on silica gel. The same procedure was utilized to synthesize compounds 2 and 3 in 27% and 60% yields respectively. All products were characterized by NMR spectroscopy, mass spectrometry, elemental analysis and in the case of 1, X-ray crystallography. NMR experiments gave largely expected data in terms of chemical shifts and coupling constants (see experimental section for details) and the spectra of the 1 H NMR, 13  The designed route to the para-substituted open chained diferrocenediyl compounds is displayed in Figure 1. Each bridged diferrocenediyl species was synthesized through a Sonogashira coupling of 1,1′-diiodoferrocene with the arene linking units terminated with ethynyl ligands utilizing the widely reported Pd(P t Bu3)2 catalyst [14]. The linker groups were chosen due to their potential for π-stacking between the arene rings and their facile electronic communication, as noted in our previous work [15,16]. Compound 2 has an increased length in comparison to compound 1 which is expected to alter the communication between the ferrocene centers while compound 3 offers the potential for increased solubility.
The desired compounds were achieved as the most prevalent products from the respective reactions by using an excess of 1,1′-diiodoferrocene compared to the arene linker to reduce the potential for polymerization products. Compound 1 was synthesized in reasonable yields (43%) by a Sonogashira coupling of 1,1′-diiodoferrocene with the difunctionalised arene, and utilizing the Pd(0) catalyst Pd( t Bu3)2, followed by purification via column chromatography on silica gel. The same procedure was utilized to synthesize compounds 2 and 3 in 27% and 60% yields respectively. All products were characterized by NMR spectroscopy, mass spectrometry, elemental analysis and in the case of 1, X-ray crystallography. NMR experiments gave largely expected data in terms of chemical shifts and coupling constants (see experimental section for details) and the spectra of the 1 H NMR, 13   Cyclisation of compounds 1 and 3 (reactions involving compound 2 were too insoluble to give meaningful data) was then attempted with the second bridge to be inserted being the same bridging arene ligand already located within the compound. Reactions were carried out under high dilution conditions in DIPA and THF, again under Sonagashira coupling conditions. Unfortunately, no cyclic products could be identified in any of these products however, an array of new linear diferrocenediyl systems were formed ( Figure 2). For 1 and 3, the main products from the reaction were the openchained systems (compounds 4 and 5). Compound 4 was purified by column chromatography and identified by NMR spectrometry and mass spectrometry. In the 1 H NMR spectrum ( Figure S4), the multiplets at δ 7.40 to 7.30 ppm correspond to the eight H atoms on the two phenyl rings. The pseudo triplets at δ 4.49, 4.46, 4.28 and 4.30 ppm are all signals due to the iodoferrocene unit while the peaks at δ 4.55 and 4.35-4.33 ppm are due to the other ferrocene unit. Both these peaks are due to the overlaying of two pseudo triplets due to the asymmetry around this ferrocene unit. Furthermore, the singlet at δ 3.16 ppm corresponds to the proton on the terminal alkyne. Mass spectrometry showed a peak at m/z 743.98 (expected m/z 743.97). Compound 5 was more difficult to purify but was identified via mass spectrometry, with three overlapping product bands being observed on the column that could not be fully separated.
The unfortunate lack of cyclisation reactions under these conditions could be due to a high energy cyclisation barrier, steric strain and/or the conformation of the starting ferrocenediyl unit making cyclisation reaction difficult. Changing some of the reaction conditions could improve the Cyclisation of compounds 1 and 3 (reactions involving compound 2 were too insoluble to give meaningful data) was then attempted with the second bridge to be inserted being the same bridging arene ligand already located within the compound. Reactions were carried out under high dilution conditions in DIPA and THF, again under Sonagashira coupling conditions. Unfortunately, no cyclic products could be identified in any of these products however, an array of new linear diferrocenediyl systems were formed ( Figure 2). For 1 and 3, the main products from the reaction were the open-chained systems (compounds 4 and 5). Compound 4 was purified by column chromatography and identified by NMR spectrometry and mass spectrometry. In the 1 H NMR spectrum ( Figure S4), the multiplets at δ 7.40 to 7.30 ppm correspond to the eight H atoms on the two phenyl rings. The pseudo triplets at δ 4.49, 4.46, 4.28 and 4.30 ppm are all signals due to the iodoferrocene unit while the peaks at δ 4.55 and 4.35-4.33 ppm are due to the other ferrocene unit. Both these peaks are due to the overlaying of two pseudo triplets due to the asymmetry around this ferrocene unit. Furthermore, the singlet at δ 3.16 ppm corresponds to the proton on the terminal alkyne. Mass spectrometry showed a peak at m/z 743.98 (expected m/z 743.97). Compound 5 was more difficult to purify but was identified via mass spectrometry, with three overlapping product bands being observed on the column that could not be fully separated.
The unfortunate lack of cyclisation reactions under these conditions could be due to a high energy cyclisation barrier, steric strain and/or the conformation of the starting ferrocenediyl unit making cyclisation reaction difficult. Changing some of the reaction conditions could improve the result and lead to cyclisation. For example, the use of even higher dilution to further reduce the chance of the formation of linear of polymeric by-products; or a decrease in reaction temperature to limit the movement and conformational freedom of the molecule.
Inorganics 2018, 6, x FOR PEER REVIEW 3 of 8 result and lead to cyclisation. For example, the use of even higher dilution to further reduce the chance of the formation of linear of polymeric by-products; or a decrease in reaction temperature to limit the movement and conformational freedom of the molecule.

X-ray Crystallography
The structure of 1 ( Figure 3) was determined by single-crystal X-ray diffraction of crystals grown by solvent layering of n-hexane/CH2Cl2. Selected bond lengths are shown in Table 1. The structure shows a trans-conformation of the ferrocene units with the iodine atoms pointing into the structure. The structure of 1 was found to sit across a center of symmetry at the middle of the C6H4 ring.

Electrochemistry
The electrochemical properties of complexes 1, 2 and 3 were studied to probe the communication through the bridging units. Cyclic voltammetry (CV) and differential potential voltammetry (DPV) experiments were run in a 0.1 M solution of [( n Bu)4N]PF6 in DCM. Relevant data are summarized in

X-ray Crystallography
The structure of 1 (Figure 3) was determined by single-crystal X-ray diffraction of crystals grown by solvent layering of n-hexane/CH 2 Cl 2 . Selected bond lengths are shown in Table 1. The structure shows a trans-conformation of the ferrocene units with the iodine atoms pointing into the structure. The structure of 1 was found to sit across a center of symmetry at the middle of the C 6 H 4 ring. result and lead to cyclisation. For example, the use of even higher dilution to further reduce the chance of the formation of linear of polymeric by-products; or a decrease in reaction temperature to limit the movement and conformational freedom of the molecule.

X-ray Crystallography
The structure of 1 (Figure 3) was determined by single-crystal X-ray diffraction of crystals grown by solvent layering of n-hexane/CH2Cl2. Selected bond lengths are shown in Table 1. The structure shows a trans-conformation of the ferrocene units with the iodine atoms pointing into the structure. The structure of 1 was found to sit across a center of symmetry at the middle of the C6H4 ring.

Electrochemistry
The electrochemical properties of complexes 1, 2 and 3 were studied to probe the communication through the bridging units. Cyclic voltammetry (CV) and differential potential voltammetry (DPV) experiments were run in a 0.1 M solution of [( n Bu)4N]PF6 in DCM. Relevant data are summarized in Table 2 and displayed in Figure 4.

Electrochemistry
The electrochemical properties of complexes 1, 2 and 3 were studied to probe the communication through the bridging units. Cyclic voltammetry (CV) and differential potential voltammetry (DPV) experiments were run in a 0.1 M solution of [( n Bu) 4 N]PF 6 in DCM. Relevant data are summarized in Table 2 and displayed in Figure 4.    Compounds 1, 2 and 3 display a reversible redox event at an E1/2 close to 260 mV, with the values of 1 and 3 being indistinguishable and those for 2 being at a slightly lower potential. This could be due less stabilization of the charges on the ferrocenes across the biphenyl bridge of 2 in comparison to 1 and 3.
With ip ∝ vs 1/2 , this suggests that a purely diffusion based process is observed for all these compounds. These systems also show an ipa/ipc ≈ 1, suggestive of a reversible system i.e., a value of ∆E ≈ 59 mV is expected for a reversible one-electron exchange. This value was found for compound 2 but larger values were found for 1 and 3. This could be due to broadening of the peaks due to a low level of communication between the ferrocene centers over the bridge. This argument is further strengthened by an increase in the FWHM value of 1 and 3 in the DPV spectra ( Figure 4 right and Figures S5-S7).
The low levels of communication in all these systems is expected to be due to the rotation of the bridging motifs between the metals centers. This is further decreased in 2 due to increased rotation of the two (as opposed to single) rings [17].
In conclusion, within this paper we have reported the synthesis of several new linear, openchain conjugated ferrocenediyl molecules. We have described a modular, step-wise methodology that also has the potential to lead to a range of cyclic, ferrocenediyl systems featuring bridging diethynyl-arene units. The Sonagashira-coupling synthetic methodology displays good yields and versatility in the products that can be produced. The compounds have been probed through crystallography, electrochemistry and NMR analysis. The synthetic methodology will enable the synthesis of a wider range and more complex ferrocene-containing molecules, moving towards fully macrocyclic compounds under optimal reaction conditions. Compounds 1, 2 and 3 display a reversible redox event at an E 1/2 close to 260 mV, with the values of 1 and 3 being indistinguishable and those for 2 being at a slightly lower potential. This could be due less stabilization of the charges on the ferrocenes across the biphenyl bridge of 2 in comparison to 1 and 3.
With i p ∝ v s 1/2 , this suggests that a purely diffusion based process is observed for all these compounds. These systems also show an i pa /i pc ≈ 1, suggestive of a reversible system i.e., a value of ∆E ≈ 59 mV is expected for a reversible one-electron exchange. This value was found for compound 2 but larger values were found for 1 and 3. This could be due to broadening of the peaks due to a low level of communication between the ferrocene centers over the bridge. This argument is further strengthened by an increase in the FWHM value of 1 and 3 in the DPV spectra ( Figure 4 right and Figures S5-S7). The low levels of communication in all these systems is expected to be due to the rotation of the bridging motifs between the metals centers. This is further decreased in 2 due to increased rotation of the two (as opposed to single) rings [17].
In conclusion, within this paper we have reported the synthesis of several new linear, open-chain conjugated ferrocenediyl molecules. We have described a modular, step-wise methodology that also has the potential to lead to a range of cyclic, ferrocenediyl systems featuring bridging diethynyl-arene units. The Sonagashira-coupling synthetic methodology displays good yields and versatility in the products that can be produced. The compounds have been probed through crystallography, electrochemistry and NMR analysis. The synthetic methodology will enable the synthesis of a wider range and more complex ferrocene-containing molecules, moving towards fully macrocyclic compounds under optimal reaction conditions.

Experimental
General: All reactions were performed using standard air sensitive chemistry and Schlenk line techniques under an atmosphere of nitrogen. No special precautions were taken to exclude air during the work-up. Solvents used in reactions were collected from solvent towers sparged with nitrogen and dried with 3 Å molecular sieves, apart from diisopropylamine (DIPA), which was distilled onto activated 3 Å molecular sieves. 1,1 -Diiodoferrocene [18], 4,4 -diethynyl-1,1 -biphenyl [19] and 2,5-diethynyl-1,4-dioctyloxybenzene [20] were prepared via literature procedures from commercially available starting materials. All other compounds were purchased from commercial suppliers and used without further purification. 1  A solution of 1,1 -diiodoferrocene (6.00 g, 13.73 mmol) in dry DIPA (30 mL) was added to an oven-dried Schlenk flask and was degassed under N 2 for 10 min. 1,4-Diethynylbenzene (150 mg, 1.29 mmol) and CuI (15 mg, 0.079 mmol) were added to the solution against the flow of N 2 and degassed for a further 10 min. Pd(P t Bu 3 ) 2 (40 mg, 0.78 mmol) were added to the solution against the flow of N 2 and the reaction mixture was stirred overnight at room temperature covered with aluminum foil. The solvent was removed and the crude product was purified by silica gel column chromatography, eluted with n-hexane/CH 2 Cl 2 (1:0 → 0:1 v/v) to gain the product as a red-orange powder (381 mg, 43%). 1

Synthesis of Compound 2
A solution of 1,1 -diiodoferrocene (4.38 g, 10 mmol) in dry DIPA (25 mL) was added to an oven-dried Schlenk tube and was degassed under N 2 for 10 min. 4,4 -Diethynyl-1,1 -biphenyl (200 mg, 10 mmol) and CuI (9.5 mg, 0.05 mmol) were added to the solution against the flow of N 2 and degassed for a further 10 min. Pd(P t Bu 3 ) 2 (77 mg, 0.15 mmol) were added to the solution against the flow of N 2 and the reaction mixture was stirred overnight at room temperature covered with aluminium foil. The solvent was removed and the crude product was purified by chromatography on a silica column, eluted with n-hexane/CH 2 Cl 2 (1:0 → 0:1 v/v) to gain the product as an orange powder (216.4 mg, 27%). 1  A solution of 1,1 -diiodoferrocene (2.29 g, 5.23 mmol) in dry DIPA (15 mL) was added to an oven-dried Schlenk tube and was degassed under N 2 for 10 min. 2,5-Diethynyl-1,4-dioctyloxybenzene (200 mg, 0.52 mmol) and CuI (5 mg, 0.026 mmol) were added to the solution against the flow of N 2 and degassed for a further 10 min. Pd(P t Bu 3 ) 2 (40 mg, 0.078 mmol) were added to the solution against the flow of N 2 and the reaction mixture was stirred overnight at room temperature covered with aluminium foil. The solvent was removed and the crude product was purified by chromatography on a silica column, eluted with n-hexane/CH 2 Cl 2 (1:0 → 0.8:0.2 v/v) to gain the product as an red-orange solid (312 mg, 60%). 1

Synthesis of Compound 4
Compound 1 (100 mg, 0.135 mmol), 1,4-diethynylbenzene (17 mg, 0.135 mmol), CuI (0.5 mg 0.0027 mmol) and THF (70 mL) were combined under N 2 and degassed for 10 min. DIPA ( 30 mL) was added to the solution and degassed for a further 10 min. Pd(P t Bu 3 ) 2 (3.4 mg, 0.00675 mmol) was added against a flow of N 2 . The reaction was stirred at room temperature for 3 days. The solvent was removed and the crude product was purified by chromatography on a silica column, eluted with n-hexane/CH 2 Cl 2 (1:0 → 0:1 v/v) to gain the product as an orange solid (312 mg, 60%). 1  Compound 2 (111 mg, 0.135 mmol), 2,5-diethynyl-1,4 dioctyloxybenzene (52 mg, 0.135 mmol), CuI (0.5 mg 0.0027 mmol) and THF (70 mL) were combined under N 2 and degassed for 10 min. DIPA (30 mL) was added to the solution and degassed for a further 10 min. Pd(P t Bu 3 ) 2 (3.4 mg, 0.00675 mmol) was added against a flow of N 2 . The reaction was stirred at room temperature for 3 days. The solvent was removed and the crude product was attempted to be purified by repeated chromatography on silica or alumina columns, eluting with varying ratios of n-hexane/CH 2 Cl 2 . Three products were identified on the columns but could not be fully separated to

Conflicts of Interest:
The authors declare no conflict of interest.