Synthesis and Single‐Molecule Conductance Study of Redox‐Active Ruthenium Complexes with Pyridyl and Dihydrobenzo[b]thiophene Anchoring Groups

Abstract: The ancillary ligands 4'-(4-pyridyl)-2,2':6',2''-terpyridine and 4'-(2,3-dihydrobenzo[b]thiophene)-2,2'-6',2"-terpyridine were used to synthesize two series of mono- and dinuclear ruthenium complexes differing in their lengths and anchoring groups. The electrochemical and single-molecular conductance properties of these two series of ruthenium complexes were studied experimentally by means of cyclic voltammetry and the scanning tunneling microscopy-break junction technique (STM-BJ) and theoretically by means o… Show more

“…[23][24][25] The wide agreement between conductance data obtained for OPE3 junctions in different research groups, makes this an excellent candidate for a systematic study on the influence of side and end-groups. We chose the very stable dihydrobenzo[b]thiophene (DHBT) anchor as this group is known to bind efficiently to metal electrodes, with high junction formation probability, [26][27][28] and without the problems associated with thiol anchors, such as oxidation and formation of metal-thiolate clusters. 29 We demonstrate that these molecules possess the highly versatile structural features that are required for thermal conductance studies.…”

Electronic conductance and thermopower of single-molecule junctions of oligo(phenyleneethynylene) derivatives

“…[23][24][25] The wide agreement between conductance data obtained for OPE3 junctions in different research groups, makes this an excellent candidate for a systematic study on the influence of side and end-groups. We chose the very stable dihydrobenzo[b]thiophene (DHBT) anchor as this group is known to bind efficiently to metal electrodes, with high junction formation probability, [26][27][28] and without the problems associated with thiol anchors, such as oxidation and formation of metal-thiolate clusters. 29 We demonstrate that these molecules possess the highly versatile structural features that are required for thermal conductance studies.…”

Electronic conductance and thermopower of single-molecule junctions of oligo(phenyleneethynylene) derivatives

“…Creutz-Taube complex, (b) [(tpy)Ru(L)Ru(tpy)] m+ complexes, [69][70][71] (c) [(tpy)Ru II (L)Co III (tpy)] 5+ complexes displaying directional electron transfer, 72,73 (d) [(tpy)Ru II (L)Os II (tpy)] 4+ complexes displaying directional energy transfer. 74,75 six-coordinate bis-terimine 83,84 and ter-bisimine 46,81,82 Cr III complexes.…”

“…[64][65][66][67][68] When applied to back-to-back bis-terpyridine bridging ligands L in [(tpy)Ru(L)Ru(tpy)] 5+ (Fig. 2b), the associated theories successfully rationalized the exponential decrease of the electronic interaction parameter with increasing intermetallic separations [69][70][71] and the magnification of both through-bond electron transfer (Fig. 2c) 72,73 and energy transfer ( Fig.…”

Cr^IIIas an alternative to Ru^IIin metallo-supramolecular chemistry

“…To wards functionalm olecular electronic devices, intensive studies have been focused on charge transport characterization of single-molecule junctions with functional units to revealt he role of the molecular structure, [1,2,3] anchoring group, [1,4] environment, [5,6] external stimuli, [7,8,9] and electrode materials [10,11,12] in the charget ransport process.R ecently, chemicalr esponsive molecular junctionsh ave received intensive interestf or their potential in the sensing of surrounding environments throught he charge transport characterizationa t the single-molecule scale, such as pH and ions. Scullion et al have reportedac onductancec hangeo f1 7t imes in peptide single-molecule junctions triggered by pH change.…”

Quantum Interference Enhanced Chemical Responsivity in Single‐Molecule Dithienoborepin Junctions