Conductance of a single molecule anchored by an isocyanide substituent to gold electrodes
スポンサーリンク
概要
- 論文の詳細を見る
The effect of anchoring group on the electrical conductance of a single molecule bridging two Au electrodes was studied using disubstituted [isocyanide (CN–), thiol (S–), or cyanide (NC–)] benzene. The conductance of a single Au/1,4-diisocyanobenzene/Au junction anchored by isocyanide via a C atom (junction with the Au–CN bond) was 3×10−3G0(=2e2/h). The value was comparable to 4×10−3G0 of a single Au/1,4-benzenedithiol/Au junction with the Au–S bond. The Au/1,4-dicyanobenzene/Au molecular junction with the Au–NC bond did not show well-defined conductance values. The metal-molecule bond strength was estimated by the distance over which the molecular junction was stretched before breakdown. The stretched length of the molecular junction with the Au–CN bond was comparable to that of the Au junction, indicating that the Au–CN bond was stronger than the Au–Au bond. ©2006 American Institute of Physics
- 2006-11-21
著者
関連論文
- Conductance of single 1,4-disubstituted benzene molecules anchored to Pt electrodes
- Conductance of a single molecule anchored by an isocyanide substituent to gold electrodes
- Phosphine Sulfides as an Anchor Unit for Single Molecule Junctions
- The effect of hydrogen evolution reaction on conductance quantization of Au, Ag, Cu nanocontacts
- Quantized conductance behavior of Pt metal nanoconstrictions under electrochemical potential control
- Fabrication of stable metal nanowire showing conductance quantization in solution
- Conductance bistability of gold nanowires at room temperature
- Mechanical fabrication of metal nano contacts showing conductance quantization under electrochemical potential control
- Electrochemical Potential Control of Stretched Length of Au Nano-wire in Solution
- Fabrication of sustainable Au mono-atomic wire showing conductance quantization in solution
- 26pRJ-10 Evolution of a nano-gap fabricated by mechanically controlled breaking
- 26pTG-2 Conductance of single C_ molecule bridging between Au electrodes in solution