4 article(s) from Lambert, Colin J
- Full Research Paper
- Published 08 Dec 2015
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Figure 1: Schematic of the proposed molecular switch, where the asymmetric rotor blade is terminated at one e...
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Figure 2: The potential energy profile, UBSC (eV), calculated from the changes in the total energy of the sys...
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Figure 3: (a) The molecular structure within the junction. (b) A contour plot of the local density of states ...
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Figure 4: The weighted current (blue curve) from Equation 5 and the NDR (green curve, dI/dV) for applied bias between 0...
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Supp. Info
- Full Research Paper
- Published 26 Jun 2015
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Figure 1: Porphyrin SET molecular structure. a) Porphyrin molecule with butterfly backbone, b) the device str...
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Figure 2: a) HOMO−1, b) HOMO, c) LUMO and d) LUMO+1 state iso-surfaces.
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Figure 3: Molecular and electronic structure of the EBG electrodes. a) Molecular orbital iso-surfaces, b) ban...
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Figure 4: Conductance, G/G0, as a function of the Fermi energy, EF, of the EBG electrodes shown in Figure 1b.
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Figure 5: Nonequilibrium I–V characteristic of the PM–EBG device.
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Figure 6: Tight-binding model of the PM–EBG device. (a) Schematic of the simplified device for tight-binding ...
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Figure 7: Thermal properties of the PM–EBG device. Thermopower (blue) and thermal conductance (green) as a fu...
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- Full Research Paper
- Published 18 May 2015
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Figure 1: Geometry of the graphene-based structures, (a) monolayer graphene ribbon, (b) monolayer graphene na...
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Figure 2: (a) Transmission coefficient T(E); (b,c) electrical and thermal conductance (G, κ), (d,e) Peltier (...
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Figure 3: (a) Transmission coefficient T(E); (b) electrical conductance (G), (c) Peltier (П) coefficient, (d)...
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Figure 4: (a) Ideal step function like transmission coefficient T(E) asymmetric around Fermi energy (E = 0), ...
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Figure 5: The variation of room-temperature values of ZTe, GS2T, S and κ as a function of the Fermi energy EF...
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Figure 6: The variation of room-temperature values of ZTe, GS2T, S and κ as a function of EF for zigzag bilay...
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- Full Research Paper
- Published 18 Oct 2011
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Figure 1: Molecular structures of AC, AQ, and AH.
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Figure 2: (A) Schematics of the system configuration and (B) pictures of the mechanical part in the MCBJ setu...
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Figure 3: Conductance and voltage output for the piezo stack versus time for 0.1 mM AC in THF/decane (v:v = 1...
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Figure 4: Individual conductance–distance traces and histogram constructed from these sets of three traces fo...
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Figure 5: (A–C) Individual current–voltage curves of (A) a gold–gold contact, (B) a gold|AC|gold molecular ju...
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Figure 6: (A) 2-D I–V histogram constructed from 2500 individual traces recorded during a current–distance st...
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Figure 7: Conductance histograms of 0.1 mM AC in THF/decane (v:v = 1:4). Black: From 500 current–distance str...
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Figure 8: 1-D conductance histograms and conductance–distance 2-D histograms constructed from 500 individual ...
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Figure 9: Plateau-length distributions (black) and Gaussian fits (red) of (A) AC (B) AQ (C) AH and (D) the bl...
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Figure 10: Model of the breaking process of the Au|AC|Au junction. (A) A typical trace with labels indicating ...
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