Thermal and Thermoelectric Properties of Molecular Junctions

Wang, Kun; Meyhöfer, Edgar; Reddy, Pramod

doi:10.1002/adfm.201904534

Cited by 86 publications

(77 citation statements)

References 147 publications

(208 reference statements)

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“…Thermal properties of molecular wires can be determined using modifications to these and other methods. [27][28][29][30] Molecular junctions are widely investigated using computational methods. Charge transport simulations using molecular orbitals derived from density functional theory (DFT) or Hückel (tight-binding) theory are used to calculate transmission functions for molecular junctions.…”

Section: Experimental and Computational Methodsmentioning

confidence: 99%

“…91 Notably, the Seebeck coefficient of a molecular junction is independent of the number of molecules present. 28 This means that unlike studies of electrical conductance, comparisons can be made between materials and methods without needing to estimate the number of molecules present in an ensemble junction. Thermal conductance measurements of SAMs are possible, but so far are largely limited to alkane species.…”

Section: A History Of Oaes In Molecular Electronicsmentioning

confidence: 99%

“…This section is concerned with the measurement of thermal properties of OAEs in molecular junctions. Molecular wires such as OPEs have been proposed as candidate materials for low-cost, environmentally-friendly thermoelectric generators, [27][28][29] i.e. devices that can harvest (waste) heat and transform it into electricity.…”

Section: Thermoelectric Properties Of Oaesmentioning

confidence: 99%

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A review of oligo(arylene ethynylene) derivatives in molecular junctions

O’Driscoll

Bryce

2021

Nanoscale

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Section: Experimental and Computational Methodsmentioning

confidence: 99%

Section: A History Of Oaes In Molecular Electronicsmentioning

confidence: 99%

Section: Thermoelectric Properties Of Oaesmentioning

confidence: 99%

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A review of oligo(arylene ethynylene) derivatives in molecular junctions

O’Driscoll

Bryce

2021

Nanoscale

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“…During the past two decades, the development of experimental techniques made it possible to measure the thermoelectric properties at the level of single molecules, providing new insights into different aspects of structure-function relationship in single-molecule junctions (recently reviewed by Wang et al 7 ). For instance, experimental techniques such as scanning tunneling microscope break junction (STM-BJ) 8 – 11 , mechanically controllable break junction (MCBJ) 12 , 13 and electromigrated break junction (EMBJ) 14 were developed to measure the thermopower of single-molecule junctions connected to metal electrodes—mostly made of gold (Au)—to form a metal-molecule-metal structure.…”

Section: Introductionmentioning

confidence: 99%

Side-group-mediated thermoelectric properties of anthracene single-molecule junction with anchoring groups

Akbarabadi

Soleimani

Tagani

2021

Sci Rep

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Charge transfer characteristics of single-molecule junctions at the nanoscale, and consequently, their thermoelectric properties can be dramatically tuned by chemical or conformational modification of side groups or anchoring groups. In this study, we used density functional theory (DFT) combined with the non-equilibrium Green’s function (NEGF) formalism in the linear response regime to examine the thermoelectric properties of a side-group-mediated anthracene molecule coupled to gold (Au) electrodes via anchoring groups. In order to provide a comparative inspection three different side groups, i.e. amine, nitro and methyl, in two different positions were considered for the functionalization of the molecule terminated with thiol or isocyanide anchoring groups. We showed that when the anchored molecule is perturbed with side group, the peaks of the transmission spectrum were shifted relative to the Fermi energy in comparison to the unperturbed molecule (i.e. without side group) leading to modified thermoelectric properties of the system. Particularly, in the thiol-terminated molecule the amine side group showed the greatest figure of merit in both positions which was suppressed by the change of side group position. However, in the isocyanide-terminated molecule the methyl side group attained the greatest thermoelectric efficiency where its magnitude was relatively robust to the change of side group position. In this way, different combinations of side groups and anchoring groups can improve or suppress thermopower and the figure of merit of the molecular junction depending on the interplay between charge donating/accepting nature of the functionals or their position.

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“…To deliberately supress or switch off the nearfield trapping in the hotspot region (experimental details in Note S8), we defocus the laser in a controlled way or block the laser immediately after a set of experiments (see Figures S12 and 13). The first additional control allows us to exclude far-field effects related to laser illumination, like photocurrent 34 or photo-thermal effects, 52 that could influence the conductance and the stability of the single-molecule junction. Turning off the laser immediately after a power-dependent experiment, on the other hand, allows us to confirm the reversibility of the plasmon-supported enhancement of τ.…”

Section: Nearfield Trapping and Junction Breakdown Behaviourmentioning

confidence: 99%

Nearfield trapping increases lifetime of single-molecule junction by one order of magnitude

Aragonès

Domke

2020

Preprint

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Progress in molecular electronics (ME) is largely based on improved understanding of the properties of single molecules (SM) trapped for seconds or longer to enable their detailed characterization. We present a plasmon-supported break-junction (PBJ) platform to significantly increase the lifetime of SM junctions of 1,4-benzendithiol (BDT) without the need for chemical modification of molecule or electrode. Moderate far-field power densities of ca. 11 mW/µm2 lead to a >10-fold increase in minimum lifetime compared to laser-OFF conditions. The nearfield trapping efficiency is twice as large for bridge-site contact compared to hollow-site geometry, which can be attributed to the difference in polarizability. Current measurements and tip-enhanced Raman spectra confirm that native structure and contact geometry of BDT are preserved during the PBJ experiment. By providing a non-invasive pathway to increase short lifetimes of SM junctions, PBJ is a valuable approach for ME, paving the way for improved SM sensing and recognition platforms.

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Thermal and Thermoelectric Properties of Molecular Junctions

Cited by 86 publications

References 147 publications

A review of oligo(arylene ethynylene) derivatives in molecular junctions

A review of oligo(arylene ethynylene) derivatives in molecular junctions

Side-group-mediated thermoelectric properties of anthracene single-molecule junction with anchoring groups

Nearfield trapping increases lifetime of single-molecule junction by one order of magnitude

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Thermal and Thermoelectric Properties of Molecular Junctions

Cited by 86 publications

References 147 publications

A review of oligo(arylene ethynylene) derivatives in molecular junctions

A review of oligo(arylene ethynylene) derivatives in molecular junctions

Side-group-mediated thermoelectric properties of anthracene single-molecule junction with anchoring groups

Nearfield trapping increases lifetime of&nbsp;single-molecule junction by one order of magnitude

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Nearfield trapping increases lifetime of single-molecule junction by one order of magnitude