Thermoelectric voltage switching in gold atomic wire junctions

Saffarzadeh, Alireza; Demir, Firuz; Kirczenow, George

doi:10.1103/physrevb.98.115436

Cited by 5 publications

(5 citation statements)

References 60 publications

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“…Clearly, the conductance and Seebeck coefficient of molecular lines are closely related to the number of benzene rings in a chain structure composed of several identical units while the magnitude and sign of Seebeck can simultaneous change by alternate the anchoring group. Similarly, theoretical simulation also predict the interesting sign oscillation phenomenon of Seebeck coefficient when length of the molecule chain is increasing . It means that the transformation of thermoelectric devices from n‐type to p‐type can be easily realized by control the length of the molecular chain.…”

Section: Optimization Strategies For Ote Devicesmentioning

confidence: 68%

“…Similarly, theoretical simulation also predict the interesting sign oscillation phenomenon of Seebeck coefficient when length of the molecule chain is increasing. [155,156] It means that the transformation of thermoelectric devices from n-type to p-type can be easily realized by control the length of the molecular chain. The more direct evidence for size effect on thermoelectric performance regulation is the ZT value (electron contribution) can also increase with the number of benzene rings, [157] which usually indicates the enhancement of power factor (see Figure 10d).…”

Section: Size Effectmentioning

confidence: 99%

See 1 more Smart Citation

Nanoscale Organic Thermoelectric Materials: Measurement, Theoretical Models, and Optimization Strategies

Zeng

Cao

et al. 2019

Adv Funct Materials

119

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The demands for waste heat energy recovery from industrial production, solar energy, and electronic devices have resulted in increasing attention being focused on thermoelectric materials. Over the past two decades, significant progress is achieved in inorganic thermoelectric materials. In addition, with the proliferation of wireless mobile devices, economical, efficient, lightweight, and bio‐friendly organic thermoelectric (OTE) materials have gradually become promising candidates for thermoelectric devices used in room‐temperature environments. With the development of experimental measurement techniques, the manufacturing for nanoscale thermoelectric devices has become possible. A large number of studies have demonstrated the excellent performance of nanoscale thermoelectric devices, and further improvement of their thermoelectric conversion efficiency is expected to have a significant impact on global energy consumption. Here, the development of experimental measurement methods, theoretical models, and performance modulation for nanoscale OTE materials are summarized. Suggestions and prospects for the future development of these devices are also provided.

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Section: Optimization Strategies For Ote Devicesmentioning

confidence: 68%

Section: Size Effectmentioning

confidence: 99%

Nanoscale Organic Thermoelectric Materials: Measurement, Theoretical Models, and Optimization Strategies

Zeng

Cao

et al. 2019

Adv Funct Materials

119

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“…To do this, each one of the valence orbitals 4s, 4p x , 4p y , 4p z , 3d xy , 3d xz , 3d yz , 3d z 2 , and 3d x 2 −y 2 belonging to the ten (seven) farthest atoms of each electrode from the junction is connected to a onedimensional ideal lead representing electron reservoirs (see Figs. 1(a)-(d)) [8,[48][49][50][51][52]. The electron transmission amplitudes t ji (E) through the system consisting of the electrodes and water molecules are obtained by solving the Lippmann-Schwinger equation…”

Section: Theorymentioning

confidence: 99%

“…Metallic junctions and the process of their contact formation have been the subject of many experimental and theoretical studies exploring physical properties, such as electrical conduction [1][2][3][4], quantum interference [5][6][7] and thermoelectric energy conversion [7][8][9][10] at the atomic and molecular scales. Achieving control over the electronic transport properties of single atom contacts is crucial for the realization of practical nanoelectronic devices.…”

Section: Introductionmentioning

confidence: 99%

Mechanisms of jump to contact and conductance plateau formation in copper atomic junctions in vacuum and aqueous environments

Saffarzadeh,

Kirczenow

2020

Preprint

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The interplay between groups of water molecules and single-atom contacts, as reflected in the electrical conductances and mechanical forces of copper atomic junctions, is explored by means of first-principles theory and semi-empirical calculations. We study the influence of the atomic geometries of copper electrodes with pyramidal and non-crystalline structures in the presence and absence of water on the conductance profiles as the electrodes approach each other. It is shown that the atomic arrangements of nano-contacts have crucial effects on the formation of plateaus and the conductance values. Groups of hydrogen bonded water molecules bridge the junction electrodes before a direct Cu-Cu contact between the electrodes is made. However, the bridging of the two copper electrodes by a single H2O molecule only occurs in the junctions with pyramidal electrodes. Our findings reveal that the presence of H2O molecules modifies strongly the conductance profile of these junctions. In the absence of water molecules, the pyramidal junctions exhibit continuous transitions between integer conductance plateaus, while in the presence of H2O molecules, these junctions show abrupt jump to contact behavior and no well-defined conductance plateaus. By contrast, in the absence of H2O molecules, the non-crystalline junctions display jump to contact behavior and no well-defined plateaus, while in the presence of H2O molecules they exhibit a jump to contact and abrupt transitions between fractional and integer plateaus.

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“…In the past decade, Peltier cooling in nanoscopic systems has attracted enormous theoretical [9][10][11][12][13][14][15][16][17][18] and experimental [19][20][21][22][23][24][25][26][27][28] efforts. Thanks to the impressive advances in the synthesis, fabrication and manipulation of nano-sized materials, Peltier cooling has been realized in molecular junctions [19-21, 27, 28], organic thermoelectric flakes [22,26], and ferromagnetic/ferrimagnetic metal films [23][24][25].…”

mentioning

confidence: 99%

Kondo cooling in quantum impurity systems

Zeng¹,

Ye²,

Cao³

et al. 2022

Preprint

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The Peltier effect is the reverse phenomenon of the Seebeck effect, and has been observed experimentally in nanoscale junctions. However, despite its promising applications in local cooling of nanoelectronic devices, the role of strong electron correlations on such a phenomenon is still unclear. Here, by analyzing the thermoelectric properties of quantum impurity systems out of equilibrium, we unveil the essential role of electron-electron interactions and quantum resonant states in Peltier cooling, leading to the prediction of the Kondo cooling phenomenon. The existence of such Kondo cooling is validated by a reverse heat current and a lowered local temperature in a model junction. The discovery of this unconventional Peltier cooling offers a new approach toward nano-refrigeration, and highlights the unique role of strong electron correlations in nonequilibrium quantum systems.

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Thermoelectric voltage switching in gold atomic wire junctions

Cited by 5 publications

References 60 publications

Nanoscale Organic Thermoelectric Materials: Measurement, Theoretical Models, and Optimization Strategies

Nanoscale Organic Thermoelectric Materials: Measurement, Theoretical Models, and Optimization Strategies

Mechanisms of jump to contact and conductance plateau formation in copper atomic junctions in vacuum and aqueous environments

Kondo cooling in quantum impurity systems

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