Comprehensive suppression of single-molecule conductance using destructive σ-interference

Garner, Marc H.; Li, Haixing; Chen, Yan; Su, Timothy A.; Shangguan, Zhichun; Paley, Daniel W.; Liu, Taifeng; Ng, Fay; Li, Hexing; Xiao, Shengxiong; Nuckolls, Colin; Venkataraman, Latha; Solomon, Gemma C.

doi:10.1038/s41586-018-0197-9

“…Quantum interference (QI) offers the unique opportunity to tune charge transport through molecular devices and materials, [1] which leads to various applications such as QIbased thermoelectrics, [2] molecular memory, [3] molecular transistors, [4] and sensors. [5] Them olecular building blocks play avital role in investigating QI-based molecular junctions.…”

mentioning

confidence: 99%

“…

Molecular components are vital to introduce and manipulate quantum interference (QI) in charge transport through molecular electronic devices.Uptonow,the functional molecular units that show QI are mostly found in conventional p-a nd s-bond-based systems;i ti st hus intriguing to study QI in multicenter bonding systems without both p-a nd sconjugations.N ow the presence of QI in multicenter-bondbased systems is demonstrated for the first time,t hrough the single-molecule conductance investigation of carborane junctions.W ef ind that all the three connectivities in carborane frameworks showdifferent levels of destructive QI, which leads to highly suppressed single-molecule conductance in para-and meta-connected carboranes.T he investigation of QI into carboranes provides ap romising platform to fabricate molecular electronic devices based on multicenter bonds.Quantum interference (QI) offers the unique opportunity to tune charge transport through molecular devices and materials, [1] which leads to various applications such as QIbased thermoelectrics, [2] molecular memory, [3] molecular transistors, [4] and sensors. [5] Them olecular building blocks play avital role in investigating QI-based molecular junctions.

…”

mentioning

confidence: 99%

Multicenter‐Bond‐Based Quantum Interference in Charge Transport Through Single‐Molecule Carborane Junctions

Tang

¹

,

Chen

²

,

Zhang

³

et al. 2019

View full text Add to dashboard Cite

Molecular components are vital to introduce and manipulate quantum interference (QI) in charge transport through molecular electronic devices.Uptonow,the functional molecular units that show QI are mostly found in conventional p-a nd s-bond-based systems;i ti st hus intriguing to study QI in multicenter bonding systems without both p-a nd sconjugations.N ow the presence of QI in multicenter-bondbased systems is demonstrated for the first time,t hrough the single-molecule conductance investigation of carborane junctions.W ef ind that all the three connectivities in carborane frameworks showdifferent levels of destructive QI, which leads to highly suppressed single-molecule conductance in para-and meta-connected carboranes.T he investigation of QI into carboranes provides ap romising platform to fabricate molecular electronic devices based on multicenter bonds.Quantum interference (QI) offers the unique opportunity to tune charge transport through molecular devices and materials, [1] which leads to various applications such as QIbased thermoelectrics, [2] molecular memory, [3] molecular transistors, [4] and sensors. [5] Them olecular building blocks play avital role in investigating QI-based molecular junctions. Up to now,the molecular building blocks with QI are mostly found in conventional two-center-two-electron (2c-2e) bondbased systems,w hich lead to p-interference [1d, 3, 4, 6] and sinterference. [2b] In the p systems,the involvement of s bonds are inevitable,a nd the p-interference can only suppress the p channels,l eaving the s channels unaffected. When the molecular building blocks are only constructed from s bonds with the vanishing of p channels,t he s-interference will lead to strong conductance suppression, as recently demonstrated in s-conjugated silane system. [2b] Besides the 2c-2e bondbased system, inorganic clusters based on metal-metal bonds were also found to show QI. [7] These progresses suggest the great potential of exploring QI in distinctive bonding systems.Besides the conventional 2c-2e bonds,t here exist abundantly unconventional multicenter bonding systems,showing much richer patterns to form bonds with the absence of both p and s conjugations (Figure 1a). Thus,whether and how QI is present in those multicenter bonding systems become an unexplored and promising avenue.T oe xplore such multicenter-bond-based QI, carborane is an ideal molecular building block. Since the carborane framework is constructed from three-center-two-electron( 3c-2e) bonds,t he electrons of the 3c-2e bonds can delocalize around the framework, ensuring efficient conjugation between each multicenter bond. Thee fficient conjugation of carborane leads to distinctively three-dimensional aromaticity [8] and high stability, [9] which has already been applied in ab road spectrum of fields, [9b,10] such as catalysis, [11] supramolecular chemistry, [12] and optoelectronics. [13] Thus the single-molecule conductance investigation of carborane provides an ideal testbed to investigate the multicenter-bond-based QI, which w...

show abstract

“…This enhancement is mainly because the meta configuration of the central ring of the OPE molecule induces destructive π‐interference which leads to a steeper slope of the transmission function at the Fermi energy. Similarly, a recent study by Garner et al reports that this concept can also be applied to destructive σ‐interference in a σ‐orbital system (Figure c). Specifically, they demonstrate that a saturated silicon‐based molecule with a functionalized bicyclo[2.2.2]octasilane moiety (Si2‐Si222‐Si2) can exhibit strong destructive QI in its σ‐system.…”

Section: Thermoelectric Properties Of Molecular Junctionsmentioning

confidence: 75%

Thermal and Thermoelectric Properties of Molecular Junctions

Wang

¹

,

Meyhöfer

²

,

Reddy

³

2019

Adv Funct Materials

View full text Add to dashboard Cite

Molecular junctions (MJs) represent an ideal platform for studying charge and energy transport at the atomic and molecular scale and are of fundamental interest for the development of molecular‐scale electronics. While tremendous efforts have been devoted to probing charge transport in MJs during the past two decades, only recently advances in experimental techniques and computational tools have made it possible to precisely characterize how heat is transported, dissipated, and converted in MJs. This progress is central to the design of thermally robust molecular circuits and high‐efficiency energy conversion devices. In addition, thermal and thermoelectric studies on MJs offer unique opportunities to test the validity of classical physical laws at the nanoscale. A brief survey of recent progress and emerging experimental approaches in probing thermal and thermoelectric transport in MJs is provided, including thermal conduction, heat dissipation, and thermoelectric effects, from both a theoretical and experimental perspective. Future directions and outstanding challenges in the field are also discussed.

show abstract

“…Utilizing the destructive quantum interference effect, Garner et al achieved the single molecule insulator in a space with a length of less than 1 nm. As showed in Figure a, its conductance was even smaller than that obtained by occupying the vacuum barrier energy of the same sized space, and an unusually large thermoelectric potential (up to 0.97 mV K −1 ) was obtained (Figure b,c).…”

Section: Optimization Strategies For Ote Devicesmentioning

confidence: 99%

Section: Optimization Strategies For Ote Devicesmentioning

confidence: 99%

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

Zeng

¹

,

Wu

²

,

Cao

³

et al. 2019

Adv Funct Materials

View full text Add to dashboard Cite

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.

show abstract

Comprehensive suppression of single-molecule conductance using destructive σ-interference

Cited by 286 publications

References 45 publications

Multicenter‐Bond‐Based Quantum Interference in Charge Transport Through Single‐Molecule Carborane Junctions

Multicenter‐Bond‐Based Quantum Interference in Charge Transport Through Single‐Molecule Carborane Junctions

Thermal and Thermoelectric Properties of Molecular Junctions

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

Contact Info

Product

Resources

About