Signatures of Room-Temperature Quantum Interference in Molecular Junctions
Conspectus During the past decade or so, research groups around the globe have sought to answer the question: “How does electricity flow through single molecules?” In seeking the answer to this question, a series of joint theory and experimental studies have demonstrated that electrons passing throu...
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| Published in | Accounts of chemical research Vol. 56; no. 3; pp. 322 - 331 |
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| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
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United States
American Chemical Society
07.02.2023
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| Abstract | Conspectus During the past decade or so, research groups around the globe have sought to answer the question: “How does electricity flow through single molecules?” In seeking the answer to this question, a series of joint theory and experimental studies have demonstrated that electrons passing through single-molecule junctions exhibit exquisite quantum interference (QI) effects, which have no classical analogues in conventional circuits. These signatures of QI appear even at room temperature and can be described by simple quantum circuit rules and a rather intuitive magic ratio theory. The latter describes the effect of varying the connectivity of electrodes to a molecular core and how electrical conductance can be controlled by the addition of heteroatoms to molecular cores. The former describes how individual moieties contribute to the overall conductance of a molecule and how the overall conductance can change when the connectivities between different moieties are varied. Related circuit rules have been derived and demonstrated, which describe the effects of connectivity on Seebeck coefficients of organic molecules. This simplicity arises because when a molecule is placed between two electrodes, charge transfer between the molecule and electrodes causes the molecular energy levels to adjust, such that the Fermi energy (E F) of the electrodes lies within the energy gap between the highest occupied molecular orbital and lowest unoccupied molecular orbital. Consequently, when electrons of energy E F pass through a molecule, their phase is protected and transport takes place via phase-coherent tunneling. Remarkably, these effects have been scaled up to self-assembled monolayers of molecules, thereby creating two-dimensional materials, whose room temperature transport properties are controlled by QI. This leads to new molecular design strategies for increasing the on/off conductance ratio of molecular switches and to improving the performance of organic thermoelectric materials. In particular, destructive quantum interference has been shown to improve the Seebeck coefficient of organic molecules and increase their on/off ratio under the influence of electrochemical gating. The aim of this Account is to introduce the novice reader to these signatures of QI in molecules, many of which have been identified in joint studies involving our theory group in Lancaster University and experimental group in Bern University. |
|---|---|
| AbstractList | During the past decade or so,
research groups around the globe
have sought to answer the question: “How does electricity flow
through single molecules?” In seeking the answer to this question,
a series of joint theory and experimental studies have demonstrated
that electrons passing through single-molecule junctions exhibit exquisite
quantum interference (QI) effects, which have no classical analogues
in conventional circuits. These signatures of QI appear even at room
temperature and can be described by simple quantum circuit rules and
a rather intuitive magic ratio theory. The latter describes the effect
of varying the connectivity of electrodes to a molecular core and
how electrical conductance can be controlled by the addition of heteroatoms
to molecular cores. The former describes how individual moieties contribute
to the overall conductance of a molecule and how the overall conductance
can change when the connectivities between different moieties are
varied. Related circuit rules have been derived and demonstrated,
which describe the effects of connectivity on Seebeck coefficients
of organic molecules. This simplicity arises because when a molecule
is placed between two electrodes, charge transfer between the molecule
and electrodes causes the molecular energy levels to adjust, such
that the Fermi energy (
E
F
) of the electrodes
lies within the energy gap between the highest occupied molecular
orbital and lowest unoccupied molecular orbital. Consequently, when
electrons of energy
E
F
pass through a
molecule, their phase is protected and transport takes place via phase-coherent
tunneling. Remarkably, these effects have been scaled up to self-assembled
monolayers of molecules, thereby creating two-dimensional materials,
whose room temperature transport properties are controlled by QI.
This leads to new molecular design strategies for increasing the on/off
conductance ratio of molecular switches and to improving the performance
of organic thermoelectric materials. In particular, destructive quantum
interference has been shown to improve the Seebeck coefficient of
organic molecules and increase their on/off ratio under the influence
of electrochemical gating. The aim of this Account is to introduce
the novice reader to these signatures of QI in molecules, many of
which have been identified in joint studies involving our theory group
in Lancaster University and experimental group in Bern University. Conspectus During the past decade or so, research groups around the globe have sought to answer the question: “How does electricity flow through single molecules?” In seeking the answer to this question, a series of joint theory and experimental studies have demonstrated that electrons passing through single-molecule junctions exhibit exquisite quantum interference (QI) effects, which have no classical analogues in conventional circuits. These signatures of QI appear even at room temperature and can be described by simple quantum circuit rules and a rather intuitive magic ratio theory. The latter describes the effect of varying the connectivity of electrodes to a molecular core and how electrical conductance can be controlled by the addition of heteroatoms to molecular cores. The former describes how individual moieties contribute to the overall conductance of a molecule and how the overall conductance can change when the connectivities between different moieties are varied. Related circuit rules have been derived and demonstrated, which describe the effects of connectivity on Seebeck coefficients of organic molecules. This simplicity arises because when a molecule is placed between two electrodes, charge transfer between the molecule and electrodes causes the molecular energy levels to adjust, such that the Fermi energy (E F) of the electrodes lies within the energy gap between the highest occupied molecular orbital and lowest unoccupied molecular orbital. Consequently, when electrons of energy E F pass through a molecule, their phase is protected and transport takes place via phase-coherent tunneling. Remarkably, these effects have been scaled up to self-assembled monolayers of molecules, thereby creating two-dimensional materials, whose room temperature transport properties are controlled by QI. This leads to new molecular design strategies for increasing the on/off conductance ratio of molecular switches and to improving the performance of organic thermoelectric materials. In particular, destructive quantum interference has been shown to improve the Seebeck coefficient of organic molecules and increase their on/off ratio under the influence of electrochemical gating. The aim of this Account is to introduce the novice reader to these signatures of QI in molecules, many of which have been identified in joint studies involving our theory group in Lancaster University and experimental group in Bern University. ConspectusDuring the past decade or so, research groups around the globe have sought to answer the question: "How does electricity flow through single molecules?" In seeking the answer to this question, a series of joint theory and experimental studies have demonstrated that electrons passing through single-molecule junctions exhibit exquisite quantum interference (QI) effects, which have no classical analogues in conventional circuits. These signatures of QI appear even at room temperature and can be described by simple quantum circuit rules and a rather intuitive magic ratio theory. The latter describes the effect of varying the connectivity of electrodes to a molecular core and how electrical conductance can be controlled by the addition of heteroatoms to molecular cores. The former describes how individual moieties contribute to the overall conductance of a molecule and how the overall conductance can change when the connectivities between different moieties are varied. Related circuit rules have been derived and demonstrated, which describe the effects of connectivity on Seebeck coefficients of organic molecules. This simplicity arises because when a molecule is placed between two electrodes, charge transfer between the molecule and electrodes causes the molecular energy levels to adjust, such that the Fermi energy ( ) of the electrodes lies within the energy gap between the highest occupied molecular orbital and lowest unoccupied molecular orbital. Consequently, when electrons of energy pass through a molecule, their phase is protected and transport takes place via phase-coherent tunneling. Remarkably, these effects have been scaled up to self-assembled monolayers of molecules, thereby creating two-dimensional materials, whose room temperature transport properties are controlled by QI. This leads to new molecular design strategies for increasing the on/off conductance ratio of molecular switches and to improving the performance of organic thermoelectric materials. In particular, destructive quantum interference has been shown to improve the Seebeck coefficient of organic molecules and increase their on/off ratio under the influence of electrochemical gating. The aim of this Account is to introduce the novice reader to these signatures of QI in molecules, many of which have been identified in joint studies involving our theory group in Lancaster University and experimental group in Bern University. |
| Author | Ismael, Ali K. Al-Jobory, Alaa Lambert, Colin J. Liu, Shi-Xia |
| AuthorAffiliation | Tikrit University Department of Physics, College of Education for Pure Science Quantum Technology Centre, Physics Department University of Anbar Department of Physics, College of Science Department of Chemistry, Biochemistry and Pharmaceutical Sciences |
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| Author_xml | – sequence: 1 givenname: Shi-Xia orcidid: 0000-0001-6104-4320 surname: Liu fullname: Liu, Shi-Xia email: shi-xia.liu@unibe.ch organization: Department of Chemistry, Biochemistry and Pharmaceutical Sciences – sequence: 2 givenname: Ali K. orcidid: 0000-0001-7943-3519 surname: Ismael fullname: Ismael, Ali K. email: k.ismael@lancaster.ac.uk organization: Tikrit University – sequence: 3 givenname: Alaa surname: Al-Jobory fullname: Al-Jobory, Alaa organization: University of Anbar – sequence: 4 givenname: Colin J. orcidid: 0000-0003-2332-9610 surname: Lambert fullname: Lambert, Colin J. email: c.lambert@lancaster.ac.uk organization: Quantum Technology Centre, Physics Department |
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| Snippet | Conspectus During the past decade or so, research groups around the globe have sought to answer the question: “How does electricity flow through single... ConspectusDuring the past decade or so, research groups around the globe have sought to answer the question: "How does electricity flow through single... During the past decade or so, research groups around the globe have sought to answer the question: “How does electricity flow through single molecules?” In... |
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| Title | Signatures of Room-Temperature Quantum Interference in Molecular Junctions |
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