Engineering Transport Orbitals in Single-Molecule Junctions

Daaoub, Abdalghani; Ornago, Luca; Vogel, David; Bastante, Pablo; Sangtarash, Sara; Parmeggiani, Matteo; Kamer, Jerry; Agraı̈t, Nicolás; Mayor, Marcel; Zant, Herre van der; Sadeghi, Hatef

doi:10.1021/acs.jpclett.2c01851

Cited by 16 publications

(25 citation statements)

References 36 publications

(63 reference statements)

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“…where Conductance Histograms. To construct conductance histograms shown in Figure S11, we follow the same procedure as in ref 26. First, we form a series of junctions with different contacting modalities to electrodes and calculate the electrical conductance G for a range of electrodes Fermi energies E F .…”

Section: ■ Computational Methodsmentioning

confidence: 99%

“…25 Thiol anchors were chosen because they have high binding energy to electrodes (E B = 2.1 eV) and make good contacts to gold electrodes experimentally. 26 To demonstrate that spin interference can be different in these radicals compared to their closed-shell counterparts, we also studied a closed-shell analogue of TPM-B where the boron atom was replaced with a carbon atom (TPM in Figure 1b).…”

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confidence: 99%

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Controlling Spin Interference in Single Radical Molecules

et al. 2023

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Quantum interference (QI) dominates the electronic properties of single molecules even at room temperature and can lead to a large change in their electrical conductance. To take advantage of this for nanoelectronic applications, a mechanism to electronically control QI in single molecules needs to be developed. In this paper, we demonstrate that controlling the quantum interference of each spin in a stable open-shell organic radical with a large π-system is possible by changing the spin state of the radical. We show that the counterintuitive constructive spin interference in a meta-connected radical changes to destructive interference by changing the spin state of the radical from a doublet to a singlet. This results in a significant change in the room temperature electrical conductance by several orders of magnitude, opening up new possibilities for spin interference based molecular switches for energy storage and conversion applications.

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Section: ■ Computational Methodsmentioning

confidence: 99%

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confidence: 99%

Controlling Spin Interference in Single Radical Molecules

et al. 2023

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“…Porphyrins, which stand for a sort of natural tetrapyrrolic macrocycle system, provide a good starting point for building molecular devices − and have been studied extensively as molecular devices in the form of the complex monomer, oligomer, fused structures and through-space π–π stacked structures . However, to our knowledge, despite fascinating features such as low conductance attenuation at long molecular length, , the tunable conductance by the image-charge effect and the central-coordinated metal, the systematic investigation on the influence of substituents, which is a primary effect in regulating energy level of molecular junctions and further the single-molecule conductance, − on the side groups of the conductive backbones in tetrapyrrolic macrocycles, has not been reported.…”

Section: Introductionmentioning

confidence: 99%

Regulating the Single-Molecule Conductance of Corroles by the Substituents on the B-Site

Pan

Guo

et al. 2022

J. Phys. Chem. C

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Although the tetrapyrrolic macrocycle system provides a promising platform for building molecular devices, investigating the relationship between the conductance and the substituents is still a challenge. Here, three A2B type corroles with the substituents exhibiting electron-withdrawing and electron-donating effects on B-site are prepared. The single-molecule conductance results via the scanning tunneling microscope break junction (STM-BJ) technique demonstrate that the single-molecule conductance of corroles is suppressed by the electron-withdrawing substituent while it is enhanced by the electron-donating substituent, which is attributed to the change of the energy gap between the HOMO and LUMO.

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“…We then employed (Figures S13−S16) DFT combined with the nonequilibrium Green's function (NEGF) method to optimize and calculate the transmission probability of these two supramolecular co-conformations and plot (Figure 1g) the calculated transmissions versus energy. 55 We found that the electron transmission probability of the [π•••π] stacked dimer junctions with parallelly displaced co-conformations is approximately over 2 orders of magnitude larger than those with fully stretched hydrogen-bonded co-conformations. In addition, [π•••π] stacked and hydrogen-bonded dimers exhibit (Figures S17−S19) different quantum interference effects primarily on account of the alternations 56 in the phase of orbitals.…”

Section: ■ Results and Discussionmentioning

confidence: 82%

“…In energy terms (Figure S10), the [π···π] stacked dimer (Figure e) is more favorable, while the hydrogen-bonded co-conformation (Figure f) represents a metastable state which, although it is 5.0–6.0 kcal/mol higher in energy, can be attained by the nanoscale motion of the electrodes. We then employed (Figures S13–S16) DFT combined with the nonequilibrium Green’s function (NEGF) method to optimize and calculate the transmission probability of these two supramolecular co-conformations and plot (Figure g) the calculated transmissions versus energy . We found that the electron transmission probability of the [π···π] stacked dimer junctions with parallelly displaced co-conformations is approximately over 2 orders of magnitude larger than those with fully stretched hydrogen-bonded co-conformations.…”

Section: Results and Discussionmentioning

confidence: 99%

Robust Single-Supermolecule Switches Operating in Response to Two Different Noncovalent Interactions

Zhou,

Fu,

Wang

et al. 2023

J. Am. Chem. Soc.

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Supramolecular electronics provide an opportunity to introduce molecular assemblies into electronic devices through a combination of noncovalent interactions such as [π···π] and hydrogen-bonding interactions. The fidelity and dynamics of noncovalent interactions hold considerable promise when it comes to building devices with controllable and reproducible switching functions. Here, we demonstrate a strategy for building electronically robust switches by harnessing two different noncovalent interactions between a couple of pyridine derivatives. The single-supermolecule switch is turned ON when compressing the junction enabling [π···π] interactions to dominate the transport, while the switch is turned OFF by stretching the junction to form hydrogen-bonded dimers, leading to a dramatic decrease in conductance. The robustness and reproducibility of these single-supermolecule switches were achieved by modulating the junction with Ångström precision at frequencies of up to 190 Hz while obtaining high ON/OFF ratios of ∼600. The research presented herein opens up an avenue for designing robust bistable mechanoresponsive devices which will find applications in the building of integrated circuits for microelectromechanical systems.

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Engineering Transport Orbitals in Single-Molecule Junctions

Cited by 16 publications

References 36 publications

Controlling Spin Interference in Single Radical Molecules

Controlling Spin Interference in Single Radical Molecules

Regulating the Single-Molecule Conductance of Corroles by the Substituents on the B-Site

Robust Single-Supermolecule Switches Operating in Response to Two Different Noncovalent Interactions

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