Yuanhui Li scite author profile

DNA is a promising molecule for applications in molecular electronics because of its unique electronic and self-assembly properties. Here we report that the conductance of DNA duplexes increases by approximately one order of magnitude when its conformation is changed from the B-form to the A-form. This large conductance increase is fully reversible, and by controlling the chemical environment, the conductance can be repeatedly switched between the two values. The conductance of the two conformations displays weak length dependencies, as is expected for guanine-rich sequences, and can be fit with a coherence-corrected hopping model. These results are supported by ab initio electronic structure calculations that indicate that the highest occupied molecular orbital is more disperse in the A-form DNA case. These results demonstrate that DNA can behave as a promising molecular switch for molecular electronics applications and also provide additional insights into the huge dispersion of DNA conductance values found in the literature.

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Financial distress, internal control, and earnings management: Evidence from China

Xiang

et al. 2020

Journal of Contemporary Accounting & Economics

106

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Denudation of Taiwan Island since the Pliocene Epoch

1976

Geol

230

121

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Detection and identification of genetic material via single-molecule conductance

et al. 2018

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The Kuroshio edge exchange processes (KEEP) study — an introduction to hypotheses and highlights

Wong

Chao

et al. 2000

Continental Shelf Research

143

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Binding configurations and intramolecular strain in single-molecule devices

Rascón-Ramos¹,

Artés²,

Li³

et al. 2015

Nature Mater

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The development of molecular-scale electronic devices has made considerable progress over the past decade, and single-molecule transistors, diodes and wires have all been demonstrated. Despite this remarkable progress, the agreement between theoretically predicted conductance values and those measured experimentally remains limited. One of the primary reasons for these discrepancies lies in the difficulty to experimentally determine the contact geometry and binding configuration of a single-molecule junction. In this Article, we apply a small-amplitude, high-frequency, sinusoidal mechanical signal to a series of single-molecule devices during junction formation and breakdown. By measuring the current response at this frequency, it is possible to determine the most probable binding and contact configurations for the molecular junction at room temperature in solution, and to obtain information about how an applied strain is distributed within the molecular junction. These results provide insight into the complex configuration of single-molecule devices, and are in excellent agreement with previous predictions from theoretical models.

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Yuanhui Li

Diffusion of ions in sea water and in deep-sea sediments

A kinetic approach to describe trace-element distribution between particles and solution in natural aquatic systems

Conformational gating of DNA conductance

Financial distress, internal control, and earnings management: Evidence from China

Denudation of Taiwan Island since the Pliocene Epoch

Detection and identification of genetic material via single-molecule conductance

The Kuroshio edge exchange processes (KEEP) study — an introduction to hypotheses and highlights

Binding configurations and intramolecular strain in single-molecule devices

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