Charge transfer in DNA and its diverse modelling approaches

Q1 Biochemistry, Genetics and Molecular Biology

Frontiers in Life Science Pub Date : 2016-07-02 DOI:10.1080/21553769.2016.1207570

Dr. Deepak Rawtani, Binal Kuntmal, Y. Agrawal

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引用次数: 12

Abstract

ABSTRACT DNA nanostructures with molecular recognition qualities have been developed, but the conceptualization of DNA-based molecular nanoelectronics is still a thought-provoking subject. An efficient and speedy charge transfer (CT) process through DNA nanoassembly is demanded for farther exploitation of DNA nanoelectronics with programmable features. The CT properties are represented in terms of localization lengths. Because of the DNA molecule’s unique and novel characteristics, it can be applied in a variety of multidisciplinary research areas such as nanobiomedicine, nanooptoelectronics and nanobiotechnology. By using this interesting phenomena, we can integrate nanotechnology with both, biology as well as engineering, and can use it as a tool for many biological and engineering applications such as DNA chips, DNA nanogrids and DNA nanoribbons. Here, we have presented a review on various experiments that measure CT and charge transport in DNA. It is a very wide and interesting area in which many scientists have published many articles. So here we have tried to show the whole picture of it.

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DNA中的电荷转移及其多种建模方法

具有分子识别特性的DNA纳米结构已经得到了发展，但基于DNA的分子纳米电子学的概念化仍然是一个发人深省的课题。为了进一步开发具有可编程特性的DNA纳米电子学，需要一种高效、快速的DNA纳米组装电荷转移过程。CT属性用局部化长度表示。由于DNA分子的独特性和新颖性，它可以应用于纳米生物医学、纳米光电子和纳米生物技术等多种多学科研究领域。通过利用这一有趣的现象，我们可以将纳米技术与生物学和工程学结合起来，并将其用作许多生物和工程应用的工具，如DNA芯片、DNA纳米网格和DNA纳米带。在这里，我们提出了各种实验，测量CT和DNA中的电荷传输的综述。这是一个非常广泛和有趣的领域，许多科学家发表了许多文章。在这里，我们试图展示它的全貌。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frontiers in Life Science MULTIDISCIPLINARY SCIENCES-

CiteScore

5.50

自引率

0.00%

发文量

期刊介绍： Frontiers in Life Science publishes high quality and innovative research at the frontier of biology with an emphasis on interdisciplinary research. We particularly encourage manuscripts that lie at the interface of the life sciences and either the more quantitative sciences (including chemistry, physics, mathematics, and informatics) or the social sciences (philosophy, anthropology, sociology and epistemology). We believe that these various disciplines can all contribute to biological research and provide original insights to the most recurrent questions.