The ultimate in microelectronics: biomolecules

Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society Pub Date : 1988-11-01 DOI:10.1109/IEMBS.1988.95308

L. Powers

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Abstract

Biological microstructures perform a variety of chemical and electrical functions: switches, proton pumps, power supplies, receptors, effectors, and transducers. In most biological systems, each function is carried out by a separate molecule or as part of a complex of molecules. In a few cases, the same molecule can perform more than one function. Since the larger of these molecules is only approximately 5 nm in diameter, this is the ultimate in miniaturization. Although these processes are not executed rapidly by comparison with solid-state electronics, they are highly efficient. The underlying principles are parallel processes and feedback control, and the mechanisms involve electron tunneling, diffusion within or adjacent to the matrix, charge separation across a highly resistive low-capacity medium, energy stored in chemical bonds, and near-thermodynamic equilibrium pools for electron transport. Thus, a detailed understanding of the structure function relationship using a host of structural and spectroscopic techniques is paramount to design of molecular-based electronic architecture.<>

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微电子学的终极:生物分子

生物微结构执行各种化学和电子功能:开关，质子泵，电源，受体，效应器和换能器。在大多数生物系统中，每种功能都是由一个单独的分子或作为分子复合体的一部分来完成的。在少数情况下，同一个分子可以执行多种功能。由于这些分子中较大的直径只有大约5纳米，这是微型化的终极目标。虽然与固态电子相比，这些过程的执行速度并不快，但它们效率很高。其基本原理是并行过程和反馈控制，其机制包括电子隧穿、在基体内部或附近扩散、电荷在高电阻低容量介质中的分离、化学键中存储的能量以及电子传输的近热力学平衡池。因此，使用一系列结构和光谱技术来详细了解结构和功能关系对于设计基于分子的电子结构是至关重要的。

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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Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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