Electronic Devices Made from Chitin: NAND Gates Made from Chitin Sorbates and Unsaturated Bridging Ligands—Possible Integration Levels and Kinetics of Operation

Stefan Fränzle, Felix Blind
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Abstract

Chitin (usually derived from aq. arthropods like shrimp Pandalus borealis) acts as a potent metal sorbent in both environmental monitoring and retention applications such as wastewater purification or nuclear fuel reprocessing. Given this established (starting in the 1970s) use of chitin and the fact that adsorption of metal ions/complexes to chitin does increase the currents observed in metal-centered redox couples by a factor of about 10, it is straightforward to conceive self-organized (by adsorption modified by adding certain ligands bridging M and chitin) surface films which exert electrical information processing by means of inner-sphere redox processes. Preliminary work is shown concerning the influence of ligands—including some possibly acting as inner-sphere-transfer agents, like caffeic acid—on metal ion retention by chitin. Another ligand is reported to enhance current flow into electrodes (i.e., electron injection from some reducing cation). These inner-sphere redox processes, in turn, can be controlled by creating or removing a chain of conjugated double bonds, e.g., by Diels–Alder reactions. Devices admitting corresponding reagents in a controlled manner and appropriate array then act as NAND gates, thus being components capable of performing each kind of classical computation. Applications in environmental analysis and “green” computing for simple purposes like electronic keys are suggested. The empirical basis for these conclusions includes studies on the influences of ligand additions on M adsorption (Mn, Ni, several REEs…) on chitin; some of these bridging ligands, like caffeinate and ferulate, can reversibly react with appropriate dienes. At the employed concentrations, distances among adsorbed metal ions are 1–3 nm, meaning that the charge-flow control takes spacer ligands like carotenoids. Practical setups are pointed to, using evidence from ligand-augmented metal ion–chitin interactions, which might combine oxidizing (Ce) and optically address reducing (Eu) metal ions into a framework for coligand-controlled charge flow.
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由几丁质制成的电子器件:由几丁质山梨酸酯和不饱和桥接配体制成的NAND门——可能的整合水平和操作动力学
几丁质(通常来自北方熊猫虾等节肢动物)在环境监测和废水净化或核燃料后处理等保留应用中都是一种有效的金属吸附剂。考虑到这种已建立的(从20世纪70年代开始)甲壳素的使用,以及金属离子/配合物对甲壳素的吸附确实使金属中心氧化还原偶中观察到的电流增加了约10倍的事实,我们可以直接设想自组织(通过添加连接M和甲壳素的某些配体修饰的吸附)表面膜通过球内氧化还原过程施加电信息处理。初步研究表明配体(包括一些可能作为球内转移剂的配体,如咖啡酸)对几丁质保留金属离子的影响。据报道,另一种配体可以增强电流流入电极(即来自某些还原阳离子的电子注入)。这些内球氧化还原过程,反过来,可以通过创建或去除一条共轭双键链来控制,例如,通过Diels-Alder反应。以可控的方式接纳相应试剂的器件和适当的阵列充当NAND门,从而成为能够执行各种经典计算的元件。建议应用于环境分析和简单用途的“绿色”计算,如电子钥匙。这些结论的经验基础包括:研究配体添加对M (Mn、Ni、几种稀土等)在甲壳素上吸附的影响;其中一些桥接配体,如咖啡酸盐和阿魏酸盐,可以与适当的二烯发生可逆反应。在所使用的浓度下,吸附金属离子之间的距离为1-3纳米,这意味着电荷流控制需要像类胡萝卜素这样的间隔配体。利用配体增强金属离子-几丁质相互作用的证据,指出了实际的设置,这可能将氧化(Ce)和光学寻址还原(Eu)金属离子结合到一个配体控制电荷流的框架中。
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来源期刊
Nanomanufacturing and Metrology
Nanomanufacturing and Metrology Materials Science-Materials Science (miscellaneous)
CiteScore
5.40
自引率
0.00%
发文量
36
期刊介绍: Nanomanufacturing and Metrology is a peer-reviewed, international and interdisciplinary research journal and is the first journal over the world that provides a principal forum for nano-manufacturing and nano-metrology.Nanomanufacturing and Metrology publishes in the forms including original articles, cutting-edge communications, timely review papers, technical reports, and case studies. Special issues devoted to developments in important topics in nano-manufacturing and metrology will be published periodically.Nanomanufacturing and Metrology publishes articles that focus on, but are not limited to, the following areas:• Nano-manufacturing and metrology• Atomic manufacturing and metrology• Micro-manufacturing and metrology• Physics, chemistry, and materials in micro-manufacturing, nano-manufacturing, and atomic manufacturing• Tools and processes for micro-manufacturing, nano-manufacturing and atomic manufacturing
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