在空气中工作的微腔等离子体装置:有效生成一氧化氮的装置结构优化

C. Shin, S. Park, J. Eden
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摘要

只提供摘要形式。本文介绍了微放电装置的制造和操作,该装置可以在微腔内保持稳定的空气等离子体,并有效地从气流中产生所需的气体。采用湿法化学工艺制备了一种坚固的纳米多孔Al2O3介电材料,并在其上制备了直流放电型微腔器件。从空气排放中产生一氧化氮(NO)是本报告的主要兴趣之一,具有生物医学治疗的潜在应用。通过控制微放电装置的特性来优化NO的产生条件,它可以在电压下选择性地产生NO,至少比其他传统技术低一个数量级。讨论了空气微等离子体中气体种类的定量测量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Microcavity plasma devices operating in air: Optimization of the device structure for efficient nitric oxide generation
Summary form only given. This presentation describes the fabrication and operation of microdischarge devices which can sustain stable air plasma inside the microcavity and efficiently produce desired gas species from a gas flow. A DC-discharge type microcavity device has been fabricated on nanoporous Al2O3 dielectrics, a robust dielectric produced by wet chemical processing.Production of nitric oxide (NO) from air discharge is one of key interests in this presentation with a potential application of biomedical therapeutics. By controlling the microdischarge device characteristics designed to have optimized condition for NO generation, it can produce NO species selectively at voltages, at least a order lower compared to other conventional techniques. Quantitative measurement of gas species out of the air microplasmas will be discussed.
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