空气环境及表面微生物最佳去污问题研究

IF 1.1 Q4 ELECTROCHEMISTRY
Yu. A. Boshnyaga, M. K. Bologa, E. Yu. Agarval
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引用次数: 0

摘要

现代文明在提供经济和社会进步的同时,客观上为各种传染病的传播创造了——有时接近于理想的——条件。SARS-CoV-2大流行的灾难性后果清楚地表明,智人似乎无法有效抵御冠状病毒的侵袭。本出版物的目的是试图填补在开发有效的微生物净化方法和手段方面的空白,这些方法和手段在关键参数方面是最佳的。观测数据表明,大量SARS-CoV-2冠状病毒感染是通过空气发生的,没有直接接触传染源,包括很长一段时间的接触。降水有助于净化空气中的污染物和病毒,减少非接触性污染,这也带来了空气环境和表面最佳微生物净化的最新问题。热力学方法已被用于优化微生物灭菌。结果表明,不可逆的化学氧化反应是实现无菌的最短途径,并且能够提供高可靠性的去污。已经确定氧气是一种最佳的氧化剂,包括从生态学的角度来看,因为它的反应形式和谐地符合自然交换循环。获得用于消毒的活性氧的最佳方法是使用低温(“冷”)等离子体,它提供了高效产生氧化反应形式:原子氧(O)、臭氧(O3)、羟基自由基(•OH)、过氧化氢(H2O2)、超氧化物(\({\text{O}}_{2}^{ - }\))和单线态氧O2(a1Δg)。由于上述大多数形式在等离子体涂抹器外的寿命很短,远离等离子体发生器的物体应该用臭氧(O3)消毒,臭氧的最小寿命相当长。研究表明,微波法产生氧等离子体是生产高效臭氧的最佳方法。提出了一种模块化的发电原理,用于在大范围内改变臭氧发生单元的生产力。该模块是在一种改进型串行微波炉的基础上开发的,其中由于电离器(点火器),包括基于辐射放射性核素发射器的电离器(点火器),可以维持非自持微波放电。在表面有大量污染的情况下,除臭氧(O3)空气消毒外,建议使用过氧化氢(H2O2)水溶液。至关重要的是,这些用于消毒远离等离子发生器的物体的活性氧是高效的,同时是环境中性的。建议为在臭氧浓度增加地区的活动提供可靠和负担得起的个人防护装备。这种被认为是最佳的消毒方法不仅适用于医学,也适用于农业、工业和日常生活中的许多实践。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
On the Problem of Optimal Microbiological Decontamination of Air Environment and Surfaces

Modern civilization, providing economic and social progress, at the same time objectively creates—sometimes close to ideal—conditions for the spread of various infections. The catastrophic consequences of the SARS-CoV-2 pandemic clearly indicate that homo sapiens appeared to be unable to effectively resist the onslaught of the coronavirus. The purpose of this publication is an attempt to fill the gap in the development of effective methods and means for microbiological decontamination that are optimal in terms of critical parameters. The observational data indicate that a significant number of SARS-CoV-2 coronavirus infections occur by air without a direct contact with the source, including over a long time interval. Precipitation helps to cleanse the air from pollutants and viruses, reducing noncontact contamination, which additionally brings up to date the problem of optimal microbiological decontamination of the air environment and surfaces. A thermodynamic approach has been used to optimize microbiological sterilization. It is shown that irreversible chemical oxidation reactions are the shortest way to achieve sterility, and they are capable of providing high reliability of decontamination. It has been established that oxygen is an optimal oxidant, including from the point of view of ecology, since its reactive forms harmoniously fit into natural exchange cycles. The optimal method for obtaining reactive oxygen species for disinfection is the use of low-temperature (“cold”) plasma, which provides the energy-efficient generation of oxidative reactive forms: atomic oxygen (O), ozone (O3), hydroxyl radical (OH), hydrogen peroxide (H2O2), superoxide (\({\text{O}}_{2}^{ - }\)), and singlet oxygen O2(a1Δg). Due to a short lifetime for most of the above forms outside the plasma applicator, objects remote from the plasma generator should be sterilized with ozone (O3), the minimum lifetime of which is quite long. It has been substantiated that the microwave method of generating oxygen plasma is optimal for energy-efficient ozone production. A modular principle of generation is proposed for varying the productivity of ozone-generating units over a wide range. The module has been developed on the basis of an adapted serial microwave oven, in which a non-self-sustaining microwave discharge is maintained thanks to ionizers (igniters), including those based on radiating radionuclides-emitters. In case of massive contamination of surfaces, it is advisable—in addition to ozone (O3) air disinfecting—to use aqueous solutions of hydrogen peroxide (H2O2). It is essential that these reactive oxygen species for disinfecting objects remote from the plasma generator are highly efficient and, at the same time, environmentally neutral. Reliable and affordable personal protective equipment is proposed for activities in zones of increased ozone concentration. The considered optimal means of disinfection can be applicable not only in medicine but also adapted for numerous practices in agriculture, industry, and everyday life.

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来源期刊
Surface Engineering and Applied Electrochemistry
Surface Engineering and Applied Electrochemistry Engineering-Industrial and Manufacturing Engineering
CiteScore
1.70
自引率
22.20%
发文量
54
审稿时长
6 months
期刊介绍: Surface Engineering and Applied Electrochemistry is a journal that publishes original and review articles on theory and applications of electroerosion and electrochemical methods for the treatment of materials; physical and chemical methods for the preparation of macro-, micro-, and nanomaterials and their properties; electrical processes in engineering, chemistry, and methods for the processing of biological products and food; and application electromagnetic fields in biological systems.
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