Synergizing cybersecurity in healthcare with novel bioprocessing for sustainable energy-centric water remediation

IF 4.3 4区环境科学与生态学 Q2 ENGINEERING, ENVIRONMENTAL

Water Reuse Pub Date : 2024-02-02 DOI:10.2166/wrd.2024.121

K. Sita Kumari, V. Ghorpade, Fatima Moayad Sami, Sulaima Lebbe Abdul Haleem, S. Kondaveeti, Sherzod Kiyosov

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Abstract

The introduction of several novel chemicals, materials, and processes with varied levels of complexity in recent decades has been a result of the incredibly rapid technological advancement that has characterised those decades. This in turn has led to an increase in the number of pollutants released into the environment, necessitating their effective removal. The results of environmental monitoring reveal that several pollutants are exceeding the limit in ground water, which raises questions about the efficacy of the wastewater treatment methods now in use. This research proposes a novel method for sustainable smart grid (SG)-based energy analysis in water remediation and network cybersecurity analysis for healthcare application. Here the water-caused damages have been analysed based on a healthcare application using SG energy analysis and the network cyber security analysis is carried out using the federated blockchain model (SGEA_FB). Experimental analysis is carried out in terms of network integrity, throughput, scalability, and training accuracy. According to an analysis of the exergy destruction rates in every method component, power generation subsystem has the greatest exergy destruction rate at 15.4 MW. A training accuracy of 96%, throughput of 86%, network integrity of 76%, and scalability of 73% were all achieved by the suggested method.

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将医疗保健领域的网络安全与新型生物处理技术相结合，实现以能源为中心的可持续水资源修复

近几十年来，由于技术的飞速发展，出现了多种复杂程度不同的新型化学品、材料和工艺。这反过来又导致排放到环境中的污染物数量增加，因此必须有效地清除这些污染物。环境监测结果显示，地下水中的多种污染物超标，这就对目前使用的废水处理方法的有效性提出了质疑。本研究提出了一种新方法，用于基于可持续智能电网（SG）的水处理能源分析和医疗应用的网络安全分析。在此，利用智能电网能源分析方法对医疗应用中水造成的损害进行了分析，并利用联盟区块链模型（SGEA_FB）进行了网络安全分析。在网络完整性、吞吐量、可扩展性和训练准确性方面进行了实验分析。根据对每个方法组件的能量破坏率分析，发电子系统的能量破坏率最大，为 15.4 MW。建议方法的训练精度为 96%，吞吐量为 86%，网络完整性为 76%，可扩展性为 73%。

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