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基于生命周期评估的高产与“标准”自下而上制备碳点方法的比较研究

Life Cycle Assessment-Based Comparative Study between High-Yield and "Standard" Bottom-Up Procedures for the Fabrication of Carbon Dots.

作者信息

Fernandes Sónia, Esteves da Silva Joaquim C G, Pinto da Silva Luís

机构信息

Chemistry Research Unit (CIQUP), Institute of Molecular Sciences (IMS), Faculty of Sciences of University of Porto, R. Campo Alegre 697, 4169-007 Porto, Portugal.

LACOMEPHI, GreenUPorto, Department of Geosciences, Environmental and Territorial Planning, Faculty of Sciences of University of Porto, R. Campo Alegre 697, 4169-007 Porto, Portugal.

出版信息

Materials (Basel). 2022 May 11;15(10):3446. doi: 10.3390/ma15103446.

DOI:10.3390/ma15103446
PMID:35629474
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9145381/
Abstract

Carbon dots (CDs) are carbon-based nanomaterials with remarkable properties that can be produced from a wide variety of synthesis routes. Given that "standard" bottom-up procedures are typically associated with low synthesis yields, different authors have been trying to devise alternative high-yield fabrication strategies. However, there is a doubt if sustainability-wise, the latter should be really preferred to the former. Herein, we employed a Life Cycle Assessment (LCA) approach to compare and understand the environmental impacts of high-yield and "standard" bottom-up strategies, by applying different life cycle impact assessment (LCIA) methods. These routes were: (1) production of hydrochar, via the hydrothermal treatment of carbon precursors, and its alkaline peroxide treatment into high-yield CDs; (2) microwave treatment of carbon precursors doped with ethylenediamine; (3) and (6) thermal treatment of carbon precursor and urea; (4) hydrothermal treatment of carbon precursor and urea; (5) microwave treatment of carbon precursor and urea. For this LCA, four LCIA methods were used: ReCiPe, Greenhouse Gas Protocol, AWARE, and USEtox. Results identified CD-5 as the most sustainable synthesis in ReCiPe, Greenhouse Gas Protocol, and USEtox. On the other hand, in AWARE, the most sustainable synthesis was CD-1. It was possible to conclude that, in general, high-yield synthesis (CD-1) was not more sustainable than "standard" bottom-up synthesis, such as CD-5 and CD-6 (also with relatively high-yield). More importantly, high-yield synthesis (CD-1) did not generate much lower environmental impacts than "standard" approaches with low yields, which indicates that higher yields come with relevant environmental costs.

摘要

碳点(CDs)是具有卓越性能的碳基纳米材料,可通过多种合成路线制备。鉴于“标准”的自下而上方法通常合成产率较低,不同的作者一直在尝试设计替代的高产率制备策略。然而,从可持续性角度来看,后者是否真的比前者更可取,这存在疑问。在此,我们采用生命周期评估(LCA)方法,通过应用不同的生命周期影响评估(LCIA)方法,来比较和理解高产率和“标准”自下而上策略对环境的影响。这些路线包括:(1)通过对碳前驱体进行水热处理制备水热炭,并将其用过氧化碱处理制成高产率的碳点;(2)对掺杂乙二胺的碳前驱体进行微波处理;(3)和(6)对碳前驱体和尿素进行热处理;(4)对碳前驱体和尿素进行水热处理;(5)对碳前驱体和尿素进行微波处理。对于此LCA,使用了四种LCIA方法:ReCiPe、温室气体协议、AWARE和USEtox。结果表明,在ReCiPe、温室气体协议和USEtox中,CD - 5是最具可持续性的合成方法。另一方面,在AWARE中,最具可持续性的合成方法是CD - 1。可以得出结论,总体而言,高产率合成(CD - 1)并不比“标准”的自下而上合成(如CD - 5和CD - 6,产率也相对较高)更具可持续性。更重要的是,高产率合成(CD - 1)产生的环境影响并不比低产率的“标准”方法低很多,这表明更高的产率伴随着相应的环境成本。

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