Microwave-Assisted Catalytic Deconstruction of Plastics Waste into Nanostructured Carbon and Hydrogen Fuel Using Composite Magnetic Ferrite Catalysts.

IF 2.3 Q2 BIOLOGY
Scientifica Pub Date : 2024-05-31 eCollection Date: 2024-01-01 DOI:10.1155/2024/3318047
Bilal Shoukat, Hammad Hussain, Muhammad Yasin Naz, Ahmed Ahmed Ibrahim, Shazia Shukrullah, Yasin Khan, Yaning Zhang
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引用次数: 0

Abstract

Finding new catalysts and pyrolysis technologies for efficiently recycling wasted plastics into fuels and structured solid materials of high selectivity is the need of time. Catalytic pyrolysis is a thermochemical process that cracks the feedstock in an inert gas environment into gaseous and liquid fuels and a residue. This study is conducted on microwave-assisted catalytic recycling of wasted plastics into nanostructured carbon and hydrogen fuel using composite magnetic ferrite catalysts. The composite ferrite catalysts, namely, NiZnFe2O4, NiMgFe2O4, and MgZnFe2O4 were produced through the coprecipitation method and characterized for onward use in the microwave-assisted valorization of wasted plastics. The ferrite nanoparticles worked as a catalyst and heat susceptor for uniformly distributed energy transfer from microwaves to the feedstock at a moderate temperature of 450°C. The type of catalyst and the working parameters significantly impacted the process efficiency, gas yield, and structural properties of the carbonaceous residue. The tested process took 2-8 minutes to pulverize feedstock into gas and carbon nanotubes (CNTs), depending on the catalyst type. The NiZnFe2O4-catalyzed process produced CNTs with good structural properties and fewer impurities compared to other catalysts. The NiMgFe2O4 catalyst performed better in terms of hydrogen evolution by showing 87.5% hydrogen (H2) composition in the evolved gases. Almost 90% of extractable hydrogen from the feedstock evolved during the first 2 minutes of the reaction.

利用复合磁性铁氧体催化剂将塑料废料微波辅助催化解构为纳米结构碳和氢燃料。
寻找新的催化剂和热解技术,将废塑料高效地回收利用为燃料和高选择性结构固体材料,是当务之急。催化热解是一种热化学过程,可在惰性气体环境中将原料裂解为气态和液态燃料及残留物。本研究利用复合磁性铁氧体催化剂,对废塑料进行微波辅助催化回收,将其转化为纳米结构碳和氢燃料。通过共沉淀法制备了复合铁氧体催化剂,即 NiZnFe2O4、NiMgFe2O4 和 MgZnFe2O4,并对其进行了表征,以便在微波辅助的废塑料价值化中继续使用。铁氧体纳米粒子既是催化剂,又是热吸收体,可在 450°C 的适度温度下将能量从微波均匀地传递到原料中。催化剂的类型和工作参数对工艺效率、气体产量和碳质残渣的结构特性有很大影响。根据催化剂类型的不同,测试过程需要 2 至 8 分钟才能将原料粉碎成气体和碳纳米管(CNT)。与其他催化剂相比,NiZnFe2O4 催化工艺生产的 CNT 具有良好的结构特性,杂质较少。NiMgFe2O4 催化剂在氢气进化方面表现更好,在进化气体中显示出 87.5% 的氢(H2)成分。原料中几乎 90% 的可萃取氢都是在反应的头 2 分钟内进化出来的。
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来源期刊
Scientifica
Scientifica BIOLOGY-
CiteScore
6.70
自引率
0.00%
发文量
43
审稿时长
21 weeks
期刊介绍: Scientifica is a peer-reviewed, Open Access journal that publishes research articles, review articles, and clinical studies covering a wide range of subjects in the life sciences, environmental sciences, health sciences, and medicine. The journal is divided into the 65 subject areas.
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