Defect and Heterostructure engineering assisted S-scheme Nb2O5 nanosystems-based solutions for environmental pollution and energy conversion

IF 15.9 1区 化学 Q1 CHEMISTRY, PHYSICAL
Karambir Singh , Abhimanyu , Sonu Sonu , Vishal Chaudhary , Pankaj Raizada , Sarvesh Rustagi , Pardeep Singh , Pankaj Thakur , Vinod Kumar , Ajeet Kaushik
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Abstract

This review explores the crystallographic versatility of niobium pentoxide (Nb2O5) at the nanoscale, showcasing enhanced catalytic efficiency for cutting-edge sustainable energy and environmental applications. The synthesis strategies explored encompass defect engineering, doping engineering, s-scheme formation, and heterojunction engineering to fine-tune the physicochemical attributes of diverse dimensional (0-D, 1-D, 2-D, and 3-D) Nb2O5 nanosystems as per targeted application. In addressing escalating environmental challenges, Nb2O5 emerges as a semiconductor photocatalyst with transformative potential, spanning applications from dye degradation to antibiotic and metal removal. Beyond its environmental impact, Nb2O5 is pivotal in sustainable energy applications, specifically in carbon dioxide and hydrogen conversion. However, challenges such as limited light absorption efficiency and scalability in production methods prompt the need for targeted research endeavors. The review details the state-of-the-art Nb2O5 nanosystems engineering, tuning their physicochemical properties employing material engineering, and their high catalytic performance in environment remediation and energy generation. It outlines challenges, potential mitigation strategies, and prospects, urging for developing greener synthesis routes, advanced charge transfer techniques, targeted optimization for specific pollutants, and application for micro/nano plastics photocatalytic reduction. As researchers and environmental stewards collaborate, Nb2O5 stands poised at the intersection of environmental remediation, energy harvesting, and nanomaterial advancements, offering a beacon of progress toward a cleaner, more sustainable future.

Abstract Image

缺陷和异质结构工程辅助基于 S 型 Nb2O5 纳米系统的环境污染和能源转换解决方案。
本综述探讨了五氧化二铌(Nb2O5)在纳米尺度上的晶体学多功能性,为尖端的可持续能源和环境应用展示了更高的催化效率。所探讨的合成策略包括缺陷工程、掺杂工程、S 型结构形成和异质结工程,以根据目标应用微调不同维度(0-D、1-D、2-D 和 3-D)Nb2O5 纳米系统的物理化学属性。为应对不断升级的环境挑战,Nb2O5 成为了一种具有变革潜力的半导体光催化剂,其应用范围从染料降解到抗生素和金属去除。除了对环境的影响之外,Nb2O5 在可持续能源应用中,特别是在二氧化碳和氢气转化方面,也具有举足轻重的作用。然而,光吸收效率和生产方法的可扩展性有限等挑战促使人们需要开展有针对性的研究工作。这篇综述详细介绍了最先进的 Nb2O5 纳米系统工程、利用材料工程调整其物理化学特性,以及它们在环境修复和能源生产中的高催化性能。报告概述了面临的挑战、潜在的缓解策略和前景,敦促开发更环保的合成路线、先进的电荷转移技术、针对特定污染物的针对性优化以及微/纳米塑料光催化还原的应用。在研究人员和环境管理者的通力合作下,Nb2O5 将成为环境修复、能源采集和纳米材料进步的交汇点,成为迈向更清洁、更可持续发展未来的一盏明灯。
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来源期刊
CiteScore
28.50
自引率
2.60%
发文量
175
审稿时长
31 days
期刊介绍: "Advances in Colloid and Interface Science" is an international journal that focuses on experimental and theoretical developments in interfacial and colloidal phenomena. The journal covers a wide range of disciplines including biology, chemistry, physics, and technology. The journal accepts review articles on any topic within the scope of colloid and interface science. These articles should provide an in-depth analysis of the subject matter, offering a critical review of the current state of the field. The author's informed opinion on the topic should also be included. The manuscript should compare and contrast ideas found in the reviewed literature and address the limitations of these ideas. Typically, the articles published in this journal are written by recognized experts in the field.
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