火焰合成实现了成分可定制的高熵含金属纳米材料

IF 20.2 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Nature chemistry Pub Date : 2025-07-30 DOI:10.1038/s41557-025-01894-w

Zhen Liu, Eirini Goudeli, Rui Guo, Houting Xie, Qinjian Luo, Laichun Zhao, Wanjun Xu, Joseph J. Richardson, Weijian Xu, Frank Caruso, Shuaijun Pan

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引用次数: 0

摘要

高熵含金属纳米材料在电催化和能量转换等多个领域引起了人们的兴趣。它们的合成通常需要高温（1000 K）来促进均匀混合和金属前驱体的快速转变。然而，目前最先进的方法通常涉及复杂的反应环境，需要专门的设备和操作。在此，我们展示了一种通用的火焰合成工艺，通过将有机金属前体混合到燃料（即石蜡）中并随后燃烧，来制造支持在烟灰状碳上的高熵金属单原子和/或纳米颗粒。高火焰温度（~ 1800 K）使金属-碳结合与可定制的化学和不同金属元素（多达25种金属研究）之间的均匀结合，而不管它们的热力学相容性如何。此外，我们展示了高性能的电合成过氧化氢，以突出这种方法作为电催化剂开发的一种有前途的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Flame synthesis achieves compositionally tailorable high-entropy metal-containing nanomaterials

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Flame synthesis achieves compositionally tailorable high-entropy metal-containing nanomaterials

High-entropy metal-containing nanomaterials have garnered interest in diverse fields such as electrocatalysis and energy conversion. Their synthesis typically requires high temperatures (>1,000 K) to facilitate homogeneous mixing and rapid transformation of metal precursors. However, current state-of-the-art approaches typically involve complex reaction environments and require specialized equipment and operations. Herein we demonstrate a versatile flame synthesis process to fabricate high-entropy metallic single atoms and/or nanoparticles supported on soot-like carbon via blending organometallic precursors into fuel (namely, paraffin wax) and subsequent burning. The high flame temperature (~1,800 K) enables strong metal–carbon association with tailorable chemistry and homogeneous bonding between dissimilar metallic elements (up to 25 metals studied), regardless of their thermodynamic compatibility. Additionally, we show high-performance electrosynthesis of hydrogen peroxide to highlight this approach as a promising method for electrocatalyst development.

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来源期刊

Nature chemistry 化学-化学综合

CiteScore

29.60

自引率

1.40%

发文量

226

审稿时长

1.7 months

期刊介绍： Nature Chemistry is a monthly journal that publishes groundbreaking and significant research in all areas of chemistry. It covers traditional subjects such as analytical, inorganic, organic, and physical chemistry, as well as a wide range of other topics including catalysis, computational and theoretical chemistry, and environmental chemistry. The journal also features interdisciplinary research at the interface of chemistry with biology, materials science, nanotechnology, and physics. Manuscripts detailing such multidisciplinary work are encouraged, as long as the central theme pertains to chemistry. Aside from primary research, Nature Chemistry publishes review articles, news and views, research highlights from other journals, commentaries, book reviews, correspondence, and analysis of the broader chemical landscape. It also addresses crucial issues related to education, funding, policy, intellectual property, and the societal impact of chemistry. Nature Chemistry is dedicated to ensuring the highest standards of original research through a fair and rigorous review process. It offers authors maximum visibility for their papers, access to a broad readership, exceptional copy editing and production standards, rapid publication, and independence from academic societies and other vested interests. Overall, Nature Chemistry aims to be the authoritative voice of the global chemical community.