Colloidal Nanoparticles of High Entropy Materials: Capabilities, Challenges, and Opportunities in Synthesis and Characterization

IF 4.8 Q2 NANOSCIENCE & NANOTECHNOLOGY ACS Nanoscience Au Pub Date : 2023-11-16 DOI:10.1021/acsnanoscienceau.3c00049
Gaurav R. Dey, Samuel S. Soliman, Connor R. McCormick, Charles H. Wood, Rowan R. Katzbaer and Raymond E. Schaak*, 
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Abstract

Materials referred to as “high entropy” contain a large number of elements randomly distributed on the lattice sites of a crystalline solid, such that a high configurational entropy is presumed to contribute significantly to their formation and stability. High temperatures are typically required to achieve entropy stabilization, which can make it challenging to synthesize colloidal nanoparticles of high entropy materials. Nonetheless, strategies are emerging for the synthesis of colloidal high entropy nanoparticles, which are of interest for their synergistic properties and unique catalytic functions that arise from the large number of constituent elements and their interactions. In this Perspective, we highlight the classes of materials that have been made as colloidal high entropy nanoparticles as well as insights into the synthetic methods and the pathways by which they form. We then discuss the concept of “high entropy” within the context of colloidal materials synthesized at much lower temperatures than are typically required for entropy to drive their formation. Next, we identify and address challenges and opportunities in the field of high entropy nanoparticle synthesis. We emphasize aspects of materials characterization that are especially important to consider for nanoparticles of high entropy materials, including powder X-ray diffraction and elemental mapping with scanning transmission electron microscopy, which are among the most commonly used techniques in laboratory settings. Finally, we share perspectives on emerging opportunities and future directions involving colloidal nanoparticles of high entropy materials, with an emphasis on synthesis, characterization, and fundamental knowledge that is needed for anticipated advances in key application areas.

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高熵材料的胶体纳米粒子:合成和表征的能力、挑战和机遇
被称为“高熵”的材料包含大量随机分布在晶体固体晶格位置的元素,因此,高构型熵被认为对它们的形成和稳定性有重要贡献。通常需要高温来实现熵稳定,这使得合成高熵材料的胶体纳米颗粒具有挑战性。尽管如此,合成胶体高熵纳米粒子的策略正在出现,它们的协同特性和独特的催化功能引起了人们的兴趣,这些功能来自于大量组成元素及其相互作用。在这个观点中,我们强调了已经制成胶体高熵纳米粒子的材料类别,以及对合成方法和它们形成的途径的见解。然后,我们讨论了“高熵”的概念,在胶体材料合成的温度远低于通常需要的熵来驱动它们的形成。接下来,我们识别和解决高熵纳米粒子合成领域的挑战和机遇。我们强调材料表征的各个方面,特别是考虑到高熵材料的纳米颗粒,包括粉末x射线衍射和扫描透射电子显微镜的元素映射,这是实验室环境中最常用的技术之一。最后,我们分享了关于高熵材料胶体纳米颗粒的新兴机会和未来方向的观点,重点是合成,表征和关键应用领域预期进展所需的基础知识。
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来源期刊
ACS Nanoscience Au
ACS Nanoscience Au 材料科学、纳米科学-
CiteScore
4.20
自引率
0.00%
发文量
0
期刊介绍: ACS Nanoscience Au is an open access journal that publishes original fundamental and applied research on nanoscience and nanotechnology research at the interfaces of chemistry biology medicine materials science physics and engineering.The journal publishes short letters comprehensive articles reviews and perspectives on all aspects of nanoscience and nanotechnology:synthesis assembly characterization theory modeling and simulation of nanostructures nanomaterials and nanoscale devicesdesign fabrication and applications of organic inorganic polymer hybrid and biological nanostructuresexperimental and theoretical studies of nanoscale chemical physical and biological phenomenamethods and tools for nanoscience and nanotechnologyself- and directed-assemblyzero- one- and two-dimensional materialsnanostructures and nano-engineered devices with advanced performancenanobiotechnologynanomedicine and nanotoxicologyACS Nanoscience Au also publishes original experimental and theoretical research of an applied nature that integrates knowledge in the areas of materials engineering physics bioscience and chemistry into important applications of nanomaterials.
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