Combinatorial Synthesis of Oxysulfides in the Lanthanum–Bismuth-Copper System

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Mitsutaro Umehara, Lan Zhou, Joel A. Haber, Dan Guevarra, Kevin Kan, Paul F. Newhouse, John M. Gregoire*
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引用次数: 1

Abstract

Establishing synthesis methods for a target material constitutes?a grand challenge in materials research, which is compounded with use-inspired specifications on the format of the material. Solar photochemistry using thin film materials is a promising technology for which many complex materials are being proposed, and the present work describes application of combinatorial methods to explore the synthesis of predicted La–Bi–Cu oxysulfide photocathodes, in particular alloys of LaCuOS and BiCuOS. The variation in concentration of three cations and two anions in thin film materials, and crystallization thereof, is achieved by a combination of reactive sputtering and thermal processes including reactive annealing and rapid thermal processing. Composition and structural characterization establish composition-processing-structure relationships that highlight the breadth of processing conditions required for synthesis of LaCuOS and BiCuOS. The relative irreducibility of La oxides and limited diffusion indicate the need for high temperature processing, which conflicts with the temperature limits for mitigating evaporation of Bi and S. Collectively the results indicate that alloys of these phases will require reactive annealing protocols that are uniquely tailored to each composition, motivating advancement of dynamic processing capabilities to further automate discovery of synthesis routes.

Abstract Image

镧-铋-铜体系中氧化硫化物的组合合成
建立目标材料的合成方法构成?材料研究中的一个巨大挑战,它与材料格式的使用启发规范相结合。利用薄膜材料的太阳光化学是一项很有前途的技术,许多复杂的材料正在被提出,本工作描述了组合方法的应用,以探索预测的La-Bi-Cu氧化硫化光电阴极的合成,特别是LaCuOS和BiCuOS合金。薄膜材料中三个阳离子和两个阴离子的浓度变化及其结晶是通过反应性溅射和包括反应性退火和快速热处理的热过程的组合来实现的。组成和结构表征建立了组成-加工-结构关系,突出了合成LaCuOS和BiCuOS所需的加工条件的广度。La氧化物的相对不可还原性和有限的扩散表明需要高温处理,这与减轻Bi和s蒸发的温度限制相冲突。总的结果表明,这些相的合金将需要针对每种成分独特定制的反应退火方案,推动动态处理能力的进步,以进一步自动化发现合成路线。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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