Short-Range-Order for fcc-based binary alloys Revisited from Microscopic Geometry

Koretaka Yuge
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Abstract

Short-range order (SRO) in disordered alloys is typically interpreted as competition between chemical effect of negative (or positive) energy gain by mixing constituent elements and geometric effects comes from difference in effective atomic radius. Although we have a number of theoretical approaches to quantitatively estimate SRO at given temperatures, it is still unclear to systematically understand trends in SRO for binary alloys in terms of geometric character, e.g., effective atomic radius for constituents. Since chemical effect plays significant role on SRO, it has been believed that purely geometric character cannot quantitatively explain the SRO trends. Despite these considerations, based on the density functional theory (DFT) calculations on fcc-based 28 equiatomic binary alloys, we find that while convensional Goldschmidt or DFT-based atomic radius for constituents have no significant correlation with SRO, atomic radius for specially selected structure, constructed purely from information about underlying lattice, can successfully capture the magnitude of SRO. These facts strongly indicate that purely geometric information of the system plays central role to determine characteristic disordered structure.
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从微观几何重新审视fcc基二元合金的近程序
无序合金中的短程有序(SRO)通常被解释为组成元素混合产生的负(或正)能量增益的化学效应与有效原子半径差异产生的几何效应之间的竞争。虽然我们有许多理论方法来定量估计给定温度下的SRO,但系统地了解二元合金在几何特征(例如成分的有效原子半径)方面的SRO趋势仍然不清楚。由于化学效应在SRO中起着重要的作用,人们认为单纯的几何特征不能定量地解释SRO的趋势。尽管有这些考虑,基于密度泛函理论(DFT)对基于fcc的28等原子二元合金的计算,我们发现,虽然传统的Goldschmidt或基于DFT的成分原子半径与SRO没有显著的相关性,但纯从基础晶格信息构建的特殊选择结构的原子半径可以成功捕获SRO的大小。这些事实强烈地表明,系统的纯几何信息对确定特征无序结构起着核心作用。
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