Zeidler Anita, Drewitt James W E, Salmon Philip S, Barnes Adrian C, Crichton Wilson A, Klotz Stefan, Fischer Henry E, Benmore Chris J, Ramos Silvia, Hannon Alex C
Department of Physics, University of Bath, Bath BA2 7AY, UK.
J Phys Condens Matter. 2009 Nov 25;21(47):474217. doi: 10.1088/0953-8984/21/47/474217. Epub 2009 Nov 5.
The change in structure of glassy GeS(2) with pressure increasing to [Formula: see text] at ambient temperature was explored by using in situ neutron and x-ray diffraction. Under ambient conditions, the glass structure is made from a mixture of corner- and edge-sharing Ge(S(1/2))(4) tetrahedra where 47(5)% of the Ge atoms are involved in edge-sharing configurations. The network formed by these tetrahedra orders on an intermediate range as manifested by the appearance of a pronounced first sharp diffraction peak in the measured total structure factors at a scattering vector k = 1.02(2) Å(-1) which has a large contribution from Ge-Ge correlations. The intermediate range order breaks down when the pressure on the glass increases above ≈2 GPa but there does not appear to be a significant alteration of the Ge-S coordination number or corresponding bond length with increasing density. The results for the glass are consistent with a densification mechanism in which there is a replacement of edge-sharing by corner-sharing Ge centred tetrahedral motifs and/or a reduction in the Ge-[Formula: see text]-Ge bond angle between corner-sharing tetrahedral motifs with increasing pressure. The change in structure with increasing temperature at a pressure of [Formula: see text] was also investigated by means of in situ x-ray diffraction as the glass crystallized and then liquefied. At 5.2(1) GPa and 828(50) K the system forms a tetragonal crystal, with space group [Formula: see text] and cell parameters a = b = 4.97704(12) and c = 9.5355(4) Å, wherein corner-sharing Ge(S(1/2))(4) tetrahedra pack to form a dense three-dimensional network. A method is described for correcting x-ray diffraction data taken in situ under high pressure, high temperature conditions for a cylindrical sample, container and gasket geometry with a parallel incident beam and with a scattered beam that is defined using an oscillating radial collimator. A method is also outlined for obtaining coordination numbers from direct integration of the peaks in measured x-ray total pair distribution functions.
通过原位中子和X射线衍射研究了室温下玻璃态GeS₂在压力增加到[公式:见文本]时的结构变化。在环境条件下,玻璃结构由角共享和边共享的Ge(S₁/₂)₄四面体混合物组成,其中47(5)%的Ge原子参与边共享构型。这些四面体形成的网络在中间范围内有序排列,这表现为在散射矢量k = 1.02(2) Å⁻¹处测量的总结构因子中出现明显的第一个尖锐衍射峰,该峰对Ge-Ge相关性有很大贡献。当玻璃上的压力增加到约2 GPa以上时,中间范围有序性消失,但随着密度增加,Ge-S配位数或相应键长似乎没有明显变化。玻璃的结果与致密化机制一致,即随着压力增加,以角共享取代边共享的以Ge为中心的四面体 motif,和/或角共享四面体 motif 之间的Ge-[公式:见文本]-Ge键角减小。还通过原位X射线衍射研究了在[公式:见文本]压力下随着温度升高玻璃结晶然后液化时的结构变化。在5.2(1) GPa和828(50) K时,系统形成四方晶体,空间群为[公式:见文本],晶胞参数a = b = 4.97704(12)和c = 9.5355(4) Å,其中角共享的Ge(S₁/₂)₄四面体堆积形成致密的三维网络。描述了一种用于校正圆柱形样品、容器和垫片几何形状在高压、高温条件下且具有平行入射束和使用振荡径向准直器定义的散射束的原位X射线衍射数据的方法。还概述了一种从测量的X射线总对分布函数中的峰直接积分获得配位数的方法。
