Sun Jian, Klug Dennis D, Martonák Roman, Montoya Javier Antonio, Lee Mal-Soon, Scandolo Sandro, Tosatti Erio
Steacie Institute for Molecular Sciences, National Research Council of Canada, Ottawa, K1A 0R6, Canada.
Proc Natl Acad Sci U S A. 2009 Apr 14;106(15):6077-81. doi: 10.1073/pnas.0812624106. Epub 2009 Mar 30.
Understanding the structural transformations of solid CO(2) from a molecular solid characterized by weak intermolecular bonding to a 3-dimensional network solid at high pressure has challenged researchers for the past decade. We employ the recently developed metadynamics method combined with ab initio calculations to provide fundamental insight into recent experimental reports on carbon dioxide in the 60-80 GPa pressure region. Pressure-induced polymeric phases and their transformation mechanisms are found. Metadynamics simulations starting from the CO(2)-II (P4(2)/mnm) at 60 GPa and 600 K proceed via an intermediate, partially polymerized phase, and finally yield a fully tetrahedral, layered structure (P-4m2). Based on the agreement between calculated and experimental Raman and X-ray patterns, the recently identified phase VI [Iota V, et al. (2007) Sixfold coordinated carbon dioxide VI. Nature Mat 6:34-38], assumed to be disordered stishovite-like, is instead interpreted as the result of an incomplete transformation of the molecular phase into a final layered structure. In addition, an alpha-cristobalite-like structure (P4(1)2(1)2), is predicted to be formed from CO(2)-III (Cmca) via an intermediate Pbca structure at 80 GPa and low temperatures (<300 K). Defects in the crystals are frequently observed in the calculations at 300 K whereas at 500 to 700 K, CO(2)-III transforms to an amorphous form, consistent with experiment [Santoro M, et al. (2006) Amorphous silica-like carbon dioxide. Nature 441:857-860], but the simulation yields additional structural details for this disordered solid.
在过去十年中,理解固态二氧化碳从以弱分子间键合为特征的分子固体转变为高压下的三维网络固体的结构转变一直是研究人员面临的挑战。我们采用最近开发的元动力学方法并结合从头算计算,以深入了解最近关于60 - 80 GPa压力区域内二氧化碳的实验报告。发现了压力诱导的聚合物相及其转变机制。从60 GPa和600 K的CO₂-II(P4₂/mnm)开始的元动力学模拟通过一个中间的部分聚合相进行,最终产生一个完全四面体的层状结构(P-4m2)。基于计算得到的拉曼光谱和X射线图谱与实验结果的一致性,最近确定的相VI [Iota V等人(2007年)六配位二氧化碳VI。《自然·材料》6:34 - 38],原本被认为是无序的类似斯石英的结构,现在被解释为分子相不完全转变为最终层状结构的结果。此外,预测在80 GPa和低温(<300 K)下,CO₂-III(Cmca)会通过一个中间的Pbca结构形成类似α-方石英的结构(P4₁2₁2)。在300 K的计算中经常观察到晶体中的缺陷,而在500至700 K时,CO₂-III转变为非晶态,这与实验结果[桑托罗M等人(2006年)无定形二氧化硅类二氧化碳。《自然》441:857 - 860]一致,但模拟为这种无序固体提供了额外的结构细节。