Pace Edward J, Coleman Amy L, Husband Rachel J, Hwang Huijeong, Choi Jinhyuk, Kim Taehyun, Hwang Gilchan, Chun Sae Hwan, Nam Daewoong, Kim Sangsoo, Ball Orianna B, Liermann Hanns-Peter, McMahon Malcolm I, Lee Yongjae, McWilliams R Stewart
SUPA, School of Physics and Astronomy & Centre for Science at Extreme Conditions, The University of Edinburgh, Edinburgh EH9 3FD, United Kingdom.
Lawrence Livermore National Laboratory, 7000 East Avenue, Livermore, California 94500, United States.
J Phys Chem Lett. 2020 Mar 5;11(5):1828-1834. doi: 10.1021/acs.jpclett.9b03797. Epub 2020 Feb 20.
Superconductivity near room temperature in the sulfur-hydrogen system arises from a sequence of reactions at high pressures, with X-ray diffraction experiments playing a central role in understanding these chemical-structural transformations and the corresponding S:H stoichiometry. Here we document X-ray irradiation acting as both a probe and as a driver of chemical reaction in this dense hydride system. We observe a reaction between molecular hydrogen (H) and elemental sulfur (S) under high pressure, induced directly by X-ray illumination, at photon energies of 12 keV using a free electron laser. The rapid synthesis of hydrogen sulfide (HS) at 0.3 GPa was confirmed by optical observations, spectroscopic measurements, and microstructural changes detected by X-ray diffraction. These results document X-ray induced chemical synthesis of superconductor-forming dense hydrides, revealing an alternative production strategy and confirming the disruptive nature of X-ray exposure in studies on high-pressure hydrogen chalcogenides, from water to high-temperature superconductors.
硫 - 氢体系中接近室温的超导性源于高压下的一系列反应,X射线衍射实验在理解这些化学结构转变以及相应的硫与氢化学计量比方面发挥着核心作用。在此,我们记录了在这种致密氢化物体系中,X射线辐照既作为一种探针,又作为化学反应的驱动因素。我们观察到在高压下,使用自由电子激光,在12千电子伏特的光子能量下,分子氢(H₂)与元素硫(S)之间直接由X射线照射引发的反应。通过光学观测、光谱测量以及X射线衍射检测到的微观结构变化,证实了在0.3吉帕压力下硫化氢(H₂S)的快速合成。这些结果记录了X射线诱导形成超导体的致密氢化物的化学合成过程,揭示了一种替代生产策略,并证实了在从水到高温超导体的高压氢化物研究中,X射线照射具有破坏性。
