Intense Reactivity in Sulfur-Hydrogen Mixtures at High Pressure under X-ray Irradiation

Edward J. Pace; Amy L. Coleman; Rachel J. Husband; Huijeong Hwang; Jinhyuk Choi; Taehyun Kim; Gilchan Hwang; Sae Hwan Chun; Daewoong Nam; Sangsoo Kim; Orianna B. Ball; Hanns Peter Liermann; Malcolm I. McMahon; Yongjae Lee; R. Stewart McWilliams

doi:10.1021/acs.jpclett.9b03797

Intense Reactivity in Sulfur-Hydrogen Mixtures at High Pressure under X-ray Irradiation

Edward J. Pace, Amy L. Coleman, Rachel J. Husband, Huijeong Hwang, Jinhyuk Choi, Taehyun Kim, Gilchan Hwang, Sae Hwan Chun, Daewoong Nam, Sangsoo Kim, Orianna B. Ball, Hanns Peter Liermann, Malcolm I. McMahon, Yongjae Lee, R. Stewart McWilliams

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Abstract

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 (H₂) and elemental sulfur (S₈) 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 (H₂S) 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.

Original language	English
Pages (from-to)	1828-1834
Number of pages	7
Journal	Journal of Physical Chemistry Letters
Volume	11
Issue number	5
DOIs	https://doi.org/10.1021/acs.jpclett.9b03797
Publication status	Published - 2020 Mar 5

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Publisher Copyright:
© 2020 American Chemical Society.

All Science Journal Classification (ASJC) codes

General Materials Science
Physical and Theoretical Chemistry

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10.1021/acs.jpclett.9b03797

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Pace, E. J., Coleman, A. L., Husband, R. J., Hwang, H., Choi, J., Kim, T., Hwang, G., Chun, S. H., Nam, D., Kim, S., Ball, O. B., Liermann, H. P., McMahon, M. I., Lee, Y., & McWilliams, R. S. (2020). Intense Reactivity in Sulfur-Hydrogen Mixtures at High Pressure under X-ray Irradiation. Journal of Physical Chemistry Letters, 11(5), 1828-1834. https://doi.org/10.1021/acs.jpclett.9b03797

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title = "Intense Reactivity in Sulfur-Hydrogen Mixtures at High Pressure under X-ray Irradiation",

abstract = "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 (H2) and elemental sulfur (S8) 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 (H2S) 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.",

author = "Pace, {Edward J.} and Coleman, {Amy L.} and Husband, {Rachel J.} and Huijeong Hwang and Jinhyuk Choi and Taehyun Kim and Gilchan Hwang and Chun, {Sae Hwan} and Daewoong Nam and Sangsoo Kim and Ball, {Orianna B.} and Liermann, {Hanns Peter} and McMahon, {Malcolm I.} and Yongjae Lee and McWilliams, {R. Stewart}",

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doi = "10.1021/acs.jpclett.9b03797",

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Pace, EJ, Coleman, AL, Husband, RJ, Hwang, H, Choi, J, Kim, T, Hwang, G, Chun, SH, Nam, D, Kim, S, Ball, OB, Liermann, HP, McMahon, MI, Lee, Y & McWilliams, RS 2020, 'Intense Reactivity in Sulfur-Hydrogen Mixtures at High Pressure under X-ray Irradiation', Journal of Physical Chemistry Letters, vol. 11, no. 5, pp. 1828-1834. https://doi.org/10.1021/acs.jpclett.9b03797

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AU - Pace, Edward J.

AU - Coleman, Amy L.

AU - Husband, Rachel J.

AU - Hwang, Huijeong

AU - Choi, Jinhyuk

AU - Kim, Taehyun

AU - Hwang, Gilchan

AU - Chun, Sae Hwan

AU - Nam, Daewoong

AU - Kim, Sangsoo

AU - Ball, Orianna B.

AU - Liermann, Hanns Peter

AU - McMahon, Malcolm I.

AU - Lee, Yongjae

AU - McWilliams, R. Stewart

PY - 2020/3/5

Y1 - 2020/3/5

N2 - 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 (H2) and elemental sulfur (S8) 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 (H2S) 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.

AB - 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 (H2) and elemental sulfur (S8) 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 (H2S) 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.

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Intense Reactivity in Sulfur-Hydrogen Mixtures at High Pressure under X-ray Irradiation

Abstract

Bibliographical note

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