Formation of Xenon Hydrate from a Vapor–Gas Medium

S. I. Ninenko; Ниненко С. И.; E. V, Zhovnerchuk; Жовнерчук Е. В.

doi:10.31857/S0044453723060225

Formation of Xenon Hydrate from a Vapor–Gas Medium

Autores: Ninenko S.¹, Zhovnerchuk E.²^,3
Afiliações:
1. Vereshchagin Institute of High Pressure Physics, Russian Academy of Sciences
2. Izmerov Institute of Occupational Medicine
3. Academy of Postgraduate Education, Federal Medical-Biological Agency
Edição: Volume 97, Nº 6 (2023)
Páginas: 800-804
Seção: ФИЗИЧЕСКАЯ ХИМИЯ РАСТВОРОВ
URL: https://journals.rcsi.science/0044-4537/article/view/136614
DOI: https://doi.org/10.31857/S0044453723060225
EDN: https://elibrary.ru/KCSEFA
ID: 136614

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Sobre autores
Bibliografia
Arquivos suplementares
Estatísticas

Resumo

Special two-chamber setups are used to study the formation of xenon hydrates from a vapor–gas medium, depending on the volume of the chamber. The effect different parameters have on the growth of hydrates and the degree of saturation is studied. Hydrate growth conditions with saturation indices close to ideal are determined. Based on the experimental data, an estimate is made of the size of the crystalline hydrate nucleus (minimum size, 10–15 µm). It is established that for the emergence of such a nucleus from a vapor–gas medium, the required amount of steam at a temperature of 5°C is contained in a sphere 1 cm in diameter. Conditions are determined for the growth of a hydrate with saturation close to theoretical from a vapor–gas medium. It is shown that the rate of hydrate formation in a vapor–gas medium is several orders of magnitude higher than the one for liquid water. Raising the initial temperature of the vapor–gas medium increases both the rate of hydrate formation and the proportion of such hydrate.

Palavras-chave

xenon hydrate, hydrate formation, xenon clathrate

Sobre autores

S. Ninenko

Vereshchagin Institute of High Pressure Physics, Russian Academy of Sciences

Email: ninenko@hppi.troitsk.ru
108840, Moscow, Russia

E. Zhovnerchuk

Izmerov Institute of Occupational Medicine; Academy of Postgraduate Education, Federal Medical-Biological Agency

Autor responsável pela correspondência
Email: ninenko@hppi.troitsk.ru
105275, Moscow, Russia; 125371, Moscow, Russia

Bibliografia

Бык С.Ш., Макогон Ю.Ф., Фомин В.И. Газовые гидраты. М.: Химия, 1980. 296 с.
Белослудов В.Р., Дядин Ю.А., Лаврентьев М.Ю. Теоретические модели клатратообразования. Новосибирск: Наука, 1999. 129 с.
Истомин В.А. Физико-химические исследования газовых гидратов: проблемы и перспективы. М.: ИРЦ ГАЗПРОМ, 2000. 71 с.
Manakov A.Y., Rodionova T.V., Penkov N.V. et al. // Russ. Chem. Rev. – 2017. V. 86. № 9. P. 845. – EDN YWBOAP.https://doi.org/10.1070/RCR4720
Божко Ю.Ю., Субботин О.С., Гец К.В. и др. // Журн. структур химии. 2017. Т. 58. № 5. С. 891. – EDN ZDIQHP.https://doi.org/10.15372/JSC20170501
Kobelev A., Yashin V., Penkov N. et al. // Crystals. 2019. V. 9. № 4. P. 215. – EDN JWMCVG.https://doi.org/10.3390/cryst9040215
Гудмундссон Й.С. / Способ транспортирования или хранения гидратов газов // Патент № 2200727 C2 РФ – EDN CVLPFZ.
Стопорев А.С., Семенов А.П. / Способ получения клатратных гидратов для хранения и транспортировки газов // Патент № 2704971 C1 РФ – EDN JQDXTV.
Law L.S.C., Lo E.A.G., Chan C.C.C. et al. // Canad. J. Anaesthesia. 2018. V. 65. № 9. P. 1041. – EDN YBVQDR.https://doi.org/10.1007/s12630-018-1163-6
Ярыгин Н.В., Шомина Е.А. // Практическая медицина. 2022. Т. 20. № 4. С. 171. – EDN EVVOBE.
Жовнерчук Е.В., Ниненко С.И. / Способ введения ксенона в организм человека при проведении ксенонотерапии // Патент № 2706424 C1 РФ – EDN JIZOAA.
Жовнерчук Е.В., Ниненко С.И. / Способ получения фармацевтической субстанции гидрат ксенона (Хе + + 6Н2О) // Заявка на патент РФ № 2022105182 от 28.02.2022.