Degradation of frozen hydrate-containing saline rocks under thermal influence from below and above

封面

如何引用文章

全文:

开放存取 开放存取
受限制的访问 ##reader.subscriptionAccessGranted##
受限制的访问 订阅或者付费存取

详细

A mathematical model has been formulated for the degradation of saline permafrost rocks (MMP) containing ice, accumulations of metastable self-conserved gas hydrates and free gas due to climate warming and the influence of heat flow from below. In the simplest case, an analytical expression of the laws of reservoir degradation is obtained from the model from above due to an increase in temperature at the upper boundary, and from below due to the inclusion of an increased heat flow. It is shown that degradation from below occurs mainly according to a linear law in time, while degradation from above occurs more slowly, i.e. only according to the root law. The proposed model and the obtained simplest formulas can be used to study the degradation fronts of a frozen formation not only due to ice melting, but also earlier and faster decomposition fronts of metastable gas hydrates without ice melting. The corresponding thermodynamic points are close. As an application of the model, a specific numerical variant is considered and the curves of the degradation fronts are illustrated.

作者简介

L. Lobkovsky

Shirshov Institute of Oceanology

Email: ipgnatali@mail.ru
Moscow, Russia

M. Ramazanov

Institute for Problems of Geothermy and Renewable Energy, Branch of the Joint Institute of High Temperatures; Sadovsky Institute of Geosphere Dynamics

Email: ipgnatali@mail.ru
Makhachkala, Russia; Moscow, Russia

N. Bulgakova

Institute for Problems of Geothermy and Renewable Energy, Branch of the Joint Institute of High Temperatures

编辑信件的主要联系方式.
Email: ipgnatali@mail.ru
Makhachkala, Russia

参考

  1. Gramberg I.S., Kulakov Yu. N., Pogrebitsky Yu.E., Sorokov D.S. Arctic oil and gas super basin / X World Petroleum Congress. London. 1983. P. 93‒99.
  2. Shakhova N., Semiletov I., Chuvilin E. Understanding the Permafrost–Hydrate System and Associated Methane Releases in the East Siberian Arctic Shelf // Geosciences. 2019. 9(6).
  3. Makogon Y.F., Holditch S.A., Makogon T.Y. Natural gas-hydrates — A potential energy source for the 21st Century // Journal of Petroleum Science and Engineering. 2007. 56(1):14‒26.
  4. Криотермия и натуральные газогидраты в Северном ледовитом океане (под ред. В.А. Соловьева). Изд-во: Севморгеология. Ленинград, 1987. 150 c.
  5. Shakhova N.E., Semiletov I.P. Methane Hydrate Feedbacks / In: Martin Sommerkorn & Susan Joy Hassol, eds., Arctic Climate Feedbacks: Global Implications. Published by WWF International Arctic Programme August. 2009. ISBN: 978-2-88085-305-1, p. 81–92.
  6. Ramazanov M.M., Bulgakova N.S., Lobkovsky L.I., Chuvilin E.M., Davletshina D.A., Shakhova N.E. Dissociation kinetics of methane hydrate in frozen rocks under decreasing external pressure: mathematical and experimental modeling // Doklady Earth Sciences. 2024. V. 516. № 2. P. 1028–1035.
  7. Ramazanov M., Bulgakova N., Lobkovsky L. Mathematical model of freezing of rocks saturated with salt solution taking into account the influence of osmosis // Russian Journal of Earth Sciences. 2023. V. 23. № 5. P. ES5007.
  8. Ramazanov M.M., Bulgakova N.S., Lobkovsky L.I., Chuvilin E.M., Gadzhimagomedova S.R., Shakhova N.E. Freezing Patterns in Saline Soils: Modeling with Regard to the Osmotic Effect // Russian Journal of Earth Sciences. 2024. V. 24. № 4. P. ES4008.

补充文件

附件文件
动作
1. JATS XML
下载

版权所有 © Russian Academy of Sciences, 2025