Russian Journal of Earth Sciences Russian Journal of Earth Sciences Russian Journal of Earth Sciences 1681-1208 54849 10.2205/2022ES000806 ОРИГИНАЛЬНЫЕ СТАТЬИ ORIGINAL ARTICLES ОРИГИНАЛЬНЫЕ СТАТЬИ ON SOME FEATURES OF ULTRASOUND REFLECTION WATER-SAMPLE IN AN INCLINED FALL (PHYSICAL MODELING) ON SOME FEATURES OF ULTRASOUND REFLECTION WATER-SAMPLE IN AN INCLINED FALL (PHYSICAL MODELING) Федин Константин Владимирович Fedin Konstantin Vladimirovich Лукьянова Алина Lukyanowa Alina Колесников Юрий Иванович Kolesnikov Yuriy Ivanovich ФГБУН Институт нефтегазовой геологии и геофизики имени А. А. Трофимука СО РАН Россия Trofimuk Institute of Petroleum Geology and Geophysics​ of Siberian Branch Russian Academy of Sciences (IPGG SB RAS) Russian Federation Новосибирский государственный технический университет Новосибирск Россия Novosibirsk State Technical University Novosibirsk Russian Federation Новосибирский государственный университет Россия Novosibirsk State University Russian Federation Новосибирский государственный университет Новосибирск Россия Novosibirsk State University Novosibirsk Russian Federation Институт нефтегазовой геологии и геофизики имени А. А. Трофимука СО РАН Россия Trofimuk Institute of Petroleum-Gas Geology and Geophysics, SB RAS Russian Federation 04 12 2022 04 12 2022 22 5 1 10 07 04 2022 09 08 2022 https://rjes.ru/en/nauka/article/54849/view

In recent years, the analysis of the dependence of reflection coefficients on the magnitude of the angle of incidence of reflected waves has been successfully used in the practice of seismic research. AVO analysis is one of the methods of dynamic analysis that is used to estimate changes in the amplitude of reflected waves depending on the distance between the explosion points and the receivers. The AVO method is based on the analysis of the dependence of the reflection coefficients on the angle of incidence. In real conditions, this dependence can be determined, for example, by the roughness of the boundaries. This determines the relevance of studying the features of reflection coefficients on uneven boundaries on objects with well-controlled properties. The aim of the work is to determine the nature of the influence of different-scale roughness of seismic boundaries on the reflection coefficients of elastic waves. The work also used the technique of isolating standing waves to determine the wave velocity. As a result, graphs were obtained demonstrating the dependence of the reflection coefficients on the magnitude of the angle of incidence of reflected waves from a rough surface. Reflection coefficients were also obtained for the boundary of an isotropic medium in the direction of the isotropy plane and possible ways of applying the results were analyzed. Based on the data obtained, we can say that when the azimuth changes relative to the direction of the surface, the reflection coefficients change significantly only at the supercritical angles of incidence.

In recent years, the analysis of the dependence of reflection coefficients on the magnitude of the angle of incidence of reflected waves has been successfully used in the practice of seismic research. AVO analysis is one of the methods of dynamic analysis that is used to estimate changes in the amplitude of reflected waves depending on the distance between the explosion points and the receivers. The AVO method is based on the analysis of the dependence of the reflection coefficients on the angle of incidence. In real conditions, this dependence can be determined, for example, by the roughness of the boundaries. This determines the relevance of studying the features of reflection coefficients on uneven boundaries on objects with well-controlled properties. The aim of the work is to determine the nature of the influence of different-scale roughness of seismic boundaries on the reflection coefficients of elastic waves. The work also used the technique of isolating standing waves to determine the wave velocity. As a result, graphs were obtained demonstrating the dependence of the reflection coefficients on the magnitude of the angle of incidence of reflected waves from a rough surface. Reflection coefficients were also obtained for the boundary of an isotropic medium in the direction of the isotropy plane and possible ways of applying the results were analyzed. Based on the data obtained, we can say that when the azimuth changes relative to the direction of the surface, the reflection coefficients change significantly only at the supercritical angles of incidence.

 rough boundaries reflection coefficients elastic waves physical modeling. rough boundaries reflection coefficients elastic waves physical modeling. The study was supported by the Russian Science Foundation, grant №22-29-00289 The study was supported by the Russian Science Foundation, grant №22-29-00289

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