ИЗМЕНЕНИЕ ЭЛЕМЕНТА ФТОРА В ПОДЗЕМНЫХ ВОДАХ ВО ВРЕМЯ ЗЕМЛЕТРЯСЕНИЯ
Ключевые слова:
землетрясение, подземные воды, альбит, анортит, каолинит.
Аннотация
В статье проанализированы пробы, отобранные в скважинах Назарбек, Текистил, Фозилов и Сабзавотчилик (ИБК), расположенных в Ташкентском геодинамическом диапазоне, и показано изменение количества фтора в подземных водах во время землетрясений.
Литература
1. Геохимия подземных вод приташкентского артезианского бассейна (республика узбекистан) Гусева Наталья Владимировна, канд. геол.-минерал. наук, ст. науч. сотр. научно-образовательного центра «Вода», доцент кафедры гидрогеологии, инженерной геологии и гидрогеоэкологии Института природных ресурсов ТПУ, Россия, 634050, г. Томск, пр. Ленина, д. 30. E-mail: guseva24@yandex.ru
2. https://en.wikipedia.org/wiki/Earthquake#:~:text=External%20links Earthquake,-179%20languages
3. The formation of loess deposits in the Tashkent region and perts of Central Asia; and problems with irrigation, hydrocollapse and soil corrosion / I.J. Smalley, N.G. Mavlyanova, Kh.L. Rakmatullaev, M.Sh. Shermatov, B. Macholett, K. O’Hara Dhand, I.F. Jefferson // Quaternary International. – 2006. – V. 152–153. – P. 59–69.
4. Journal of Modern Technology and Engineering Vol.8, No.1, 2023, pp.54-62 THE ROLE OF ARTIFICIAL INTELLIGENCE IN EFFECTIVE EARTHQUAKE FORECASTING Ulugbek Turapov1 , Fidan Nuriyeva2,3∗ ID 1Jizzakh Polytechnic Institute, Department of Automation and Management of Production Processes, Jizzakh, Uzbekistan 2Dokuz Eylul University, Department of Computer Science, Izmir, Turkiye 3 Institute of Control Systems of ANAS, Baku, Azerbaijan
5. Fluorine in shallow groundwater in China: A review of distribution, occurrence and environmental effects. Volume 10 - 2022 | https://doi.org/10.3389/feart.2022.1084890 Ping Zhao1* Shuheng Zhang1 Kaijian Xu1 Yuejiao Zhao1 Pengju Shen1 Lele Zhu2 Liugen Zheng2
6. Zuo, R.; Liu, X.; Yang, J.; Zhang, H.K.; Li, J.; Teng, Y.G.; Yue, W.F.; Wang, J.S. Distribution, origin and key influencing factors of fluoride groundwater in the coastal area, NE China. Hum. Ecol. Risk Assess. 2019, 25, 104–119. [Google Scholar] [CrossRef]
7. Rajveer, S.D.; Manan, S. A holistic study on fluoride-contaminated groundwater models and its widespread effects in healthcare and irrigation. Environ. Sci. Pollut. Res. 2021, 28, 60329–60345. [Google Scholar] [CrossRef
8. Apambire W.B., Boyle D.R., Michel F.A. Geochemistry, genesis, and health implications of fluoriferous groundwaters in the upper regions of Ghana. Environ. Earth Sci. 1997;33:13–24. doi: 10.1007/s002540050221.
9. Fuge R. Fluorine in the environment, a review of its sources and geochemistry. Appl.Geochem. 2019;100:393–406. doi: 10.1016/j.apgeochem.2018.12.016.
10. Ковальский В.В. Геохимическая экология. М.: Нау ка, 1974. 299 с.
2. https://en.wikipedia.org/wiki/Earthquake#:~:text=External%20links Earthquake,-179%20languages
3. The formation of loess deposits in the Tashkent region and perts of Central Asia; and problems with irrigation, hydrocollapse and soil corrosion / I.J. Smalley, N.G. Mavlyanova, Kh.L. Rakmatullaev, M.Sh. Shermatov, B. Macholett, K. O’Hara Dhand, I.F. Jefferson // Quaternary International. – 2006. – V. 152–153. – P. 59–69.
4. Journal of Modern Technology and Engineering Vol.8, No.1, 2023, pp.54-62 THE ROLE OF ARTIFICIAL INTELLIGENCE IN EFFECTIVE EARTHQUAKE FORECASTING Ulugbek Turapov1 , Fidan Nuriyeva2,3∗ ID 1Jizzakh Polytechnic Institute, Department of Automation and Management of Production Processes, Jizzakh, Uzbekistan 2Dokuz Eylul University, Department of Computer Science, Izmir, Turkiye 3 Institute of Control Systems of ANAS, Baku, Azerbaijan
5. Fluorine in shallow groundwater in China: A review of distribution, occurrence and environmental effects. Volume 10 - 2022 | https://doi.org/10.3389/feart.2022.1084890 Ping Zhao1* Shuheng Zhang1 Kaijian Xu1 Yuejiao Zhao1 Pengju Shen1 Lele Zhu2 Liugen Zheng2
6. Zuo, R.; Liu, X.; Yang, J.; Zhang, H.K.; Li, J.; Teng, Y.G.; Yue, W.F.; Wang, J.S. Distribution, origin and key influencing factors of fluoride groundwater in the coastal area, NE China. Hum. Ecol. Risk Assess. 2019, 25, 104–119. [Google Scholar] [CrossRef]
7. Rajveer, S.D.; Manan, S. A holistic study on fluoride-contaminated groundwater models and its widespread effects in healthcare and irrigation. Environ. Sci. Pollut. Res. 2021, 28, 60329–60345. [Google Scholar] [CrossRef
8. Apambire W.B., Boyle D.R., Michel F.A. Geochemistry, genesis, and health implications of fluoriferous groundwaters in the upper regions of Ghana. Environ. Earth Sci. 1997;33:13–24. doi: 10.1007/s002540050221.
9. Fuge R. Fluorine in the environment, a review of its sources and geochemistry. Appl.Geochem. 2019;100:393–406. doi: 10.1016/j.apgeochem.2018.12.016.
10. Ковальский В.В. Геохимическая экология. М.: Нау ка, 1974. 299 с.
Опубликован
2024-03-30
Как цитировать
Nazokat SATTTORVA, Gulhayo HASANOVA, Alisher RASULOV, & Kamoliddin MIRZAAXMEDOV. (2024). ИЗМЕНЕНИЕ ЭЛЕМЕНТА ФТОРА В ПОДЗЕМНЫХ ВОДАХ ВО ВРЕМЯ ЗЕМЛЕТРЯСЕНИЯ. Вестник УзМУ, 3(3.1), 291-295. https://doi.org/10.69617/uzmu.v3i3.1.1813
Раздел
Статьи