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Assessment of carbon dioxide exchange processes between water bodies and the atmosphere | ||
Caspian Journal of Environmental Sciences | ||
دوره 21، شماره 5، اسفند 2023، صفحه 1239-1245 اصل مقاله (698.05 K) | ||
نوع مقاله: Research Paper | ||
شناسه دیجیتال (DOI): 10.22124/cjes.2023.7419 | ||
نویسندگان | ||
P.S. Korotkih1؛ E.N. Neverov* 2؛ I.A. Korotkiy1 | ||
1Department of Heat and Cooling Engineering, Kemerovo State University, Russia | ||
2Department of Technosphere Security, Kemerovo State University, Russia | ||
چکیده | ||
Calculating the volume of carbon dioxide absorbed by the ocean is a challenging task because it depends on numerous factors, including depth, temperature, salinity, and others. Calculating the precise volume of CO2 absorbed by the ocean is even more difficult due to the complex and dynamic nature of these processes. Some studies and models provide only an approximate assessment of the annual carbon balance between the atmosphere and the ocean. The purpose of the present study was to examine the processes of CO2 exchange between water and the surrounding environment. For experimental testing, the authors developed a special apparatus used to conduct a series of studies to assess CO2 exchange processes between water and the environment. Studies were performed on distilled, fresh, and salt water. Dissolving CO2 in fresh and salt water is a complex process that plays a key part in the environment's biological, climatic, and geochemical aspects. The initial CO2 concentration in the operational volume of the experimental setup was 5,000 ppm (parts per million; 5%). The temperature inside the chamber amounted to 20 ± 2 ºC. The experiment lasted 10 days. Since the most important factor in the experiment was precision, the study employed the method of gas chromatography. Investigation of these features provided a better understanding of the importance of managing CO2 levels and its impact on Earth’s ecosystem. | ||
کلیدواژهها | ||
Carbon dioxide؛ Disposal؛ Atmosphere؛ Ocean؛ Uptake؛ Dissolution؛ Water body | ||
مراجع | ||
Aipeisova, S, Utarbayeva, N, Maui, A, Kazkeev, E & Baubekova, A 2023, Fabaceae Lindl. Species in the Floristic composition of the Aktobe Floristic District. International Journal of Environmental Studies, 80: 1076-1087, https://doi.org/10.1080/00207233.2022.2136851.
Akbayeva, L, Beisenova, R, Tazitdinova, R, Kobetaeva, N & Mamytova, N 2023, Hydrobiological assessment of water quality in the Yesil River, Astana Region: An environmental evaluation. International Journal of Design & Nature and Ecodynamics, 18: 557-564, https://doi.org/10.18280/ijdne.180307.
Alhendi, N 2022, The Role of International Legislation in Protecting the Environment. Journal of Environmental Management and Tourism, 13: 174-180, DOI:10.14505/jemt.v13.1(57).16.
Baideldynov, D, Jangabulova, A, Yerezhepkyzy, R, Berdibaуeva, A & Khamit, A 2019, Central Asian transboundary waters in the age of globalization: Problems of legal regulation and international cooperation. Journal of Environmental Management and Tourism, 10: 1060-1073.
Bekezhanov, D, Kopbassarova, G, Zhunispayeva, A, Urazymbetov, T & Seilkassymova, R 2021, Environmental problems of international legal regulation of transboundary pollution. Journal of Environmental Management and Tourism, 12: 392-405.
Blodau, C 2002, Carbon cycling in peatlands A review of processes and controls. Environmental Reviews. 10: 111-134.
Bostubayeva, M, Baimbetova, E, Makenova, M, Shumenova, N, Sarmanova, R, & Nauanova, A 2023, Screening and evaluation of potential microbial bio-activators used in sewage sludge composting. Caspian Journal of Environmental Sciences, 21: 575-583, DOI: 10.22124/cjes.2023.6936
Dubovik, M, Dmitriev, S, Shaposhnikov, A M, Xalmatjanova, G 2023, Technology for obtaining information on CO2 emissions caused by natural and man-made factors using the ARIMA model. Journal of Theoretical and Applied Information Technology, 101: 2586-2602.
Florides, GA 2009, Christodoulides P Global warming and carbon dioxide through sciences. Environment International, 35: 390-401.
Gao, Y et al. 2022, Carbon transportation, transformation, and sedimentation processes at the land-river-estuary continuum. Fundamental Research, https://doi.org/10.1016/j.fmre.2022.07.007.
Hartmann, J et al. 2013, Enhanced chemical weathering as a geoengineering strategy to reduce atmospheric carbon dioxide, supply nutrients, and mitigate ocean acidification. Reviews of Geophysics, 51: 113-149.
Jahad, UA, Al-Ameri, R, Chabuk, A, Majdi, A, Majdi, HSh, Al-Ansari, N & Laue, J 2022, Dissolved oxygen variation on the steps with a quarter circle end sill for flows over the stepped spillways. International Journal of Design & Nature and Ecodynamics, 17: 639-648, https://doi.org/10.18280/ijdne.170501.
Keller, DP et al. 2018, The effects of carbon dioxide removal on the carbon cycle. Current Climate Change Reports, 4: 250-265.
Khayyatnezhad, M & Keynoos, H 2022, Incorporating Conditional Uncertainty into Decision-making for Forecasting Actual Evapotranspiration in Semiarid Area. Advancements in Life Sciences, 9: 498-503.
Komarova, IP, Bondarenko, NE, Gubarev, RV & Ermolaev, SA 2022, Carbon unit market: international experience and approaches to forming the Russian model. International Journal of Ecosystems and Ecology Science (IJEES), 12: 409-420.
Komarova, I, Bondarenko, N, & Baibikova, K 2023, Carbon landfills as a new step towards achieving carbon neutrality of Russian regions in the context of ESG transformation. Journal of Law and Sustainable Development, 11(1), e0275. https://doi.org/10.37497/sdgs.v11i1.275.
Kuderina, A, Kuderin, I, Bekezhanov, D, Nurbek, D & Amreeva, I 2021, Environmental and legal regulation of the handling of chemicals. Journal of Environmental Management and Tourism, 12: 371-381.
Kulanov, A, Issakhova, A, Koshkina, O, Issakhova, P & Karshalova, A 2020, Venture Financing and the Fuel and Energy Complex: Investing in Alternative Energy. International Journal of Energy Economics and Policy, 10: 531-538, Retrieved from https://econjournals.com/index.php/ijeep/article/view/9963.
Kulshikova, E, Zhayliev, A, Yerekeshova, A & Kalieva, S 2023, Evaluation of solar radiation and atmospheric air during hay harvesting in Kazakhstan. OnLine Journal of Biological Sciences, 23: 65-70. https://doi.org/10.3844/ojbsci.2023.65.70.
Martirosyan, AV, Ilyushin, YV & Afanaseva, OV 2022, Development of a distributed mathematical model and control system for reducing pollution risk in mineral water aquifer systems. Water 14: 151. https://doi.org/10.3390/w14020151.
Motamedi, R, Gholizadeh, M, Patimar, R, & Raeisi, H 2023, Assessment of aquatic ecosystem health in Gorgan Bay based on biotic indices. Caspian Journal of Environmental Sciences, 21: 711-723, DOI: 10.22124/cjes.2023.6958.
Mustafayeva, B, Kaltayeva, S, Saparova, A, Alimkulova, E, & Kulbayeva, M 2019, The impact of agricultural environmental pollutions on the population’s quality of life. The Experience of Kazakhstan. Journal of Environmental Management and Tourism, 10: 161-170. DOI:10.14505//jemt.10.1(33).16.
Narozhnykh, KN, Konovalova, TV, Fedyaev, JI, Demetiev, VN & Osadchuk, LV 2018, Lead content in soil, water, forage, grains, organs and the muscle tissue of cattle in Western Siberia (Russia). Indian Journal of Ecology, 45: 866-871.
Neverov EN, Korotkiy IA, Korotkaya EV & Rasshchepkin AN 2021, Studying the sublimation of carbon dioxide. Periodico Tche Quimica, 18: 1-12.
Różkowski, J, & Rzętała, M 2021, Uzbekistan’s aquatic environment and water management as an area of interest for hydrology and thematic tourism. Journal of Environmental Management and Tourism, 12: 642-653, DOI:10.14505//jemt.v12.3(51).04.
Yadav, G & Sen, R 2017, Microalgal green refinery concept for bio-sequestration of carbon-dioxide vis-à-vis wastewater remediation and bioenergy production: Recent technological advances in climate research. Journal of CO2 Utilization, 17: 188-206. | ||
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