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Volume 10 Issue 2
Jun.  2022
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Zhang C, Xiao Q, Wu Z, et al. 2022. Ecosystem-driven karst carbon cycle and carbon sink effects. Journal of Groundwater Science and Engineering, 10(2): 99-112 doi:  10.19637/j.cnki.2305-7068.2022.02.001
Citation: Zhang C, Xiao Q, Wu Z, et al. 2022. Ecosystem-driven karst carbon cycle and carbon sink effects. Journal of Groundwater Science and Engineering, 10(2): 99-112 doi:  10.19637/j.cnki.2305-7068.2022.02.001

Ecosystem-driven karst carbon cycle and carbon sink effects

doi: 10.19637/j.cnki.2305-7068.2022.02.001
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  • It is recognized that karst processes are actively involved in the current global carbon cycle based on twenty years research, and the carbon sink occurred in karst processes is possibly an important part of “missing sink” in global carbon cycle. In this paper, an overview is given on karst carbon cycle research, and influence factors, formed carbon pools (background carbon sink) and sink increase potentials of current karst carbon cycle are analyzed. Carbonate weathering could contribute to the imbalance item (BIM) and land use change item (ELUC) in the global carbon cycle model, owing to its uptake of both atmospheric CO2 (carbon sink effect) and CO2 produced by soil respiration (carbon source reduction effect). Karst carbon sink includes inorganic carbon sink resulted from hydrogeochemical process and organic carbon sink generated by aquatic photosynthetic DIC conversion, forming relatively stable river (reservoir) water body or sediment carbon sink. The sizes of both sinks are controlled by terrestrial ecosystems and aquatic ecosystems, respectively. Desertification rehabilitation and carbon sequestration by aquatic plants are two effective ways to increase the carbon sink in karst area. It is estimated that the rate of carbon sink is at least 381 000 t CO2/a with vegetation restoration and afforestation in southwest China karst area, while the annual organic carbon sink generated by aquatic photosynthesis is about 84 200 t C in the Pearl River Basin. The development of a soil CO2 based model for assessment of regional dissolution intensity will help to improve the estimation accuracy of carbon sink increase and potential, thus provide a more clear and efficient karst sink increase scheme and pathway to achieve the goals of “double carbon”. With the deep investigation on karst carbon cycle, mechanism and carbon sink effect, and the improvement of watershed carbon sink measurement methods and regional sink increase evaluation approaches. Karst carbon sink is expected to be included in the list of atmospheric CO2 sources/sinks of the global carbon budget in the near future.
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  • Amiotte SP, Probst JL. 1993. Modelling of atmospheric CO2 consumption by chemical weathering of rocks: Application to the Garonne, Congo and Amazon basins. Chemical Geology, 107: 205-210. doi:  10.1016/0009-2541(93)90174-H
    Andrews JA, Schlesinger WH. 2001. Soil CO2 dynamics, acidification, and chemical weathering in a temperate forest with experimental CO2 enrichment. Global Biogeochemical cycles, 15(1): 149-162. doi:  10.1029/2000GB001278
    Cao JH, Yang H, Kang ZQ. 2011. Preliminary regional estimation of carbon sink flux by carbonate rock corrosion: A case study of the Pearl River Basin. Chinese Science Bulletin, 56: 3766-3773. doi:  10.1007/s11434-011-4377-3
    Cao JH, Wu X, Huang F, et al. 2018. Global significance of the carbon cycle in the karst dynamic system: Evidence from geological and ecological processes. China Geology, 1: 17-27. doi:  10.31035/cg2018004
    Chen B, Yang R, Liu ZH, et al. 2014. Effects of aquativ phototrophs on diurnal hydrochemical and δ13CDIC variations in an epikarst spring and two spring-fed ponds of Laqiao, Maolan, SW China. Geochimica, 43(4): 375-385. (in Chinese)
    Chen JA, Yang HQ, Zeng Y, et al. 2018. Combined use of radiocarbon and stable carbon isotope to constrain the sources and cycling of particular organic carbon in a large frestwater lake, China. Science of the Total Environment, 625: 27-38. doi:  10.1016/j.scitotenv.2017.12.275
    Ciais P, Sabine C, Bala G, et al. 2014. Carbon and other biogeochemical cycles//Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, 2014: 465-570.
    Cicerone DS, Stewart AJ, Roh Y. 1999. Diel cycles in calcite production and dissolution in a eutrophic basin. Environmental Toxicology and Chemistry, 18: 2169-2177. doi:  10.1002/etc.5620181008
    Cole JJ, Prairie YT, Caraco NF, et al. 2007. Plumbing the global carbon cycle: Integrating inland waters into the terrestrial carbon budget. Ecosystems, 10(1): 172-185. doi:  10.1007/s10021-006-9013-8
    Curl RL. 2012. Carbon shifted but not sequestered. Science, 335(6069): 655. doi:  10.1126/science.335.6069.655-a
    Dong XL, Cohen MJ, Martin JB, et al. 2018. Ecohydrologic processes and soil thickness feedbacks control limestone-weathering rates in a karst landscape. Chemical Geology: 527. doi:  10.1016/j.chemgeo.2018.05.021
    Dreybrodt W. 1988. Processes in Karst systems: Physics, Chemistry, and Geology. Berlin Heidelberg: Springer-Verlag, 288 pages with 184 figures.
    Drogue C, Yuan D. 1987. Genese des magasins karstiques, analyse comparative des valeurs actuelles de la dissolution naturelle des roches carbonates d’apres des examples en China et dans d’autres parties du Monde. Carsologica Sinica, 6: 127-136.
    Fang JY, Guo ZD, Piao SL, et al. 2007. Terrestrial vegetation carbon sinks in China, 1981-2000. Science in China, Series D, 37: 804-812.
    Ford D, Williams P. 2007. Karst hydrogeology and geomorphology. Chichester: John Wiley & Sons: 1-562.
    Friedlingstein P, O’Sullivan M, Jones MW, et al. 2020. Global carbon budget 2020. Earth System Science Data, 12: 3269-3340. doi:  10.5194/essd-12-3269-2020
    Gaillardet J, Calmels D, Romero-Mujalli G, et al. 2019. Global climate control on carbonate weathering intensity. Chemical Geology, 527: 118762. doi:  10.1016/j.chemgeo.2018.05.009
    Gams I. 1981. Comparative research of limestone solution by means of standard tablets (Second preliminary report of the commission of karst denudation, ISU). In Proceedings of 8th International Congress of Speleology, 1: 273-275.
    Guasch H, Armengol J, Martí E, et al. 1998. Diurnal variation in dissolved oxygen and carbon dioxide in two low-order streams. Water Research, 32: 1067-1074. doi:  10.1016/S0043-1354(97)00330-8
    Gulley JD, Martin JB, Moore PJ, et al. 2015. Heterogeneous distributions of CO2 may be more important for dissolution and karstification in coastal eogenetic limestone than mixing dissolution. Earth Surface Processes and Landforms, 40: 1057-1071. doi:  10.1002/esp.3705
    Guo Y, Wang F, Qin DJ, et al. 2021. Hydrodynamic characteristics of a typical karst spring system based on time series analysis in northern China. China Geology, 4: 433-445. doi:  10.31035/cg2021049
    Hartley AM, House WA, Leadbeater BSC, et al. 1996. The use of microelectrodes to study the precipitation of calcite upon algal biofilms. Journal of Colloid and Interface Science, 183: 498-505. doi:  10.1006/jcis.1996.0573
    He HB, Liu ZH, Chen CY, et al. 2020. The sensitivity of the carbon sink by coupled carbonate weathering to climate and land-use changes: Sediment records of the biological carbon pump effect in Fuxian Lake, Yunnan, China, during the past century. Science of the Total Environment, 720: 137539. doi:  10.1016/j.scitotenv.2020.137539
    He QF, Xiao Q, Fan JX, et al. 2022. The impact of heterotrophic bacteria on recalcitrant dissolved organic carbon formation in a typical karstic river. Science of the Total Environment, 815: 152576. doi:  10.1016/j.scitotenv.2021.152576
    Hèlie JF, Hillaireill-Marcel C, Rondeau B. 2002. Seasonal changes in the sources and fluxes of dissolved inorganic carbon through the St. Lawrence River — Isotopic and chemical constraint. Chemical Geology, 186(1): 117-138. doi:  10.1016/S0009-2541(01)00417-X
    Hinsinger P, Barros ONF, Benedetti MF, et al. 2001. Plant-induced weathering of a basaltic rock: Experimental evidence. Geochim Cosmochim Acta, 65: 137-152. doi:  10.1016/S0016-7037(00)00524-X
    Jiang ZC, Qin XQ, Cao JH, et al. 2011. Calculation of atmospheric CO2 sink formed in karst progresses of the karst divided regions in China. Carsologica Sinica, 2011, 30(4): 363-367. (in Chinese)
    Jiang ZC, Yuan DX, Cao JH, et al. 2012. A study of carbon sink capacity of karst processes in China. Acta Geoscientica Sinica, 33(2): 129-134. (in Chinese) doi:  10.3975/cagsb.2012.02.01
    Jiang ZC, Yuan DX. 1999. CO2 source-sink in karst processes in karst areas of China. Episodes, 22: 33-35. doi:  10.18814/epiiugs/1999/v22i1/005
    Kanduč T, Szramek K, Ogrinc N, et al. 2007. Origin and cycling of riverine inorganic carbon in the Sava River watershed (Slovenia) inferred from major solutes and stable carbon isotopes. Biogeochemistry, 86: 137-154. doi:  10.1007/s10533-007-9149-4
    Kempe S, Pettine M, Cauwet G. 1991. Biogeochemistry of European rivers. In: Kempe S, Degens ET, Richey JE (eds) Biogeochemistry of major world rivers. Wiley, New York, SCOPE/UNEP 42: 169-211.
    Kump LR, Brantley SL, Arthur MA. 2000. Chemical weathering, atmospheric CO2, and climate. Annual Review of Earth and Planetary Sciences, 28: 611-667. doi:  10.1146/annurev.earth.28.1.611
    Lal R. 2008. Carbon sequestration. Philosophical Transactions of the Royal Society B-Biological Sciences, 363(1492): 815-830. doi:  10.1098/rstb.2007.2185
    Lan JC, Fu WL, Peng JT, et al. 2013. Dissolution rate under soil in karst areas and the influencing factors of different land use patterns. Acta Ecologica Sinica, 33(10): 3205-3212. (in Chinese) doi:  10.5846/stxb201202290269
    Langmuir D. 1997. Aqueous environmental chemistry. Prentice-Hall, Inc. , New Jersey.
    Le Quéré C, Andres RJ, Boden T, et al. 2012. The global carbon budget 1959-2011. Earth System Science Data Discussions, 5(2): 1107-1157. doi:  10.5194/essdd-5-1107-2012
    Le Quéré C, Peters GP, Andres RJ, et al. 2014. Global carbon budget 2013. Earth System Science Data, 6(1): 235-263. doi:  10.5194/essd-6-235-2014
    Li HW, Wang SJ, Bai XY, et al. 2018. Spatiotemporal distribution and national measurement of the global carbonate carbon sink. Science of the Total Environment, 643: 157-170. doi:  10.1016/j.scitotenv.2018.06.196
    Li HW, Wang SJ, Bai XY, et al. 2019. Spatiotemporal evolution of carbon sequestration of limestone weathering in China. Science China Earth Sciences, 62(6): 974-991. doi:  10.1007/s11430-018-9324-2
    Li R, Yu S, Sun PA, et al. 2015. Characteristics of δ13C in typical aquatic plants and carbon sequestration by plant photosynthesis in the Banzhai catchment, Maolan of Guizhou Province. Carsologica Sinica, 34(1): 9-16. (in Chinese) doi:  10.11932/karst20150102
    Li W, Yu LJ, Yuan DX, et al. 2004. Bacteria biomass and carbonic anhydrase activity in some karst areas of southwest China. Journal of Asian Earth Sciences, 24: 145-152. doi:  10.1016/j.jseaes.2003.10.008
    Lian B, Yuan DX, Liu ZH. 2011. Effect of microbes on karstification in karst ecosystems. Chinese Science Bulletin, 56: 3743-3747. doi:  10.1007/s11434-011-4648-z
    Liu Z, Dreybrodt W, Wang H. 2010. A new direction in effective accounting for the atmospheric CO2 budget: Considering the combined action of carbonate dissolution, the global water cycle and photosynthetic uptake of DIC by aquatic organisms. Earth-Science Reviews, 99: 162-172. doi:  10.1016/j.earscirev.2010.03.001
    Liu Z, Dreybrodt W. 1997. Dissolution kinetics of calcium carbonate minerals in H2O–CO2 solutions in turbulent flow: The role of the diffusion boundary layer and the slow reaction H2O+CO2↔H++HCO3. Geochim Cosmochim Acta, 61: 2879-2889. doi:  10.1016/s0016-7037(97)00143-9
    Liu Z, Dreybrodt W. 2015. Significance of the carbon sink produced by H2O–carbonate–CO2–aquatic phototroph interaction on land. Science Bulletin, 60(2): 182-191. doi:  10.1007/s11434-014-0682-y
    Liu Z, Liu X, Liao C. 2008. Daytime deposition and nighttime dissolution of calcium carbonate controlled by submerged plants in a karst spring-fed pool: Insights from high time-resolution monitoring of physico-chemistry of water. Environmental Geology, 55: 1159-1168. doi:  10.1007/s00254-007-1062-6
    Liu Z, Zhao J. 2000. Contribution of carbonate rock weathering to the atmospheric CO2 sink. Environmental Geology, 39: 1053-1058. doi:  10.1007/s002549900072
    Liu ZH, Dreybrodt W, Wang HJ. 2007. A potentially important CO2 sink caused by the global water cycle. Chinese Science Bulletin, 52(20): 2418-2422. (in Chinese) doi:  10.3321/j.issn:0023-074x.2007.20.013
    Liu ZH, Groves C, Yuan DX, et al. 2004. South China karst aquifer storm-scale hydrochemistry. Ground Water, 42(4): 491-499. doi:  10.1111/j.1745-6584.2004.tb02617.x
    Liu ZH, Macpherson GL, Groves C, et al. 2018. Large and active CO2 uptake by coupled carbonate weathering. Earth-Science Reviews, 182: 42-49. doi:  10.1016/j.earscirev.2018.05.007
    Liu ZH. 2000. Two important sinks of atmospheric CO2. Chinese Science Bulletin, 45: 2348-2351. (in Chinese) doi:  10.3321/j.issn:0023-074X.2000.21.020
    Melnikov NB, O’Neill BC. 2006. Learning about the carbon cycle from global budget data. Geophysical Research Letters, 33(2): L02705. doi:  10.1029/2005GL023935
    Merkel BJ, Planer-Friedrich B. 2005. Groundwater Geochemistry. Berlin: Springer: 1-200.
    Montety VD, Martin JB, Cohen MJ, et al. 2011. Influence of diel biogeochemical cycles on carbonate equilibrium in a karst river. Chemical Geology, 283: 31-43.
    Pan GX, Sun YH, Teng YZ, et al. 2000. Distribution and transferring of carbon in kast soil system of peak forest depression in humid subtropical regon. Chinese Journal of Applied Ecology, 11(1): 69-72. (in Chinese) doi:  10.13287/j.1001-9332.2000.0018
    Pei JG, Zhang C, Zhang Q, et al. 2012. Flux estimation of carbon sink in typical karst water systems. Rock and Mineral Analysis, 31(05): 884-888. (in Chinese)
    Plummer LN, Wigley TML, Parkhurst DL. 1978. Kinetics of calcite dissolution in CO2-water systems at 5℃ to 60℃ and 0.0 to 1.0 atm CO2. American Journal of Sciences, 278: 179-216. doi:  DOI:10.2475/ajs.278.2.179
    Pu JB, Jiang ZC, Yuan DX, et al. 2015. Some opinions on rock weathering related carbon sinks from the IPCC fifth assessment report. Advances in Earth Science, 30(10): 1081-1090. (in Chinese) doi:  10.11867/j.issn.1001-8166.2015.10.1081
    Pulina M. 1974. Denudacja chemiczna Na Obszarach karsu Weglanowego. Polska Academic Nauk, Instytut Geografii, Prace Geograficzne NR105: 1-159.
    Qin XQ, Jiang ZC, Zhang LK, et al. 2015. The difference of the weathering rate between carbonate rocks and silicate rocks and its effects on the atmospheric CO2 consumption in the Pearl River Basin. Geological Bulletin of China, 34(9): 1749-1757. (in Chinese)
    Regnier P, Friedlingstein P, Ciais P, et al. 2013. Anthropogenic perturbation of the carbon fluxes from land to ocean. Nature Geoscience, 6(8): 597-607. doi:  10.1038/ngeo1830
    Schindlbacher A, Borken W, Djukic I, et al. 2015. Contribution of carbonate weathering to the CO2 efflux from temperate forest soils. Biogeochemistry, 124: 273-273. doi:  10.1007/s10533-015-0097-0
    Simonsen JF, Harremoës P. 1978. Oxygen and pH fluctuations in rivers. Water Research, 12: 477-489. doi:  10.1016/0043-1354(78)90155-0
    Spiro B, Pentecost A. 1991. One day in the life of a stream — a diurnal inorganic carbon mass balance for travertine-depositing stream (Waterfall Beck, Yorkshire). Geomicrobiology Journal, 9: 1-11. doi:  10.1080/01490459109385981
    The State Council Information Office of the People’s Republic of China. 2021. Responding to Climate Change: China's Policies and Actions. [2021-11-5].
    Wang FM, Zhang JF, Ye SY, et al. 2022. Coastal blue carbon ecosystems in China. China Geology, 5: 193-194. doi:  10.31035/cg2022007
    Wang JL, Zhang C, Pei JG, et al. 2015. Diel changes of dissolved inorganic carbon and calcite precipitation in a typical karst spring-fed stream. Earth and Environment, 43(4): 395-402. (in Chinese) doi:  10.14050/j.cnki.1672-9250.2015.04.003
    Waterson EJ, Canuel EA. 2008. Sources of sedimentary organic matter in the Mississippi River and adjacent Gulf of Mexico as revealed by lipid biomarker and δ13CTOC analyses. Organic Geochemistry, 39(4): 422-439. doi:  10.1016/j.orggeochem.2008.01.011
    Xiao Q, Zhao HJ, Zhang C, et al. 2020. Study of the recalcitrant dissolved organic carbon in karst surface water. Quaternary Sciences, 40(4): 1058-1069. (in Chinese) doi:  10.11928/j.issn.10017410.2020.04.1
    Yang MX, Liu ZH, Sun HL, et al. 2016. Organic carbon source tracing and DIC fertilization effect in the Pearl River: Insights from lipid biomarker and geochemical analysis. Applied Geochemistry, 73: 132-141. doi:  10.1016/j.apgeochem.2016.08.008
    Yang R, Chen B, Liu H, et al. 2015. Carbon sequestration and decreased CO2 emission caused by terrestrial aquatic photosynthesis: Insights from diel hydrochemical variations in an epikarst spring and two spring-fed ponds in different seasons. Applied Geochemistry, 63(3): 248-260. doi:  10.1016/j.apgeochem.2015.09.009
    Yoshimura K, Inokura Y. 1997. The geochemical cycle of carbon dioxide in a carbonate rock area, Akiyoshi-dai Plateau, Yamaguchi, Southwestern, Japan. In: Proceedings of 30th International Geological Congress, 24: 114-126.
    Yu GR, Wang QF, Fang HJ. 2014. Fundamental scientific issues, theoretical framework and relative research methods of carbon-nitrogen-water coupling cycles in terrestrial ecosystems. Quaternary Sciences, 34(4): 683-698. (in Chinese) doi:  10.3969/j.issn.1001-7410.2014.04.01
    Yu XY, Ye SY. 2020. The universal applicability of logistic curve in simulating ecosystem carbon dynamic. China Geology, 3: 292-298. doi:  10.31035/cg2020029
    Yuan DX. 1997. Sensitivity of karst process to environmental change along the PEP II transect. Quaternary International, 37: 105-113. doi:  10.1016/1040-6182(96)00012-2
    Yuan DX. 1998. Contribution of IGCP379 “Karst Processes and Carbon Cycle” to global change. Episodes, 21(3): 198.
    Yuan DX. 1999. Progress in the study on karst processes and carbon cycle. Advance in Earth Sciences, 14(5): 425-432. (in Chinese).
    Yuan DX. 2009. Developing on the karst dynamics theory and the foundation of the international research center on karst under the auspice of UNESCO. Carsologica Sinica, 28(2): VII-X.
    Yuan DX. 2011. Foreword for the special topic “Geological Processs in Carbon Cycle”. Chinese Science Bulletin, 56(35): 3741-3742. doi:  10.1007/s11434-011-9944-0
    Yuan DX, Jiang ZC. 2000. Progress of IGCP379 “Karst processes and the carbon cycle” in China. Hydrogeology and Engineering Geology, 27(1): 49-51. (in Chinese)
    Yuan DX, Zhang C. 2002. Karst Processes and the carbon cycle-Final Report of IGCP379. Beijing: Geological Publishing House. 1-220.
    Zhang C. 2011. Carbonate rock dissolution rates in different landuses and their carbon sink effect. Chinese Science Bulletin, 56(35): 3759-3765. doi:  10.1007/s11434-011-4404-4
    Zhang C, Wang JL, Pu JB, et al. 2012. Bicarbonate daily variations in a karst river: The carbon sink effect of subaquatic vegetation photosynthesis. Acta Geologica Sinica (English Edition), 86(4): 973-979. doi:  10.1111/j.1755-6724.2012.00721.x
    Zhang C, Wang JL, Xiao Q. 2017. The sources and diurnal changes of dissolved inorganic carbon in Chaotian river, Guilin, China. Quaternary Sciences, 37(6): 1283-1292. (in Chinese) doi:  10.11928/j.issn.10017410.2017.06.1
    Zhang C, Wang JL, Xiao Q, et al. 2021. Day and night variations of dissolved inorganic carbon and flux in Chaotian river, Guilin, Guangxi. Acta Geoscientica Sinica, 42(4): 555-564. (in Chinese) doi:  10.3975/cagsb.2020.110301
    Zhang C, Wang JL, Xiao Q, et al. 2022. Wintertime CO2 changes in a typical karst soil profile in Slovenia. Acta Ecologica Sinica, 42(8): 3288-3299. (in Chinese) doi:  10.5846/stxb202103200738
    Zhang C, Wang JL, Yan J. 2016a. Diel cycling and flux of HCO3 in a typical karst spring-fed stream of southwestern China. Acta Carsologica, 45(2): 107-122.
    Zhang C, Worakul M, Wang JL, et al. 2016b. Dissolution rates in soil of different landuses of typical tropical karst peak depression valley in Thailand. Quaternary Sciences, 36(6): 1393-1402. (in Chinese) doi:  10.11928/j.issn.10017410.2016.06.0
    Zhang C, Worakul M, Wang JL, et al. 2014. Hydrogeochemical features of Karst in the Western Thailand. Journal of Groundwater Science and Engineering, 2(2): 18-26.
    Zhang C, Xiao Q. 2021. Study on dissolved inorganic carbon migration and aquatic photosynthesis sequestration in Lijiang River, Guilin. Carsologica Sinica, 40(4): 555-564. (in Chinese) doi:  10.11932/karst20210401
    Zhang C, Xie YQ, Ning LD, et al. 2013. Characteristics of δ13C in typical aquatic plants and carbon sequestration in the Huixian karst wetland, Guilin. Carsologica Sinica, 32(3): 247-252. (in Chinese)
    Zhang C, Yuan DX, Cao JH. 2005. Analysis of the environmental sensitivities of a typical dynamic epikarst system at the Nongla monitoring site, Guangxi, China. Environmental Geology, 47: 615-619. doi:  10.1007/s00254-004-1186-x
    Zhang C, Pei JG, Xie YQ et al. 2008. Impact of land use covers upon karst processes in a typical Fengcong depression system of Nongla, Guangxi, China. Environmental Geology, 55(8): 1621-1626. doi:  10.1007/s00254-007-1111-1
    Zhang H, Zhou QP, Jiang YH, et al. 2022. Hydrochemical origins and weathering-controlled CO2 consumption rates in the mainstream of the Yangtze River. Hydrogeology & Engineering Geology, 49(1): 30-40. (in Chinese)
    Zhang Q. 2012. The Stability of carbon sink effect related to carbonate rock dissolution: A case study of the Caohai lake geological carbon sink. Acta Geoscientica Sinica, 33(6): 947-952. (in Chinese) doi:  10.3975/cagsb.2012.06.14
    Zhao LJ, Yang Y, Cao JW, et al. 2022. Applying a modified conduit flow process to understand conduit-matrix exchange of a karst aquifer. China Geology, 5: 26-33. doi:  10.31035/cg2021046
    Zhou GS, Jia BR, Han GX et al. 2008. Toward a general evaluation model for soil respiration (GEMSR). Science in China Series C: Life Science, 51(3): 254-262.
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    [13] ZHU Xi, ZHANG Qing-lian, WANG Wan-li, LIU Yan-guang, 2015: Study on the influencing factors of rock-soil thermophysical parameters in shallow geothermal energy, Journal of Groundwater Science and Engineering, 3, 256-267.
    [14] SUN Dong-sheng, ZHAO Wei-hua, LI A-wei, ZHANG An-bin, 2015: Analysis on method for effective in-situ stress measurement in hot dry rock reservoir, Journal of Groundwater Science and Engineering, 3, 9-15.
    [15] YANG Li-zhi, LIU Chun-hua, 2015: Study on the characteristics and causes of carbon tetrachloride pollution of karst water in eastern suburbs of Jinan, Journal of Groundwater Science and Engineering, 3, 331-341.
    [16] BAI Xi-qing, LIU Yan, 2014: Feasibility Analysis on Resuming Flow of Large Karst Spring in Heilongdong, Journal of Groundwater Science and Engineering, 2, 80-87.
    [17] LU Chuan, LI Long, LIU Yan-guang, WANG Gui-ling, 2014: Capillary Pressure and Relative Permeability Model Uncertainties in Simulations of Geological CO2 Sequestration, Journal of Groundwater Science and Engineering, 2, 1-17.
    [18] ZHANG Cheng, Mahippong Worakul, WANG Jin-liang, PU Jun-bing, LYU Yong, ZHANG Qiang, HUANG Qi-bo, 2014: Hydrogeochemical Features of Karst in the Western Thailand, Journal of Groundwater Science and Engineering, 2, 18-26.
    [19] Yun TANG, Ke-wang TANG, Yan WANG, Ai-min YANG, 2014: Study of Ecological Water Demand of Rivers in Shenyang City, Northeastern China, Journal of Groundwater Science and Engineering, 2, 73-77.
    [20] , 2013: The Study of Statistical Damage Constitutive Models of Rock and Its Parameters Based on Lade-Duncan Criterion, Journal of Groundwater Science and Engineering, 1, 74-79.
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