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Volume 35 Issue 2
Apr.  2016
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ZENG Si-bo, JIANG Yong-jun. Impact of Land-Use and Land-Cover change on the carbon sink produced by karst processes: A review[J]. CARSOLOGICA SINICA, 2016, 35(2): 153-163. doi: 10.11932/karst20160204
Citation: ZENG Si-bo, JIANG Yong-jun. Impact of Land-Use and Land-Cover change on the carbon sink produced by karst processes: A review[J]. CARSOLOGICA SINICA, 2016, 35(2): 153-163. doi: 10.11932/karst20160204

Impact of Land-Use and Land-Cover change on the carbon sink produced by karst processes: A review

doi: 10.11932/karst20160204
  • Publish Date: 2016-04-25
  • Based on a new conceptual model of carbon cycle induced by the weathering carbonate rocks, the study of karst process is now having a new direction for researchers to find stable carbon sink in terrestrial carbon cycle ecosystem. The carbon cycle produced by the weathering of carbonate rocks used to be considered as an unchanged carbon sink since preindustrial times in global carbon model. However, a synthesis of recently published work reveals that Land Use/Cover Change (LUCC) due to human activities have altered these carbon fluxes. This paper is intended to review the observations concerning carbonate the response of rock weathering to LUCC, as well as a thorough analysis for their mechanisms. Recent findings show that the impact of LUCC on carbon cycle in karst process is complicated and this cycle is dependent on three aspects, i.e. soil pCO2, runoff fluctuation and the involvement of some inorganic acids, which may interact each other and control the magnitudes, variations of carbonate rock weathering under various LUCC. The effect of the first two aspects may present negative correlation, and the mechanisms of inorganic acids have different effects in the new model. Meanwhile, previous studies ignored the autochthonous organic carbon (AOC) produced in surface stream ecosystem which has great carbon sequestration capacity. The response process and mechanism to LUCC is a new direction of karst carbon cycle study. However, because of the complexity and diversity of the carbonate rock weathering under LUCC, it is difficult to determine the relationship between DIC and AOC variations in various environmental conditions caused by LUCC. Therefore, how to probe into the mechanism of carbonate rock weathering and to establish a LUCC regulating strategy are important directions of future karst carbon cycle research.

     

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  • [1]
    Raupach M R, Marland G, Ciais P, et al. Global and regional drivers of accelerating CO2 emissions[J]. Proceedings of the National Academy of Sciences of the United States of America, 2007, 104(24): 10288-10293.
    [2]
    Melnikov N B, O'Neill B C. Learning about the carbon cycle from global budget data[J]. Geophysical Research Letters, 2006, 33(2):356-360.doi: 10.1029/2005GL023935.
    [3]
    Berner R A, Lasaga AC, Garrels R M. The carbonate-silicate geochemical cycle and its effect on atmospheric carbon-dioxide over the past 100 million years[J]. America Journal of Science, 1983, 283(7): 641-683.
    [4]
    Berner R A. Weathering, plants, and the long-term carbon cycle[J]. Geochimica et Cosmochimica Acta, 1992, 56(8): 3225-3231
    [5]
    Berner R A. The rise of plants and their effect on weathering and atmospheric CO2[J]. Science, 1997, 276(5321): 544-546.
    [6]
    刘再华, Dreybrodt W, 刘洹. 大气CO2汇:硅酸盐风化还是碳酸盐风化的贡献?[J]. 第四纪研究, 2011, 31(3): 426-430.
    [7]
    Liu Z H, Dreybrodt W, Wang H. 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[J]. Earth-Science Reviews, 2010, 99(3-4): 162-172.
    [8]
    Liu Z H, Dreybrodt W. Significance of the carbon sink produced by H2O–carbonate–CO2–aquatic phototroph interaction on land[J]. Science Bulletin, 2015, 60(2): 182-191.
    [9]
    Turner II B L, Moss R H, Skole DL. 1993: Relating land use and global land-cover change: A proposal for an IGBP-HDP core project[M], pp. 65, International Biosphere-Geosphere Program: A study of global change and the human dimensions of global environmental change programme, Stockholm.
    [10]
    DeFries R S, Field C B, Fung I, et al. Combining satellite data and biogeochemical models to estimate global effects of human-induced land cover change on carbon emissions and primary productivity[J]. Global Biogeochemical Cycles, 1999, 13(3): 803-815.
    [11]
    Schimel D S, House J I, Hibbard K A. Recent patterns and mechanisms of carbon exchange by terrestrial ecosystems[J]. Nature, 2000, 414(6860): 169-172.
    [12]
    Gislason S R, Oelkers E H, Eiriksdottir E S, et al. Direct evidence of the feedback between climate and weathering[J]. Earth and Planetary Science Letters, 2009, 277(1-2): 213-222.
    [13]
    Macpherson G L, Roberts J A, Blair J M, et al. Increasing shallow groundwater CO2, and limestone weathering, Konza Prairie, USA[J]. Geochimica et Cosmochimica Acta, 2008, 72(23):5581-5599.
    [14]
    Raymond P A, Oh N H, Turner R E, et al. Anthropogenically enhanced fluxes of water and carbon from the Mississippi River[J]. Nature, 2008, 451(7177): 449-452.
    [15]
    Battin T J, Luyssaert S, Kaplan L A, et al. The boundless carbon cycle[J]. Nature Geoscience, 2009, 2(9):598-600.
    [16]
    Dreybrodt W. Processes in karst systems [M].Springer Series in Physical Environment. Heidelberg: Springer, 1988.
    [17]
    White W B. Thermodynamic equilibrium, kinetics, activation barriers, and reaction mechanisms for chemical reactions in karst terrains[J]. Environmental Geology, 1997, 30(1): 46-58.
    [18]
    刘再华, 何师意, 袁道先,等. 土壤中的CO2及其对岩溶作用的驱动[J].水文地质工程地质, 1998, 4:42-45.
    [19]
    Raich J W, Potter C S, Bhagawati D. Interannual variability in global soil respiration 1980-94[J]. Global Change Biology, 2002, 8(8): 800-812.
    [20]
    Raich J W, Schlesinger W H.The global carbon dioxide flux in soil respiration and its relationship to vegetation and climate[J]. Tellus series B-chemical and physical meteorology, 1992, 44(2): 81-99.
    [21]
    G k M, Coupé V M H, Berkhof J, et al. Respiration as the main determinant of carbon balance in European forests[J]. Nature, 2000, 404(6780):861-865.
    [22]
    Yang R, Liu Z, Zeng C. Response of epikarst hydrochemical changes to soil CO2 and weather conditions at Chenqi, Puding, SW China[J]. Journal of Hydrology, 2012, 468:151-158.
    [23]
    Lloyd J, Taylor J A. On the temperature dependence of soil respiration[J]. Functional Ecology, 1994, 8(3): 315-323.
    [24]
    Davidson E A, Janssens I A. Temperature sensitivity of soil carbon decomposition and feedbacks to climate change[J]. Nature, 2006, 440(7081): 165-173.
    [25]
    Rey A, Pegoraro E, Tedeschi V, et al. Annual variation in soil respiration and its components in a coppice oak forest in Central Italy[J]. Global Change Biology, 2002, 8(9): 851-866.
    [26]
    Suseela V, Conant R T, Wallenstein M D, et al. Effects of soil moisture on the temperature sensitivity of heterotrophic respiration vary seasonally in an old-field climate change experiment[J]. Global Change Biology, 2012, 18(1): 336-348.
    [27]
    Schimel D S, Braswell B H, Holland E A, et al. Climatic, edaphic, and biotic controls over storage and turnover of carbon in soils[J]. Global Biogeochemical Cycles, 1994, 8(3): 279-293.
    [28]
    Hanson P J, Edwards N T, Garten C T, et al. Separating root and soil microbial contributions to soil respiration: A review of methods and observations[J]. Biogeochemistry, 2000, 48(1): 115-146.
    [29]
    Raich J W, Tufekcioglu A. Vegetation and soil respiration: correlations and controls[J]. Biogeochemistry, 2000, 48(1): 71-90.
    [30]
    Frank A B, Liebig M A, Tanaka D L. Management effects on soil CO2 efflux in northern semiarid grassland and cropland[J]. Soil & Tillage Research, 2006, 89(1): 78-85.
    [31]
    Smith D L, Johnson L. Vegetation-mediated changes in microclimate reduce soil respiration as woodlands expand into grasslands[J]. Ecology, 2004, 85(12): 3348-3361.
    [32]
    Knoll M A, James W C. Effect of the advent and diversification of vascular land plants on mineral weathering through geologic time[J]. Geology, 1987, 15(12): 1099-1102.
    [33]
    Cochran M F, Berner R A. Promotion of chemical weathering by higher plants: field observations on Hawaiian basalts[J]. Chemical Geology, 1996, 132(1-4): 71-77.
    [34]
    Liu Z H, Zhao J. Contribution of carbonate rock weathering to the atmospheric CO2 sink[J]. Environmental Geology, 2000, 39(9): 1053-1058.
    [35]
    Yan J H, Wang W T, Zhou C Y, et al. Responses of water yield and dissolved inorganic carbon export to forest recovery in the Houzhai karst basin, southwest China[J]. Hydrological Processes, 2014, 28(4): 2082-2090.
    [36]
    Andrews J A, Schlesinger W H. Soil CO2 dynamics, acidification, and chemical weathering in a temperate forest with experimental CO2 enrichment[J]. Global Biogeochemical Cycles, 2001, 15(1): 149-162.
    [37]
    Zhao M, Zeng C, Liu Z H, et al. Effect of different land use/land cover on karst hydrogeochemistry: A paired catchment study of Chenqi and Dengzhanhe, Puding, Guizhou, SW China[J]. Journal of Hydrology, 2010, 388(1-2): 121-130.
    [38]
    Lan F N, Qin X Q, Jiang Z C, et al. Influence of land use/land cover on hydrogeochemical indexes of karst groundwater in the Dagouhe Basin, Southwest China[J]. Clean-Soil Air Water, 2015, 43(5): 621-786.
    [39]
    Jiang Y, Yuan D, Zhang C, et al. Impact of land use change on groundwater quality in a typical karst watershed of southwest China[J]. Hydrogeology Journal, 2008, 16(4): 727-735.
    [40]
    章程. 不同土地利用下的岩溶作用强度及其碳汇效应[J]. 科学通报, 2011, 56(26):2174-2180.
    [41]
    王文娟, 蓝芙宁, 蒋忠诚,等. 湖南大龙洞流域不同岩性不同土地利用类型条件下碳酸盐岩试片的溶蚀速率[J]. 中国岩溶, 2013, 32(1):29-33.
    [42]
    刘再华. 岩石风化碳汇研究的最新进展和展望[J]. 科学通报, 2012, 57(z1):95-102.
    [43]
    袁道先. 地质作用与碳循环研究的回顾和展望[J]. 科学通报, 2011, 56(26):2157
    [44]
    肖时珍, 熊康宁, 蓝家程,等. 石漠化治理对岩溶地下水水化学和溶解无机碳稳定同位素的影响[J]. 环境科学, 2015, 36(5):1590-1597.
    [45]
    Sheng H, Yang Y, Yang Z, et al. The dynamic response of soil respiration to land-use changes in subtropical China[J]. Global Change Biology, 2010, 16(3): 1107-1121.
    [46]
    Zeng C, Liu Z, Zhao M, et al. Hydrologically-driven variations in the karst-related carbon sink fluxes: Insight form high-resolution monitoring of three karst catchments in Southwest China[J]. Journal of Hydrology, 2016, 533: 74-90.
    [47]
    Jackson R B, Jobbágy E G, Avissar R, et al. Trading Water for Carbon with Biological Carbon Sequestration[J]. Science, 2005, 310(5756): 1944-1947.
    [48]
    Scanlon B R, Reedy R C, Stonestrom D A. Impact of land use and land cover change on groundwater recharge and quality in the southwestern US[J]. Global Change Biology, 2005, 11(10): 1577-1593.
    [49]
    Mahe G, Paturel J E, Servat Eric. The impact of land use change on soil water holding capacity and river flow modelling in the Nakambe River, BurkinaFaso[J]. Journal of Hydrology, 2005, 300: 33-43.
    [50]
    Ahearn D S, Sheibley R W, Dahlgren R A. Land use and land cover influence on water quality in the last free-flowing river draining the western Sierra Nevada, California[J]. Journal of Hydrology, 2005, 313(3-4): 234-247.
    [51]
    Liu M, Tian H, Chen G, et al. Effect of land-use and land-cover change on Evapotranspiration and water yield in China during 1900-2000[J]. Journal of the American Water Resources Association, 2008, 44(5): 1993-1207.
    [52]
    Fan J, Oestergaard K T, Guyot A. Estimating groundwater recharge and evapotranspiration from water table fluctuations under three vegetation covers in a coastal sandy aquifer of subtropical Australia[J]. Journal of Hydrology, 2014, 519: 1120-1129.
    [53]
    Matheussen B, Kirschbaum R L, Goodman I A, et al. Effects of land cover change on stream flow in the interior Columbia River Basin (USA and Canada) [J]. Hydrological Processes, 2000, 14 (5): 867-885.
    [54]
    Petheram C, Walker G, Grayson R, et al. Towards a framework for predicting impacts of land-use on recharge: 1. A review of recharge studies in Australia[J]. Australian Journal of Soil Research, 2002, 40(3): 397-417.
    [55]
    Benyon R G, Theiveyanathan S, Doody T M. Impacts of tree plantations on groundwater in south-eastern Australia[J]. Australian Journal of Botany, 2006, 54(2): 181-192.
    [56]
    Zhang Y K, Schilling K E. Effects of land cover on water table, soil moisture, evapotranspiration, and groundwater recharge: A Field observation and analysis[J]. Journal of Hydrology, 2006, 319(1-4): 328-338.
    [57]
    Raymond P A, Cole J J. Increase in the Export of Alkalinity from North America's Largest River[J]. Science, 2003, 301(5629): 88-91.
    [58]
    Raymond P A, Bauer J E, Caraco N F, et al. Controls on the variability of organic matter and dissolved inorganic carbon ages in northeast US rivers[J]. Marine Chemistry, 2004, 92(1-4): 353-366.
    [59]
    Guo Y D, Song C, Wan Z, et al. Effects of long-term land use change on dissolved carbon characteristics in the permafrost streams of northeast China[J]. Environmental Science Prcocss & Impact, 2014, 16(11): 2096-2506.
    [60]
    Biemans H, Haddeland I, Kabat P, et al. Impact of reservoirs on river discharge and irrigation water supply during the 20th century[J]. Water Resources Research, 2011, 47, W03509.
    [61]
    Huang S, Krysanova V, Zai J, et al. Impact of Intensive Irrigation Activities on River Discharge under Agricultural Scenarios in the Semi-Arid Aksu River Basin, Northwest China[J]. Water Resources Management, 2015, 29(3): 945-959.
    [62]
    朱辉, 曾诚, 刘再华,等. 岩溶作用碳汇强度变化的土地利用调控规律:贵州普定岩溶水-碳通量大型模拟试验场研究[J]. 水文地质工程地质, 2015, 42(6): 120-125.
    [63]
    Semhi K, Amiotte-Suchet P, Clauer N et al. Impact of nitrogen fertilizers on the natural weathering-erosion processes and fluvial transport in the Garonne basin[J]. Applied Geochemistry, 2000, 15(6): 865-878.
    [64]
    Gandois L, Perrin A-S, Probst A. Impact of nitrogenous fertilizer-induced proton release on cultivated soils with contrasting carbonate contents: A column experiment[J]. Geochimica et Cosmochimica Acta, 2011, 75(5): 1185-1198.
    [65]
    Perrin A, Probst A, Probst J. Impact of nitrogenous fertilizers on carbonate dissolution in small agricultural catchments: Implications for weathering CO2 uptake at regional and global scales[J]. Geochimica et Cosmochimica Acta, 2008, 72(13): 3105-3123.
    [66]
    Li S L, Calmels D, Han G L. Sulfuric acid as an agent of carbonate weathering constrained by δ13CDIC: Examples from Southwest China[J]. Earth and Planetary Science Letters, 2008, 270(3-4): 189-199.
    [67]
    张兴波, 蒋勇军, 邱述兰,等. 农业活动对岩溶作用碳汇的影响:以重庆青木关地下河流域为例[J]. 地球科学进展, 2012, 27(4): 466-476.
    [68]
    Jiang Y. The contribution of human activities to dissolved inorganic carbon fluxes in a karst underground river system: Evidence from major elements and δ13CDIC in Nandong, Southwest China[J]. Journal of Contaminant Hydrology, 2013, 152: 1-11.
    [69]
    Jiang Y, Hu Y, Schirmer M. Biogeochemical controls on daily cycling of hydrochemistry and δ13C of dissolved inorganic carbon in a karst spring-fed pool[J]. Journal of Hydrology, 2013, 478: 157-168.
    [70]
    Raymond P A, Oh N H. Long term changes of chemical weathering products in rivers heavily impacted from acid mine drainage: Insights on the impact of coal mining on regional and global carbon and sulfur budgets[J]. Earth and Planetary Science Letters, 2009, 284(1-2): 50-56.
    [71]
    Barnes R T, Raymond P A. The contribution of agricultural and urban activities to inorganic carbon fluxes within temperate watersheds[J]. Chemical Geology, 2009, 266(3-4): 318-327.
    [72]
    Gammons C H, Babcock J N, Parker S R et al. Diel cycling and stable isotopes of dissolved oxygen, dissolved inorganic carbon, and nitrogenous species in a stream receiving treated municipal sewage[J]. Chemical Geology, 2011, 283(1-2): 44-55.
    [73]
    White B W. Rate processes: chemical kinetics and karst landform development. In: Lafleur, R E (Ed.), Groundwater as a Geomorphic Agent[M]. Binghampton Symp. In Geomorphology, 1984, vol. 13. Allen & Unwin, Boston, pp. 227-247.
    [74]
    Gombert P. Role of karstic dissolution in global carbon cycle[J]. Global and Planetary Change, 2002, 33(1-2): 177-184.
    [75]
    刘再华. 岩溶作用及其碳汇强度计算的”入渗-平衡化学法”—兼论水化学径流法和溶蚀试片法[J]. 中国岩溶, 2011, 30(4): 382-399.
    [76]
    Waterson E J, Canuel E A. Sources of sedimentary organic matter in the Mississippi River and adjacent Gulf of Mexico as revealed by lipid biomarker and δ13CTOC analyses[J]. Organic Geochemistry, 2008, 39(4): 422-439.
    [77]
    陶贞, 高全洲, 姚冠荣,等. 增江流域河流颗粒有机碳的来源、含量变化及输出通量[J]. 环境科学学报, 2004, 24(5): 789-795.
    [78]
    Tao F, Liu C, Li S. Sources and POC in two subtropical karstic tributaries with contrasting land use practice in the Yangtze River Basin[J]. Applied Geochemistry, 2009, 24(11): 2102-2112.
    [79]
    Worrall F, Burt T. Predicting the future DOC flux from upland peat catchments[J]. Journal of Hydrology, 2005, 300(1-4): 126–139.
    [80]
    Monteith D T, Stoddard J L, Evans C D, et al. Dissolved organic carbon trends resulting from changes in atmospheric deposition chemistry[J]. Nature, 2007, 450(7169): 537-541.
    [81]
    Iglesias-Rodriguez M D, Halloran P R, Rickaby R E, et al. Phytoplankton calcification in a high CO2 world[J]. Science, 2008, 320(5874): 336-340.
    [82]
    Liu Y, Liu Z, Zhang J, et al. Experimental study on the utilization of DIC by Oocystis solitaria Wittr and its influence on the precipitation of calcium carbonate in karst and non-karst waters[J]. Carbonates and Evaporites, 2010, 25(1): 21-26.
    [83]
    Perry M J. Phosphate utilization by an oceanic diatom in phosphorus-limited chemostat culture and in the oligotrophic waters of the central North Pacific[J]. Limnology and Oceanography, 1976, 21: 88-107.
    [84]
    Caperon J, Meyer J. Nitrogen-limited growth of marine phytoplankton-II uptake kinetics and their role in nutrient limited growth of phytoplankton[J]. Deep Sea Research, 1972, 19: 619-632.
    [85]
    Martin J H, Gordon R M, Fitzwater S E. Iron in Antarctic waters[J]. Nature, 1990, 345(6271): 156-158.
    [86]
    Roberts B, Mulholland P, Hill W. Multiple scales of temporal variability in ecosystem metabolism rates: Results from 2 years of continuous monitoring in a forested headwater stream[J]. Ecosystems, 2007, 10(4): 588-606.
    [87]
    Sakamaki T, Richardson J S. Biogeochemical properties of fine particulate organic matter as an indicator of local and catchment impacts on forested streams[J]. Journal of Applied Ecology, 2011, 48(6):1462-1471.
    [88]
    Hagen E M, McTammany M E, Webster J R, et al. Shifts in allochthonous input and autochthonous production in streams along an agricultural land-use gradient[J]. Hydrobiologia, 2010, 655(1):61-77.
    [89]
    Giling D P, Grace M R, Thomson J R, et al. Effect of native vegetation loss on stream ecosystem processes: dissolved organic matter composition and export in agricultural landscapes[J]. Ecosystems, 2013, 17(1): 82-95.
    [90]
    Williams C J, Yamashita Y, Wilson H F, et al. Unraveling the role of land use and microbial activity in shaping dissolved organic matter characteristics in stream ecosystems[J]. Limnology and Oceanography, 2010, 55(3): 1159-71.
    [91]
    Yang L, Hong H, Guo W, et al. Effects of changing land use on dissolved organic matter in a subtropical river watershed, southeast China[J]. Regional Environmental Change, 2012, 12(1): 145-151.
    [92]
    Ramankutty N, Foley J A, Foley J A. Estimating historical changes in global land cover: croplands from 1700 to 1992[J]. Global Biogeochemical Cycles, 1999, 13(4): 997-1027.
    [93]
    Klein G K, Ramankutty N. Land cover change over the last three centuries due to human activities: the availability of new global data sets[J]. Geojournal, 2004, 61(4): 335-344.
    [94]
    Williams P W. An initial estimate of the speed of limestone solution in County Clare[J]. Irish Geography, 1983, 4 (6): 432-444.
    [95]
    Probst J L, Mortatti J, Tardy Y. Carbon river fluxes and weathering CO2 consumption in the Congo and Amazon river basins[J]. Applied Geochemistry, 1994, 9(1): 1-13.
    [96]
    Blum J D, Gazis C A, Jacobson A D. Carbonate versus silicate weathering in the Raikhot watershed within the High Himalayan Crystalline Series[J]. Geology, 1998, 26(5): 411-414.
    [97]
    Jacobson A D, Blum J D. Ca/Sr and Sr-87/Sr-86 geochemistry of disseminated calcite in Himalayan silicate rocks from Nanga Parbat: Influence on river-water chemistry[J]. Geology, 2000, 28(5): 463-466.
    [98]
    Liu X, Zhang Y, Han W, et al. Enhanced nitrogen deposition over China[J]. Nature, 2013, 494(7438): 459-463.
    [99]
    Dentener F, Drevet J, Lamarque F J, et al. Nitrogen and sulfur deposition on regional and global scales: A multimodel evaluation[J]. Global Biogeochemical Cycles, 2006, 20, GB4003, doi: 10.1029/2005GB002672.
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