Berner, R. A. and Morse, J. W.
: Dissolution kinetics of calcium carbonate in sea water; IV, Theory of calcite dissolution, Am. J. Sci., 274, 108–134, 1974.
Bertrand, I., Delfosse, O., and Mary, B.
: Carbon and nitrogen mineralization in acidic, limed and calcareous agricultural soils: apparent and actual effects, Soil Biol. Biochem., 39, 276–288, 2007.
Biasi, C., Lind, S. E., Pekkarinen, N. M., Huttunen, J. T. Shurpali, N. J., Hyvönen, N. P., Repo, M. E., and Martikainen, P. J.
: Direct experimental evidence for the contribution of lime to CO2
release from managed peat soil, Soil Biol. Biochem., 40, 2660–2669, 2008.
Burton, E. A. and Walter, L. M.
: The role of pH in phosphate inhibition of calcite and aragonite precipitation rates in seawater, Geochim. Cosmochim. Ac., 54, 797–808, 1990.
Chien, S. H., Prochnow, L. I., Tu, S., and Snyder, C. S.
: Agronomic and environmental aspects of phosphate fertilizers varying in source and solubility: an update review, Nutr. Cycl. Agroecosys., 89, 229–255, 2011.
: Reply to the comment by Y. Zhang and CA Grattoni on:“precipitation kinetics of calcite in the system CaCO3
: the conversion to CO2
by the slow process H+
O as a rate limiting step” by W. Dreybrodt, L. Eisenlohr, B. Madry, and S. Ringer, Geochim. Cosmochim. Ac., 62, 3791–3792, 1998.
Dreybrodt, W., Lauckner, J., Zaihua, L., Svensson, U., and Buhmann, D.
: The kinetics of the reaction CO2
as one of the rate limiting steps for the dissolution of calcite in the system H2
, Geochim. Cosmochim. Ac., 60, 3375–3381, 1996.
Egli, M. and Fitze, P.
: Quantitative aspects of carbonate leaching of soils with differing ages and climates, Catena, 46, 35–62, 2001.
Errin, A. S. P., Robst, A. P., and Robst, J. L. P.
: Impact of nitrogen fertilizers on natural weathering processes: evident role on CO2
consumption the oxygen isotopic composition of Precambrian cherts, Goldschmidt Conference, Melbourne, AUSTRALIA (27 August–1 September 2006), 2332–2332, 2006.
Etchanchu, D. and Probst, J.
: Evolution of the chemical composition of the Garonne River water during the period 1971–1984, Hydrolog. Sci. J., 33, 243–256, 1988.
: Fertilizer requirements in 2015 and 2030, Rome, FAO, 2000.
: Comparative research of limestone solution by means of standard tablets, Proceedings of the 8th International Congress of Speleology Bowling Green, Kentucky, 18 to 24 July 1981, 1981 273–275, 1981.
: International comparative measurements of surface solution by means of standard limestone tablets, Razpr IV Razeda Sazu, 26, 361–386, 1985.
Gandois, L., Perrin, A. S., and Probst, A.
: Impact of nitrogenous fertiliser-induced proton release on cultivated soils with contrasting carbonate contents: a column experiment, Geochim. Cosmochim. Ac., 75, 1185–1198, 2011.
: 2014 Guizhou Statistical Yearbook, Statistical Press of China, Beijing, 2014.
Hagedorn, B. and Cartwright, I.
: Climatic and lithologic controls on the temporal and spatial variability of CO2
consumption via chemical weathering: an example from the Australian Victorian Alps, Chem. Geol., 260, 234–253, 2009.
Hamilton, S. K., Kurzman, A. L., Arango, C., Jin, L., and Robertson, G. P.
: Evidence for carbon sequestration by agricultural liming, Global Biogeochem. Cy., 21, 1–12, 2007.
Han, Z. and Jin, Z.
: Hydrogeology of Guizhou Province, China, Seismic Publication, Beijing, 1996.
House, W. A.
: Inhibition of calcite crystal growth by inorganic phosphate, J. Colloid Interf. Sci., 119, 505–511, 1987.
Hunter, A. H.
: Soil Fertility analytical services in Bangladesh, BARC∕IDAS Cosultancy Report Contract Aid/388-0005, Dhaka, Bangladesh Agricultural Research Council, 581–601, 1984.
: The contribution of human activities to dissolved inorganic carbon fluxes in a karst underground river system: evidence from major elements and δ13
in Nandong, Southwest China, J. Contam. Hydrol., 152, 1–11, 2013.
Jiang, Y., Wu, Y., Groves, C., Yuan, D., and Kambesis, P.
: Natural and anthropogenic factors affecting the groundwater quality in the Nandong karst underground river system in Yunan, China, J. Contam. Hydrol., 109, 49–61, 2009.
Jiang, Z. and Yuan, D.
source-sink in karst processes in karst areas of China, Episodes, 22, 33–35, 1999.
Kiefer, R. H.
: Temporal cycles of karst denudation in northwest Georgia, USA, Earth Surf. Proc. Land., 19, 213–232, 1994.
Kump, L. R., Brantley, S. L., and Arthur, M. A.
: Chemical weathering, atmospheric CO2
, and climate, Annu. Rev. Earth Pl. Sc., 28, 611–667, 2000.
: Geochemistry of surface and ground water in Guiyang, China: water/rock interaction and pollution in a karst hydrological system, Appl. Geochem., 21, 887–903, 2006.
Lerman, A. and Wu, L.
and sulfuric acid controls of weathering and river water composition, J. Geochem. Explor., 88, 427–430, 2006.
Lerman, A., Wu, L., and Mackenzie, F. T.
consumption in weathering and material transport to the ocean, and their role in the global carbon balance, Mar. Chem., 106, 326–350, 2007.
Li, S., Calmels, D., Han, G., Gaillardet, J., and Liu, C.
: Sulfuric acid as an agent of carbonate weathering constrained by δ13
: examples from Southwest China, Earth Planet. Sc. Lett., 270, 189–199, 2008.
Li, S., Xu, Z., Wang, H., Wang, J., and Zhang, Q.
: Geochemistry of the upper Han River basin, China: 3: Anthropogenic inputs and chemical weathering to the dissolved load, Chem. Geol., 264, 89–95, 2009.
Li, S., Liu, C.-Q., Patra, S., Wang, F., Wang, B., and Yue, F.
: Using a dual isotopic approach to trace sources and mixing of sulphate in Changjiang Estuary, China, Appl. Geochem., 26, S210–S213, 2011.
Lian, B., Chen, Y., Zhu, L., and Yang, R.
: Effect of Microbial Weathering on Carbonate Rocks, Earth Science Frontiers, 15, 90–99, 2008.
Lin, Y. P. and Singer, P. C.
: Inhibition of calcite precipitation by orthophosphate: speciation and thermodynamic considerations, Geochim. Cosmochim. Ac., 70, 2530–2539, 2006.
Liu, C., Li, S., Lang, Y., and Xiao, H.
: Using δ15
N- and δ18
O-Values To Identify Nitrate Sources in Karst Ground Water, Guiyang, Southwest China, Environ. Sci. Technol., 40, 6928–6933, 2006.
Liu, Z. and Dreybrod, W.
: Dissolution kinetics of calcium carbonate minerals in H2
solutions in turbulent flow: the role of the diffusion boundary layer and the slow reaction H2
O + CO2
, Geochim. Cosmochim. Ac., 61, 2879–2889, 1997.
Liu, Z., Dreybrodt, W., and 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, Earth-Sci. Rev., 99, 162–172, 2010.
: Growth kinetics and composition of magnesian calcite overgrowths precipitated from seawater: quantitative influence of orthophosphate ions, Geochim. Cosmochim. Ac., 50, 2255–2265, 1986.
: 2014 Statistical Yearbook, Statistical Press of China, Beijing, 2014.
Oh, N. and Raymond, P. A.
: Contribution of agricultural liming to riverine bicarbonate export and CO2
sequestration in the Ohio River basin, Global Biogeochem. Cy., 20, 1–17, 2006.
Perrin, A., Probst, A., and Probst, J.
: Impact of nitrogenous fertilizers on carbonate dissolution in small agricultural catchments: implications for weathering CO2
uptake at regional and global scales, Geochim. Cosmochim. Ac., 72, 3105–3123, 2008.
Pierson-Wickmann, A., Aquilina, L., Martin, C., Ruiz, L., and Molénat, J.
: High chemical weathering rates in first-order granitic catchments induced by agricultural stress, Chem. Geol., 265, 369–380, 2009.
: Factors controlling carbonate dissolution rates quantified in a field test in the Austrian alps, Geomorphology, 68, 201–212, 2005.
Pokrovsky, O. S., Golubev, S. V., Schott, J., and Castillo, A.
: Calcite, dolomite and magnesite dissolution kinetics in aqueous solutions at acid to circumneutral pH, 25 to 150 °C and 1 to 55 atm p
: new constraints on CO2
sequesration in sedimentary basins, Chem. Geol., 265, 20–32, 2009.
: Dissolved and suspended matter transported by the Girou River (France): mechanical and chemical erosion rates in a calcareous molasse basin, Hydrolog. Sci. J., 31, 61–79, 1986.
: The influence of foreign ions on crystal growth from solution. 1. The stabilization of the supersaturation of calcium carbonate solutions by anions possessing OPOPO chains, Discuss. Faraday Soc., 5, 234–237, 1949.
Reddy, M. M.
: Crystallization of calcium carbonate in the presence of trace concentrations of phosphorus-containing anions: I. Inhibition by phosphate and glycerophosphate ions at pH 8.8 and 25 °C, J. Cryst. Growth, 41, 287–295, 1977.
Semhi, K. and Suchet, A.
: Impact of nitrogen fertilizers on the natural weathering-erosion processes and fluvial transport in the Garonne basin, Appl. Geochem., 15, 865–878, 2000.
Shin, W., Ryu, J., Mayer, B., Lee, K., and Lee, S.
: Natural and anthropogenic sources and processes affecting water chemistry in two South Korean streams, Sci. Total Environ., 485, 270–280, 2014.
Singh, J., Kunhikrishnan, A., Bolan, N. S., and Saggar, S.
: Impact of urease inhibitor on ammonia and nitrous oxide emissions from temperate pasture soil cores receiving urea fertilizer and cattle urine, Sci. Total Environ., 465, 56–63, 2013.
Song, C., Liu, C., Wang, J., Zhang, Y., and Hou, H.
: Impact of the addition of a compound fertilizer on the dissolution of carbonate rock tablets: a column experiment, Appl. Geochem., 26, 170–173, 2011.
Song, C., Liu, C., Zhang, Y., and Hou, H.
: Impact of animal manure addition on agricultural lime weathering in acidic soil: pH dependence and CO2
independence of agricultural lime weathering, Proced. Earth Plan. Sc., 10, 405–409, 2014.
Song, C., Liu, C., and Han, G.
: Impact of fertilization with irrigation on carbonate weathering in an agricultural soil in Northern China: a column experiment, Geochem. J., 51, 143–155, 2017a.
Song, C., Liu, C., Zhang, Y., and Hou, H.
: Impact of animal manure addition on the weathering of agricultural lime in acidic soils: the agent of carbonate weathering, Journal of Groundwater Science and Engineering, 2, 202–212, 2017b.
Trudgill, S. T.
: Measurement of erosional weight loss of rock tablets, British Geomorphological Research Group Technical Bulletin, 17, 13–20, 1975.
Wang, L., Ruiz-Agudo, E., Putnis, C. V., Menneken, M., and Putnis, A.
: Kinetics of calcium phosphate nucleation and growth on calcite: implications for predicting the fate of dissolved phosphate species in alkaline soils, Environ. Sci. Technol., 46, 834–842, 2012.
West, T. O. and McBride, A. C.
: The contribution of agricultural lime to carbon dioxide emissions in the United States: dissolution, transport, and net emissions, Agr. Ecosyst. Environ., 108, 145–154, 2005.
Yue, F. J., Li, S. L., Liu, C. Q., Lang, Y. C., and Ding, H.
: Sources and transport of nitrate constrained by the isotopic technique in a karst catchment: an example from Southwest China, Hydrol. Process., 29, 1883–1893, 2015.
Zeng, C., Zhao, M., Yang, R., and Liu, Z.
: Comparison of karst processes-related carbon sink intensity calculated by carbonate rock tablet test and solute load method: a case study in the Chenqi karst spring system, Hydrogology and Engineering Geology, 41, 106–111, 2014.
: Carbonate rock dissolution rates in different landuses and their carbon sink effect, Chinese Sci. Bull., 56, 3759–3765, 2011.