[1] 李克让, 王绍强, 曹明奎. 中国植被和土壤碳贮量. 中国科学, 2003, 33(1): 72-80.
LI K R, WANG S Q, CAO M K. Carbon storage of vegetation and soil in China. Science in China, 2003, 33(1):72-80. (in Chinese)
[2] YANG Y, FANG J, TANG Y, JI C, ZHENG C, HE J, ZHU B. Storage, patterns and controls of soil organic carbon in the Tibetan grasslands. Global Change Biology, 2008, 14(7):1592-1599.
[3] 李娜, 王根绪, 高永恒, 籍长志. 青藏高原生态系统土壤有机碳研究进展. 土壤, 2009, 41(4): 512-519.
LI N, WANG G X, GAO Y H, JI C Z. On soil organic carbon of alpine ecosystem in Qinghai-Tibet Plateau. Soils, 2009, 41(4): 512-519. (in Chinese)
[4] GUO LB, GIFFORD R M. Soil carbon stocks and land use change: A meta analysis. Global Change Biology, 2002, 8(4): 345-360.
[5] MARTENS D A, REEDY T E, LEWIS D T. Soil organic carbon content and composition of 130-year crop, pasture and forest land-use managements. Global Change Biology, 2003, 10(1):65-78.
[6] YONEYAMA T, DACANAY E V, CASTELO O, KASAJIMA I, PARK T H. Estimation of soil organic carbon turnover using natural 13C abundance in Asian tropics: a case study in the Philippines. Soil Science and Plant Nutrition, 2004, 50(4): 599-602.
[7] BEHESHTI A, RAIESI F, GOLCHIN A. Soil properties, C fractions and their dynamics in land use conversion from native forests to croplands in northern Iran. Agriculture, Ecosystems and Environment, 2012, 148(2): 121-133.
[8] DING F, HU Y L, LI L J, LI A, SHI S, LIAN P Y, ZENG D H. Changes in soil organic carbon and total nitrogen stocks after conversion of meadow to cropland in Northeast China. Plant and Soil, 2013, 373(1/2): 659-672.
[9] SINGH A K, RAI A, SINGH N. Effect of long term land use systems on fractions of glomalin and soil organic carbon in the Indo-Gangetic plain. Geoderma, 2016, 277: 41-50.
[10] ROLANDO J L, DUBEUX JR J C, PEREZ W, RAMIREZ D A, TURIN C, RUIZ-MORENO M, COMERFORD N B, MARES V, GARCIA S, QUIROZ R. Soil organic carbon stocks and fractionation under different land uses in the Peruvian high-Andean Puna. Geoderma, 2017, 307: 65-72.
[11] 关卫星, 焦国成, 刘启勇, 高小丽. 西藏一江两河地区农业耕作制度的现状与改革对策. 西藏农业科技, 2012, 34(4): 44-48.
GUAN W, JIAO G, LIU Q, GAO X. Present situation and reform countermeasure on agricultural tillage system in the “YLN” region of Tibet. Tibet Journal of Agricultural Sciences, 2012, 34(4): 44-48. (in Chinese)
[12] PAUL E A. The nature and dynamics of soil organic matter: Plant inputs, microbial transformations, and organic matter stabilization. Soil Biology and Biochemistry, 2016, 98: 109-126.
[13] CELIK I. Land-use effects on organic matter and physical properties of soil in a southern Mediterranean highland of Turkey. Soil and Tillage Research, 2005, 83(2):270-277.
[14] WILSON B R, KOEN T B, BARNES P, GHOSH S, KING D. Soil carbon and related soil properties along a soil type and land-use intensity gradient, New South Wales, Australia. Soil Use and Management, 2011, 27(4): 437-447.
[15] BISSETT A, RICHARDSON A E, BAKER G, THRALL P H. Long-term land use effects on soil microbial community structure and function. Applied Soil Ecology, 2011, 51: 66-78.
[16] RODRIGUES J L M, PELLIZAZI V H, MUELLER R, BAEK K, JESUS E D, PAULA F S, MIRZA B, HAMAOUI G S, TSAI S M, FEIGL B, TIEDJE J M, BOHANNAN B J M, NUSSLEIN K. Conversion of the Amazon rainforest to agriculture results in biotic homogenization of soil bacterial communities. Proceedings of the National Academy of Science of the United States of America, 2013, 110(3): 988-993.
[17] GRÜZWEIG J M, SPARROW S D, CHAPIN III F S. Impact of forest conversion to agriculture on carbon and nitrogen mineralization in subarctic Alaska. Biogeochemistry, 2003, 64(2): 271-296.
[18] HAFNER S, UNTEREGELSBACHER S, SEEBER E, LENA B, XU X L, LI X G, GUGGENBERGER G, MIEHE G, KUZYAKOV Y. Effect of grazing on carbon stocks and assimilate partitioning in a Tibetan montane pasture revealed by 13CO2 pulse labeling. Global Change Biology, 2012, 18(2): 528-538.
[19] CHANG X F, ZHU X X, WANG S P, CUI S J, LUO C Y, ZHANG Z H, WILKES A. Impacts of management practices on soil organic carbon in degraded alpine meadows on the Tibetan Plateau. Biogeosciences, 2014, 11(13): 3495-3503.
[20] VON LÜTZOW M, KÖGEL-KNABNER I, EKSCHMITT K, FLESSA H, GUGGENBERGER G, MATZNER E, MARSCHNER B. SOM fractionation methods: relevance to functional pools and to stabilization mechanisms. Soil Biology and Biochemistry, 2007, 39(9): 2183-2207.
[21] SIX J, CONANT R T, PAUL E A, PAUSTIAN K. Stabilization mechanisms of soil organic matter: Implications for C-saturation of soils. Plant and Soil, 2002, 241(2): 155-176.
[22] SOLOMON D, LEHMANN J, KINYANGI J, AMELUNG W, LOBE I, PELL A, RIHA S, NGOZE S, VERCHOT L, MBUGUA D, SKJEMSTAD J, SCHAFER T. Long-term impacts of anthropogenic perturbations on dynamics and speciation of organic carbon in tropical forest and subtropical grassland ecosystems. Global Change Biology, 2007, 13(2): 511-530.
[23] SIX J, PAUSTIAN K. Aggregate-associated soil organic matter as an ecosystem property and a measurement tool. Soil Biology and Biochemistry, 2014, 68(1): A4-A9.
[24] DEL GALDO I, SIX J, PERESSOTTI A, COTRUFO M F. Assessing the impact of land-use change on soil C sequestration in agricultural soils by means of organic matter fractionation and stable C isotopes. Global Change Biology, 2003, 9(8): 1204-1213.
[25] GUILLAUME T, MUHAMMAD D, KUZYAKOV Y. Losses of soil carbon by converting tropical forest to plantations: erosion and decomposition estimated by δ13C. Global Change Biology, 2015, 21(9): 3548-3560.
[26] WERTH M, KUZYAKOV Y. 13C fractionation in transformations at the interface between roots, microorganisms, and soil: a review and synthesis. Soil Biology and Biochemistry, 2010, 42(9): 1372-1384.
[27] QIAO N, XU X L, CAO G M, OUYANG H, KUZYAKOV Y. Land use change decreases soil carbon stocks in Tibetan grasslands. Plant and Soil, 2015, 395(1-2):231-241.
[28] STEWART C E, PAUSTIAN K, CONANT R T, PLANTE A F, SIX J. Soil C saturation: implications for measurable C pool dynamics in long-term incubations. Soil Biology and Biochemistry, 2009, 41(2): 357-366.
[29] WEI X, SHAO M, GALE W J, ZHANG X, LI L. Dynamics of aggregate-associated organic carbon following conversion of forest to cropland. Soil Biology and Biochemistry, 2013, 57(3): 876-883.
[30] DAVIDSON E A, JANSSENS I A. Temperature sensitivity of soil carbon decomposition and feedbacks to climate change. Nature, 2006, 440(7081): 165-173.
[31] ZHANG K, DANG H, ZANG Q, CHENG X. Soil carbon dynamics following land-use change varied with temperature and precipitation gradients: evidence from stable isotopes. Global Change Biology, 2015, 21(7): 2762-2772.
[32] SCHWEIZER S A, FISCHER H, HÄRING V, STAHR K. Soil structure breakdown following land use change from forest to maize in Northwest Vietnam. Soil and Tillage Research, 2017, 166: 10-17.
[33] ROVIRA P, VALLEJO V R. Labile, recalcitrant, and inert organic matter in Mediterranean forest soils. Soil Biology and Biochemistry, 2007, 39(1): 202-215.
[34] SOLOMON D, LEHMANN J, ZECH W. Land use effects on soil organic matter properties of chromic Luvisols in semi-arid northern Tanzania: carbon, nitrogen, lignin and carbohydrates. Agriculture, Ecosystems and Environment, 2000, 78(3): 203-213.
[35] PLAZA C, COURTIER-MURIAS D, FERNÁNDEZ J M, POLO A, SIMPSON A J. Physical, chemical, and biochemical mechanisms of soil organic matter stabilization under conservation tillage systems: a central role for microbes and microbial by-products in C sequestration. Soil Biology and Biochemistry, 2013 57(2): 124-134.
[36] GUNINA A, KUZYAKOV Y. Pathways of litter C by formation of aggregates and SOM density fractions: Implications from 13C natural abundance. Soil Biology and Biochemistry, 2014, 71(6): 95-104.
[37] SIX J, ELLIOTT E T, PAUSTIAN K. Soil macroaggregate turnover and microaggregate formation: a mechanism for C sequestration under no-tillage agriculture. Soil Biology and Biochemistry, 2000, 32(14): 2099-2103.
[38] SIX J, BOSSUYT H, DEGRYZE S, DENEF K. A history of research on the link between (micro)aggregates, soil biota, and soil organic matter dynamics. Soil and Tillage Research, 2004, 79(1): 7-31.
[39] KALHORO S A, XU X, CHEN W, HUA R, RAZA S, DING K.
Effects of different land-use systems on soil aggregates: a case study of the Loess Plateau (Northern China). Sustainability, 2017, 9(8): 1349.
[40] GARCIA-FRANCO N, ALBALADEJO J, ALMAGRO M, MARTINEZ-MENA M. Beneficial effects of reduced tillage and green manure on soil aggregation and stabilization of organic carbon in a Mediterranean agroecosystem. Soil and Tillage Research, 2015, 153: 66-75.
[41] TORN M S, KLEBER M, ZAVALETA E S, ZHU B, FIELD C B, TRUMBORE S E. A dual isotope approach to isolate carbon pools of different turnover times. Biogeosciences, 2013, 10(12): 8067-8081.
[42] 蔡岸冬, 徐香茹, 张旭博, 徐明岗, 张文菊. 不同利用方式下土壤矿物结合态有机碳特征与容量分析. 中国农业科学, 2014, 47(21): 4291-4299.
CAI A D, XU X R, ZHANG X B, XU M G, ZHANG W J. Capacity and characteristics of mineral associated soil organic carbon under various land uses. Scientia Agricultura Sinica, 2014, 47(21): 4291-4299. (in Chinese)
[43] BAYER C, MIELNICZUK J, GIASSON E, MARTIN-NETO L, PAVINATO A. Tillage effects on particulate and mineral‐associated organic matter in two tropical Brazilian soils. Communications in Soil Science and Plant Analysis, 2006, 37(3/4): 389-400.
[44] DENEF K, SIX J, MERCKX R, PAUSTIAN K. Carbon sequestration in microaggregates of no-tillage soils with different clay mineralogy. Soil Science Society of America Journal, 2004, 68(6): 1935-1944.
[45] VIRTO I, BARRÉ P, CHENU C. Microaggregation and organic matter storage at the silt-size scale. Geoderma, 2008, 146(1/2): 326-335.
[46] PAUL E A, COLLINS H P, LEAVITT S W. Dynamics of resistant soil carbon of Midwestern agricultural soils measured by naturally occurring 14C abundance. Geoderma, 2001, 104(3/4): 239-256.
[47] HOBBIE E A, WERNER R A. Intramolecular, compound-specific, and bulk carbon isotope patterns in C-3 and C-4 plants: a review and synthesis. New Phytologist, 2004, 161(2): 371-385.
[48] XU M, LI X, CAI X, GAI J, LI X, CHRISTIE P, ZHANG J. Soil microbial community structure and activity along a montane elevational gradient on the Tibetan Plateau. European Journal of Soil Biology, 2014, 64(6): 6-14.
[49] DUNGAIT J A J, HOPKINS D W, GREGORY A S, WHITMORE A P. Soil organic matter turnover is governed by accessibility not recalcitrance. Global Change Biology, 2012, 18(6): 1781-1796. |