Effects of land use change on carbon storage in terrestrial ecosystem

Abstract

Abstract: Terrestrial ecosystem is an important carbon pool, which plays a crucial role in carbon biogeochemical cycle. Human activities such as fossil fuel combustion and land use change have resulted in carbon fluxes from terrestrial ecosystem to the atmosphere, which increased the atmospheric CO₂ concentration, and reinforced the greenhouse effect. Land use change affects the structure and function of the terrestrial ecosystem, which causes its change of carbon storage. To a great extent, the change of carbon storage lies in the type of ecosystem and the change of land use patterns. The conversion of forest to agricultural land and pasture causes a large reduction of carbon storage in vegetation and soil, and the decrease of soil carbon concentration is mainly caused by the reduction of detritus, the acceleration of soil organic matter decomposition, and the destroy of physical protection to organic matter due to agricultural practices. The loss of soil organic matter appears at the early stage after deforestation, and the loss rate is influenced by many factors and soil physical, chemical and biological processes. The conversion of agricultural land and pasture to forest and many conservative agricultural practices can sequester atmospheric carbon in vegetation and soil. Vegetation can sequester large amounts of carbon from atmosphere, while carbon accumulation in soil varies greatly because of farming history and soil spatial heterogeneity.Conservative agricultural practices such as no tillage, reasonable cropping system,and fertilization can influence soil physical and chemical characters, plant growth, quality and quantity of stubble,and soil microbial biomass and its activity,and hence, maintain and increase soil carbon concentration.

CLC Number:

Q948

YANG Jingcheng, HAN Xingguo, HUANG Jianhui, PAN Qingmin . Effects of land use change on carbon storage in terrestrial ecosystem[J]. Chinese Journal of Applied Ecology, 2003, (8): 1385-1390.

References

[1] Angers DA, Giroux M. 1996. Recently deposited organic matter in soil water-stable aggregates. Soil Sci Soc Am J, 60:1547～1551
[2] Balesdent J, Chenu C, Balabane M. 2000. Relationship of soil organic matter dynamics to physical protection and tillage. Soil Res, 53: 215～230
[3] Beare MH, Cabrera ML, Hendrix PF, et al. 1994. Aggregate-protected and unprotected organic matter pools in conventional-tillage and no-tillage soils. Soil Sci Soc Am J, 58:787～795
[4] Campbell CA, McConkey BG, Zentner RP, et al. 1996. Long-term effects of tillage and rotations on soil organic C and total N in a clay soil in southwestern Saskatchewan. Can J Soil Sci, 76: 395～401
[5] Campbell CA, Zentner RP, Liang BC, et al. 2000. Organic C accumulation in soil over 30 years in semiarid southwestern Saskatchewan-Effect of crop rotations and fertilizers. Can J Soil Sci, 80:179～192
[6] Campbell CA, Zentner RP, Selles F, et al. 1992. Comparative effects of grain lentil-wheat and monoculture wheat on crop production: N economy and N fertility in a brown Chernozem. Can J Plant Sci, 72:1091～1107
[7] Cunningham W. 1963. The effect of clearing on a tropical forest soil. J Soil Sci, 14: 334～345
[8] Davidson EA, Ackerman AL. 1993. Changes in soil carbon inventories following cultivation of previously untilled soils. Biogeochemistry, 20:161～164
[9] Delcourt HR, Harris WF. 1980. Carbon budget of the southeastern U.S. Biota: Analysis of historical change in trend from source to sink. Science, 210:321～323
[10] Detwiler RP, Hall CA 1988. Tropical forest and the global cycles. Science, 239:42～47
[11] Detwiler RP, Hall CA. 1988. The global carbon cycle. Science, 241:1738～1739
[12] Detwiler RP. 1986. Land use change and the global carbon cycle:The role of tropical soils. Biogeochemistry, 2: 67～93
[13] Dixon RK, Brown S, Houghon RA, et al. 1994. Carbon pools and flux of global forest ecosystems. Science, 263: 185～190
[14] Donigian AS, Patwardhan AS, Jackson RB, et al. 1995. Modeling the impacts of agricultural management practices on soil carbon in the central U. S. Advances in Soil Sciences: Soil Management and Greenhouse Effect. Boca Raton, Florida:CRC Press. 121～135
[15] FAO. 1997. State of the World' s Forests. Forest and Agriculture Organization of the United Nations Rome, Italy.
[16] Franzluebbers AJ, Hons FM, Zuberer DA. 1994. Long-term changes in soil carbon and nitrogen pools in wheat management systems. Soil Sci Soc Am J, 58:1639～1645
[17] Gao Y-C(高云超),Zhu W-S(朱文珊),Chen W-X(陈文新). 1994. The relationship between soil microbial biomass and the transformation of plant nutrients in straw mulched no-tillage soils.Sci Agric Sin(中国农业科学),27(6):41～49(in Chinese)
[18] Gaston G, Brown S, Lorenzini M, et al. 1998. State and change in carbon pools in the forests of tropical Africa. Global Change Biol, 4:97～114
[19] Gestel V, Ladd JN, Amato M. 1991. Carbon and nitrogen mineralization from two soils of contrasting texture and microaggregate stability: Influence of sequential fumigation, drying and storage. Soil Biol Biochem, 23: 313～322
[20] Havlin JL, Kissel DE, Claassen LD, et al. 1990. Crop rotation and tillage effects on soil organic carbon and nitrogen. Soil Sci Soc Am J, 54: 448～452
[21] Houghton RA, Hackler JL. 1999. Emissions of carbon from forestry and land- use change in tropical Asia. Global Change Biol, 5: 481～492
[22] Houghton RA, Hobbie JE, Melillo JM, et al. 1983. Changes in the carbon content of terrestrial biota and soils between 1860 and 1980: A net release of CO₂ to the atmosphere. Ecol Monog, 53: 235～262
[23] Houghton RA. 1995. Changes in the storage of terrestrial carbon since 1850. In: Soil and Global Change. Boca Raton, Florida: CRC Press. 45～65
[24] Janzen HH, Campbell CA, Ellert BH, et al. 1998. Management ef fects on soil C storage in the Canadian prairies. Soil Tillage Res, 47: 181～195
[25] Jastrow JD. 1996. Soil aggregate formation and the accrual of particulate and mineral associated organic matter. Soil Biol Biochem, 28: 656～676
[26] Jener LM, Carlos CC, Jerry MM, et al. 1995. Soil carbon stocks of the Brazilian Amazon Basin. Soil Sci Soc Am J, 59: 244～247
[27] Jin F-S(晋凡生),Zhang B-L(张宝林).The effects of no-tillage with maize stalk mulched on soil environment in dryland. Eco-agric Res(生态农业研究),8(3):47～50(in Chinese)
[28] Johnson DW. 1992. Effects of forest management on soil carbon storage. Water Air Soil Poll, 64: 83～120
[29] Lal R. 1999. Soil management and restoration for C sequestration to mitigate the accelerated greenhouse effect. Prog Environ Sci, 1: 307～326
[30] Liu G-H(刘国华),Fu B-J(傅伯杰),Fang J-Y(方精云).2000. Carbon dynamics of chinese forests and its contribution to globalcarbon balance.Acta Ecol Sin(生态学报),20(5):733～739
[31] Lugo AE, Sanchez AJ, Brown S. 1986. Land use and organic carbon content of some subtropical soils. Plant Soil, 96:185～196
[32] Lupwayi NZ, Rice WA, Clayton GW. 1999. Soil microbial biomass and carbon dioxide flux under wheat as influenced by tillage and crop rotation. Can J Soil Sci, 79:273～280
[33] Nohrstedt HA, Arnebrant K, Baath E, et al. 1989. Changes in carbon content, respiration rate, ATP content, and microbial biomass in nitrogen-fertilized pine forest soils in Sweden. Can J For Res, 19: 323～328
[34] Nyborg M, Malhi SS, Solberg ED, et al. 1999. Carbon storage and light fraction C in a grassland Dark Gray Chernozem soil as influenced by N and S fertilization. Can J Soil Sci, 79: 317～320
[35] Olk DC, Cassman KG, Randall EW, et al. 1996. Changes in chemical properties of organic matter with intensified rice cropping in tropical lowland soil. Eur J Soil Sci, 47: 293～303
[36] Paustian K, Andren O, Janzen H, et al. 1997. Agricultural soil as a C sink to offset CO₂ emission. Soil Use Man, 13:230～244
[37] Post WM, Kwon KC. 2000. Soil carbon sequestration and land-use change: Processes and potential. Global Change Biol, 6: 317～327
[38] Post WM, Peng TH, Emanuel WR, et al. 1990. The global carbon cycle. Am Sci, 78: 310～326
[39] Potter CS, Randerson JT, Field CB, et al. 1993. Terrestrial ecosystem production: A process model based on global satellite and surface data. Global Biogeochem Cyc, 7: 811～841
[40] Richter DD, Markerwit D, Trumbore SE, et al. 1999. Rapid accumulation and turnover of soil carbon in a re-establishing forest. Nature, 400: 56～58
[41] Rivera LW, Zimmerman JK, Aide TM. 2000. Forest recovery in abandoned agricultural lands in karst region of the Dominican Republic. Plant Ecol, 148:115～125
[42] Schiffman PM, Johnson WC. 1990. Phytomass and detrital storage during forest regrowth in the southeastern United States Piedmont. Can J For Res, 19:69～78
[43] Schlesinger WH. 1990. Evidence from chronosequence studies for a low carbon-storage potential of soils. Nature, 348: 232～234
[44] Six J, Elliott ET, Paustian K, et al. 1998. Aggregation and soil organic matter accumulation in cultivated and native grassland soils. Soil Sci Soc Am J, 12:1367～1377
[45] Six J, Paustian K, Elliott ET, et al. 2000. Soil structure and organic matter Ⅰ . Distribution of aggregate-size classes and aggregate-asso-ciated carbon. Soil Sci Soc Am J, 64: 681～689
[46] Skole DL, Chomentowski WH, Salas WA, et al. 1994. Physical and human dimensions of deforestation in Amazonia. Bioscience, 44: 314～322
[47] Smith P, Powlson DS, Glendining MJ, et al. 1998. Preliminary estimates of the potential for carbon mitigation in European soils through no-till farming. Global Change Biol, 4: 679～685
[48] Tisdall JM, Oades JM. 1982. Organic matter and water-stable aggregates in soils. J Soil Sci, 33:141～163
[49] Turner J, Lambert MJ. 1986. Fate of applied nutrients on a longterm superphosphate trial in Pinus radiata. Plant Soil, 93: 373～382
[50] Wilde SA. 1964. Change in soil productivity induced by pine plantations. Soil Sci, 97: 276～278
[51] Witt C, Cassman KG, Olk DC, et al. 2000. Crop rotation and residue management effects on carbon sequestration, nitrogen cycling and productivity of irrigated rice systems. Plant Soil, 225: 263～278
[52] Zhao L-P(赵兰坡),Ma J(马晶),Yang X-M(杨学明),et al. 1997. Composition and types of humus in different particle fractions of arable albic soil.Acta Soil Sin(土壤学报),27(30):28～41(in Chinese)