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Erschienen in:
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2021 | OriginalPaper | Buchkapitel

Effect of Anthropogenic Activities on the Rate of Soil CO2 Flux in the Dipterocarpus Forest Ecosystem of Northeast India

verfasst von : P. S. Yadava, Amrabati Thokchom

Erschienen in: Climate Change and Green Chemistry of CO2 Sequestration

Verlag: Springer Singapore

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Abstract

The aim of the present study is to study the effect of anthropogenic activities, i.e. burning and logging on the rate of soil CO2 flux and its relationship with the abiotic and the biotic factor in the Dipterocarpus forest of Northeast India. Rates of soil CO2 flux were found to be the highest in burnt and the lowest in logged forest site. Seasonally soil CO2 flux rate was found to be maximum in rainy season and minimum in winter season in all the study sites. Simple linear regression shows there is a strong positive relationship between soil CO2 flux and soil moisture, temperature, and soil organic carbon. Soil CO2 flux rate can be altered through different forest management practices such as harvesting, thinning, and burning to mitigate climate change.

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Vorheriges Kapitel CO2 Sequestration Through Phytoremediation Techniques with Special Emphasis on Urban Forestry to Mitigate Climate Change Impact
Nächstes Kapitel Estimation of Carbon Dioxide Fluxes Between Land, Ocean and Atmosphere During 2006–2011 with a 4D Variational Assimilation Scheme and Special Reference to Asia
Literatur
1.
Han G, Zhou G, Xu Z, Yang Y, Liu J, Shi K (2007) Biotic and abiotic factors controlling the spatial and temporal variation of soil CO2 flux in an agricultural ecosystem. Soil Bio Biochem 39:418–425CrossRef
2.
Zhou Z, Zhang Z, Zha T, Luo Z, Zheng J, Sun OJ (2013) Predicting soil CO2 flux using carbon stock in roots, litter and soil organic matter in forests of Loess Plateau in China. Soil Biol Biochem 57:135–143CrossRef
3.
Schlesinger WH, Andrews JA (2000) Soil CO2 flux and the global carbon cycle. Biogeochem 48:7–20CrossRef
4.
Raich JW, Schlesinger WH (1992) The global carbon dioxide flux in soil CO2 flux and its relationship to vegetation and climate. Tellus 44:81–89CrossRef
5.
Schimel DS, Braswell BH, Holland EA, McKeown R, Ojima DS, Painter TH, Parton WJ, Townsend AR (1994) Climatic, edaphic, and biotic controls over storage and turnover of carbon in soils. Glob Biog Cyc 8:279–293CrossRef
6.
Townsend AR, Vitousek PM, Holland EA (1992) Tropical soils could dominate the shortterm carbon cycle feedbacks to increased global temperatures. Climatic Change 22:293–303CrossRef
7.
Tufekcioglu A, Raich JW, Isenhart TM, Schultz RC (2001) Soil CO2 flux within riparian buffers and adjacent crop fields. Plant Soil 229:117–124CrossRef
8.
Devi NB, Yadava PS (2009) Emission of CO2 from the soil and immobilization of carbon in microbes in a sub-tropical mixed oak forest ecosystem, Manipur, N.E., India. Cur Sc 96:1630–1637
9.
Maier M, Schack-Kirchner H, Hildebrand EE, Schindler D (2011) Soil CO2 efflux vs. soil CO2 flux: implications for flux models. Agri For Meteor 151:1723–1730CrossRef
10.
Qi Y, Xu M (2001) Separating the effects of moisture and temperature on soil CO2 efflux in a coniferous forest in the Sierra Nevada mountains. Plant Soil 237:15–23CrossRef
11.
Yohannes Y, Shibistova O, Abate A, Fetine M, Guggenberger G (2011) Soil CO2 efflux in an Afromontane forest of Ethiopia as driven by seasonality and tree species. For Ecol Manag 261:1090–1098CrossRef
12.
Chen W, Jia X, Zha T, Wu B, Zhang Y, Li C, Wang X, He G, Yu H, Chen G (2013) Soil CO2 flux in a mixed urban forest in China in relation to soil temperature and water content. Eur J Soil Biol 54:63–68CrossRef
13.
Thokchom A, Yadava PS (2014) Soil CO2 flux in different ecosystem of North-East India. Curr Sci 107(1):99–105
14.
Wiseman PE, Seiler JR (2004) Soil CO2 flux across four age classes of plantation loblolly pine (Pinus taeda L.) on the Virginia Piedmont. For Ecol Manag 192:297–331CrossRef
15.
Anderson JM, Ingrame SI (1993) Tropical soil biology and fertility (TSBF), Methods handbook internation union of biological sciences, 77
16.
Singh JS, Gupta SR (1977) Plant decomposition and soil CO2 flux in terrestrial ecosystems. Bot Rev 43:449–528CrossRef
17.
Fritze H, Smolender A, Levula T, Kitunen V, Malkoner E (1994) Wood ash fertilization and fire treatments in a scots pine forest stand: effects on the organic layer, microbial biomass and microbial activity. Biol Fert Soils 17:57–63CrossRef
18.
Mac Donald LH, Huffman EL (2004) Post fire soil water repellency: persistance and soil moisture thresholds. Soil Sc Soc Amer J 68:1729–1734
19.
Zimmermann M, Meir P, Bird M, Malhi Y, Ccahuana A (2009) Litter contribution to diurnal and annual soil CO2 flux in tropical montane cloud forest. Soil Biol Biochem 41:1338–1340CrossRef
20.
Högberg P, Nordgren A, Buchmann N et al (2001) Large-scale forest girdling shows that current photosynthesis drives soil CO2 flux. Nature 411:789–792CrossRef
21.
Flerchinger GN, Pierson FB (1997) Modelling plant canopy effects on variability of soil temperature and water: model calibration and validation. J Arid Environ 35:641–653CrossRef
22.
Lytle DE, Cronan CS (1998) Comparative soil CO2 evolution, litter decay, and root dynamics in clearcut and uncut spruce-fir forest. For Ecol Manage 103:121–128CrossRef
23.
Laishram ID, Yadava PS, Kakati LN (2002) Soil CO2 flux in a mixed oak forest ecosystem at shiroy hills, Manipur in North Eastern India. Inter J Ecol Envt Sc 28:133–137
24.
Kirschbaum MUF (1995) The temperature dependence of soil organic matter decomposition, and the effect of global warming on soil organic C storage. Soil Bio Biochem 27:753–760CrossRef
25.
Bond-Lamberty B, Thomson A (2010) Temperature-associated increases in the global soil CO2 flux record. Nature 464:579–582CrossRef
26.
Ryan MG, Linder S, Vose JM, Hubbard RM (1994) Dark respiration of pines (Copenhagen). Ecol Bul 43:50–63
27.
Adachi M, Bekku YS, Rashidah W, Okuda T, Koizumi H (2006) Difference in soil CO2 flux between different tropical ecosystems. Appl Soil Ecol 34:258–265CrossRef
28.
Li LJ, You MY, Shi HA, Ding XL, Qiao YF, Han XZ (2013) Soil CO2 emissions from a cultivated mollisol: effects of organic amendments, soil temperature and moisture. Eur J Soil Biol 55:83–90CrossRef
29.
IPCC (2007) Climate change 2007 synthesis report. In: Pachauri RK, Reisinger A (eds) Working group contributions to the fourth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge, UK, pp 23–73
30.
Cooney CM (2010) The perception factor: climate change gets personal. Environ Health Pers 118(11):A484–A489CrossRef
31.
Kutílek M (2011) Soils and climate change. Soil Tillage Res. 117:1–7CrossRef
32.
IPCC (1995) Scientific assessments of climate change. The policymaker’s summary of working group 1 to the intergovernmental panel on climate change, WMO/UNEP
33.
34.
Ciais P, Tans PP, Trolier M, White JWC, Francey RJ (1995) A large northern hemisphere terrestrial CO2 sink indicated by the 13C/12C ratio of atmospheric CO2. Science 269:1098–1102CrossRef
35.
Houghton JT, Filho LGM, Callander BA, Harris N, Kattenburg A, Maskell K (1996) Climate change 1995: the science of climate change: contribution of working group I to the second assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge, U.K.
Metadaten
Titel
Effect of Anthropogenic Activities on the Rate of Soil CO2 Flux in the Dipterocarpus Forest Ecosystem of Northeast India
verfasst von
P. S. Yadava
Amrabati Thokchom
Copyright-Jahr
2021
Verlag
Springer Singapore
Buch
Climate Change and Green Chemistry of CO2 Sequestration

Print ISBN: 978-981-16-0028-9

Electronic ISBN: 978-981-16-0029-6

Copyright-Jahr: 2021

DOI
https://doi.org/10.1007/978-981-16-0029-6_16