Agronomy Science, przyrodniczy lublin, czasopisma up, czasopisma uniwersytet przyrodniczy lublin
  1. Strona domowa
  2. Archiwum
  3. Tom 58 (2003)
  4. Articles

Carbon balance in arable grey forest soils

Alla A. Larionova

Institute of Physico-Chemical and Biological Problems in Soil Science, Pushchino, Institutskaya 2, Moscow Region 142290

Ludmila N. Rozanova

Institute of Physico-Chemical and Biological Problems in Soil Science, Pushchino, Institutskaya 2, Moscow Region 142290

Ilya V. Yevdokimov

Institute of Physico-Chemical and Biological Problems in Soil Science, Pushchino, Institutskaya 2, Moscow Region 142290

Sergey A. Blagodatsky

Institute of Physico-Chemical and Biological Problems in Soil Science, Pushchino, Institutskaya 2, Moscow Region 142290



Abstrakt

Land use management strategies have been developed to decrease the emissions of greenhouse gases to the atmosphere and to increase C stock in stable forms of soil humus. The impact of land use change and management on soil C sequestration was studied in the years 1980-1990 on grey forest soils in Pushchino, Moscow Region, Russia (54o50’ N, 37o35’ E). At present, up to 80% of grey forest soils (Humic Luvisols) are used for agriculture; these soils have been intensively used for crop production since the beginning of 19 th century. Estimates of carbon sink as net primary production and source as CO2 emission evidence the equilibration of these fluxes in most nonfertilised crops. Application of mineral fertilisers separately and in combination with low rates of organic fertilisers promoted the establishment of a mostly positive C balance in the agroecosystems studied. However, the inclusions of crops with negative C balance in crop rotations (fallow and spring cereals) led to the slow increase in stable forms, i.e. in soil humus.

Słowa kluczowe:

soil respiration, C balance, cropland, fertiliser application, C sequestration

Blagodatsky S.A, Larionova A.A, Yevdok . Effect of mineral nitrogen on the respiration rate and growth efficiency of soil microorganisms. Eurasian Soil Sci. 25, 85-95.
Blagodatsky S.A., Yevdokimov I.V. 1998. Extractability of microbial N as influenced by C:N ratio in the flush after drying or fumigation. Biology and Fertility of Soils, 28, 5-11.
Bouwman A.F. 1990. Exchange of greenhouse gases between terrestrial ecosystems and the atmosphere. In: Soils and the greenhouse effect (Ed. A.F. Bouwman), Wiley, Chichester, 61-127.
Davidson E.A., Ackerman I.L. 1993. Changes in soil carbon inventories following cultivation of previously untilled soils. Biogeochemistry, 20, 161-193.
Dobrovolsky G.V., Urusevskaya I.S. 1984. Soil Geography. MGU, Moscow. (in Russian) .
Guo L.B., Gifford R.M. 2002. Soil carbon stocks and land use Change Biology, 8, 345-360.
Jenkinson D.S. 1990. The accumulation of organic carbon and nitrogen in soil. Philosophical Transactions of the Royal Society of London, B, 329, 361-368.
Houghton R.A., Skole D.L. 1990. Carbon. In: The Earth as transformed by human action (Ed. B.L. Turner), Cambridge University Press, Cambridge, 393-408.
Kobak K.I. 1988. Biotic compounds of carbon cycle. Gidrometeoizdat, Leningrad. (in Russian)
Kogut B.M. 1998. Transformation of humus state of chernozems by agricultural use. Pochvovedenije, 7, 794-802. (in Russian)
Kononova M.M. 1984. Organic substances and soil fertility. Pochvovedenije, 8, 6-20. (in Russian)
Kudeyarov V.N. 1999. Nitrogen and carbon balance in soil. Pochvovedenije, 1, 73-82. (in Russian)
Kurganova I.N., Kudeyarov V.N. 1998. Assessment of carbon dioxide fluxes from Taiga Zone of Russia. Pochvovedenije, 9, 1058-1070. (in Russian)
Kuzyakov Y., Friedel J.K., Stahr K. 2000. Review of mechanisms and quantification of priming effects. Soil Biology and Biochemistry, 32, 1485-1498.
Larionova A.A., Yermolayev A.M., Blagodatsky S.A., Rozanova L.N., Yevdokimov I.V., Orlinsky D.B. 1998. Soil respiration and carbon balance of gray forest soils as affected by land use. Biology and Fertility of Soils, 27, 251-257.
Nikitishen V.I., Dmitrakova L.K., Zaborin A.V., Yegorova Y.F. 1996. Ecological and agrochemical aspects of continuous application of mineral fertilisers on grey forest soils of Moscow
Region. Pochvovedenije, 11, 1376-1384. (in Russian)
Nilsson S., Shvidenko A., Stolbovoi V., Gluck M., Jonas M., Obersteiner M. 2000. Full carbon account for Russia. Interim Report IR-00-021, International Institute for Applied Systems Analysis, Laxenburg, Austria.
Orlov D.S., Biryukova O.N., Sukhanova N.I. 1996. Soil Organic Matter of Russia Nauka, Moscow. (in Russian)
Pankhurst C.E., Ophelkeller K., Doube B.M., Gupta V.V.S.R. 1996. Biodiversity of soil microbial communities in agricultural systems. Biodiversity Conservation, 5, 197-209.
Paustian K., Andren O., Clarholm M. 1990. Carbon and nitrogen budgets of four agroecosystems with annual and perennial crops with and without N fertilisation. Journal of Applied Ecology, 27, 60-84.
Paustian K., Andren O., Janzen H.H., Lal R., Smith P., Tian G., Tiessen H., Van Noordwijk M., Woomer P.L. 1997. Agricultural soils as a sink to mitigate CO2 emissions. Soil Use and Management, 13, 230-244.
Schlesinger W.H. 1985. Changes in soil carbon storage and properties associated with disturbance and recovery. In: The Changing Carbon Cycle: A Global Analysis (Eds J.R. Trabalka, D.L. Reichle), Springer, New York.
Schlesinger W.H. 2000. Carbon sequestration in soils: some cautions amidst optimism. Agricultural Ecosysystems and Environment, 82, 121-127.
Shevtsova L.K., Volodarskaya I.V. 1998. Humus transformation of soddy-podzolic soils in ex-periments with long-term application of mineral fertilisers. Pochvovedenije, 7, 825-831. (in Russian)
Smith P., Powlson D.S., Smith J.U., Falloon P., Coleman K. 2000. Meeting Europe's climate change commitments: quantitative estimates of the potential for carbon mitigation by agriculture. Global Change Biology, 6, 525-539.
Szegi J. 1988. Cellulose decomposition and soil fertility. Budapest,
Titlyanova A., Tesarova M. 1991. The regimes of biological turnover, Nauka, Novosibirsk. (in Russian)
Zelles L., Bai Q.Y., Beck T., Beese F. 1992. Signature fatty acids in phospholipids and lipopolysaccharides as indicators of microbial biomass and community structure in agricultural soils. Soil Biology and Biochemistry, 24, 317-323.
Pobierz


Opublikowane
31-12-2003



Alla A. Larionova 
Institute of Physico-Chemical and Biological Problems in Soil Science, Pushchino, Institutskaya 2, Moscow Region 142290
Ludmila N. Rozanova 
Institute of Physico-Chemical and Biological Problems in Soil Science, Pushchino, Institutskaya 2, Moscow Region 142290
Ilya V. Yevdokimov 
Institute of Physico-Chemical and Biological Problems in Soil Science, Pushchino, Institutskaya 2, Moscow Region 142290
Sergey A. Blagodatsky 
Institute of Physico-Chemical and Biological Problems in Soil Science, Pushchino, Institutskaya 2, Moscow Region 142290



Licencja

Artykuły są udostępniane na zasadach CC BY 4.0 (do 2020 r. na zasadach CC BY-NC-ND 4.0)..
Przysłanie artykułu do redakcji oznacza, że nie był on opublikowany wcześniej i nie jest rozpatrywany do publikacji gdzie indziej.

Autor podpisuje oświadczenie o oryginalności dzieła, wkładzie poszczególnych osób i źródle finansowania.

 

Samoarchiwizacja

Czasopismo Agronomy Science przyjęło politykę samoarchiwizacji nazwaną przez bazę Sherpa Romeo drogą niebieską. Od 2021 r. autorzy mogą samoarchiwizować postprinty artykułów oraz wersje wydawnicze (zgodnie z licencją CC BY). Artykuły z lat wcześniejszych (udostępniane na licencji CC BY-NC-ND 4.0) mogą być samoarchiwizowane tylko w wersji wydawniczej.

 




Wydawnictwo Uniwersytetu Przyrodniczego w Lublinie

ul. Akademicka 15,
20-950 Lublin
tel. (81) 445 66 60

Copyright

Copyright 2018 by Uniwersytet Przyrodniczy w Lublinie
OJS Support and Customization by LIBCOM
Platform & workfow by OJS/PKP