Проблемы моделирования биогеохимического цикла углерода в агроландшафтах

103. Kammann C., Hepp S., Lenhart K., Mьller C. Stimulation of methane consumption by endogenous CH4 production in aerobic grassland soil // Soil Biol. Biochem. - 2009. - V. 41, No 3. - P. 622-629. - doi: 10.1016/j.soilbio.2008.12.025.

104. Eliseev A.V., Mokhov I.I. Carbon cycle - climate feedback sensitivity to parameter changes of a zero-dimensional terrestrial carbon cycle scheme in a climate model of intermediate complexity // Theor. Appl. Climatol. - 2007. - V. 89, No 1-2. - P. 9-24. - doi: 10.1007/s00704-006-0260-6.

105. McGuire A.D., Sitch S., Clein J.S., Dargaville R., Esser G., Foley J., Heimann M., Joos F., Kaplan J., Kicklighter D.W., Meier R.A., Melillo J.M., Moore III B., Prentice I.C., Ra- mankutty N., Reichenau T., Schloss A., Tian H., Williams L.J., Wittenberg U. Carbon balance of the terrestrial biosphere in the twentieth century: analyses of CO2, climate and land use effects with four process-based ecosystem models // Global Biogeochem. Cycles. - 2001. - V. 15. - P. 183-206. - doi: 10.1029/2000GB001298.

106. Zavalishin N.N. Dynamic compartment approach for modeling regimes of carbon cycle functioning in bog ecosystems // Ecol. Modell. - 2008. - V. 213, No 1. - P. 16-32. - doi: 10.1016/j.ecolmodel.2007.12.006.

107. Комаров А.С., Припутина И.В., Михайлов А.В., Чертов О.Г. Биогеохимический цикл углерода в лесных экосистемах центра Европейской России и его техногенные изменения // Почвенные процессы и пространственно-временная организация почв / Отв. ред. В.Н. Кудеяров. - М.: Наука, 2006. - С. 362-377.

108. Голубятников Л.Л., Мохов И.И., Елисеев А.В. Цикл азота в земной климатической системе и его моделирование // Изв. РАН. Физика атмосферы и океана. - 2013. Т. 49, № 3. - С. 255-270.

109. Elzen M.G.J., Beusen A.H.W., Rotmans J. An integrated modeling approach to global carbon and nitrogen cycles: Balancing their budgets // Global Biogeochem. Cycles. - 1997. - V. 11, No 2. - P. 191-215. - doi: 10.1029/96GB03938.

110. Базилевич Н.И., Титлянова А.А. Биотический круговорот на пяти континентах: азот и зольные элементы в природных наземных экосистемах. - Новосибирск: Изд-во СО РАН, 2008. - 381 с.

111. Thornton P.E., Lamarque J.F., Rosenbloom N.A., Mahowald N.M. Influence of carbonnitrogen cycle coupling on land model response to CO2 fertilization and climate variability // Global Biogeochem. Cycles. - 2007. - V. 21, No 4. - Art. GB4018, P. 1-15. - doi: 10.1029/2006GB002868.

112. Gerber S., Hedin L.O., Oppenheimer M., Pacala S.W., Shevliakova E. Nitrogen cycling and feedbacks in a global dynamic land model // Global Biogeochem. Cycles. - 2010. - V. 24, No 1. - Art. GB1001, P. 1-15. - doi: 10.1029/2008GB003336.

113. Jain A., YangX., Kheshgi H., McGuire A.D., Post W., Kicklighter D. Nitrogen attenuation of terrestrial carbon cycle response to global environmental factors // Global Biogeochem. Cycles. - 2009. - V. 23, No 4. - Art. GB4028, P. 1-13. - doi: 10.1029/2009GB003474.

114. Thornton P.E., Doney S.C., Lindsay K., Moore J.K., MahowaldN., Randerson J.T., Fung I., Lamarque J.F., Feddema J.J., Lee Y.H. Carbon-nitrogen interactions regulate climate- carbon cycle feedbacks: results from an atmosphere-ocean general circulation model // Biogeosciences. - 2009. - V. 6, No 10. - P. 2099-2120. - doi: 10.5194/bg-6-2099-2009.

115. Титлянова А.А., Чупрова В.В. Изменение круговорота углерода в связи с различным использованием земель (на примере Красноярского края) // Почвоведение. - 2003. - № 2. - С. 211-219.

116. Ганжара Н.Ф., Борисов Б.А. Гумусообразование и агрономическая оценка органического вещества почв. - М.: Агроконсалт, 1997. - 82 с.

117. Gougoulias C., Clark J.M., Shaw L.J. The role of soil microbes in the global carbon cycle: Tracking the below-ground microbial processing of plant-derived carbon for manipulating carbon dynamics in agricultural systems // J. Sci. Food Agric. - 2014. - V. 94, No 12. - P. 2362-2371. - doi: m.1002/jsfa.6577.

118. Лопес де Гереню В.О., Курганова И.Н., Ермолаев А.М., Кузяков Я.В. Измерение пулов органического углерода при самовосстановлении пахотных черноземов // Агрохимия. - 2009. - № 5. - С. 5-12.

119. Дегтярев В.В., Панасенко О.С., Недбаев В.Н. Содержание коллоидных форм гумуса в структурных агрегатах черноземов типичных при различных условиях лесостепи Украины // Вестн. Курск. гос. с.-х. акад. - 2013. - № 5. - С. 60-62.

120. Чупрова В.В. Минерализуемый пул органического вещества в агрочерноземах юга Средней Сибири // Вестн. Краснояр. гос. аграр. ун-та. - 2013. - № 9. - С. 83-89.

121. Шарков И.Н., Самохвалова Л.М., Мишина П.Н., Шепелев А.Г. Влияние пожнивных остатков на состав органического вещества чернозема выщелоченного в лесостепи Западной Сибири // Почвоведение. - 2014. - № 4. - С. 473-479.

122. Кузнецова Т.В., Удальцов С.Н., Демкин В.А. Минерализация активного органического вещества современных и погребенных каштановых почв сухостепной зоны // Вестн. Тамб. ун-та. Сер. Естеств. науки. - 2013. - Т. 18, Вып. 3. - С. 978-981.

123. Когут Б.М., Яшин М.А., Семенов В.М., Авдеева Т.Н., Маркина Л.Г., Лукин С.М., Тарасов С.И. Распределение трансформированного органического вещества в структурных отдельностях дерново-подзолистой супесчаной почвы // Почвоведение. - 2016. - № 1. - С. 52-64. - doi: 10.7868/S0032180X1601007X.

124. Цыбулько Н.Н., Шапшеева Т.П., Арастович Т.В., Зайцев А.А. Минерализационная способность органического вещества торфяных почв и поступление ^^s в многолетние злаковые травы // Мелиорация. - 2010. - № 2. - С. 109-122.

125. Muller T., Hoper Н. Soil organic matter turnover as a function of the soil clay content: Consequences for model application // Soil Biol. Biochem. - 2004. - V. 36, No 6. - P. 877-888. - doi: 10.1016/j.soilbio.2003.12.015.

126. Schwendenmann L., Pendal E. Response of organic matter dynamics to conversion from tropical forest to grassland as determined by long-term incubation // Biol. Fertil. Soils. - 2008. - V. 44, No 8. - P. 1053-1062. - doi: 10.1007/s00374-008-0294-2.

127. Иванов И.В., Песочина Л.С., Семенов В.М. Биоминерализация органического вещества в современных целинных, пахотных, погребенных и ископаемых черноземах // Почвоведение. - 2009. - № 10. - С. 1192-1202.

128. Bond-Lamberty B., Thompson A. Temperature associated increases in the global soil respiration record // Nature. - 2010. - V. 464. - P. 579-582. - doi: 10.1038/nature08930.

129. Kuzyakov Y. Sources of CO2 efflux from soil and review of partitioning methods // Soil Biol. Biochem. - 2006. - V. 38, No 3. - P. 425-448. - doi: 10.1016/j.soilbio.2005.08.020.

130. Luo Y., Zhou X. Soil Respiration and the Environment. - Burlington: Acad. Press, 2006. - 316 p.

131. Raich J.W., Potter C.S., Bhagawatti D. Interannual variability in global soil respiration, 1980-94 // Global Change Biol. - 2002. - V. 8, No 8. - P. 800-812. - doi: 10.1046/j .1365-2486.2002.00511.x.

132. Степанов А.Л. Микробная трансформация парниковых газов в почвах. - М.: ГЕОС, 2011. - 192 с.

133. BardgettR.D. Plant-soil interactions in a changing world // Biol. Rep. - 2011. - V. 3. - Art. 16, P. 1-6. - doi: 10.3410/B3-16.

134. Ларионова А.А., Сапронов Д.В., Лопес де Гереню В.О., Кузнецова Л.Г., Кудеяров

135. Н. Вклад дыхания корней растений в эмиссию СО2 из почвы // Почвоведение. - 2006. - № 10. - С. 1248-1257.

136. Заварзин Г.А., Кудеяров В.Н. Почва как главный источник углекислоты и резервуар органического углерода на территории России // Вестн. РАН. - 2006. - Т. 76, № 1. -

137. 14-29.

138. Сапронов Д.В., Кузяков Я.В. Разделение корневого и микробного дыхания: сравнение трех методов // Почвоведение. - 2007. - № 7. - С. 862-872.

139. Кузяков Я.В., Ларионова А.А. Вклад ризомикробного и корневого дыхания в эмиссию СО2 из почвы (обзор) // Почвоведение. - 2006. - № 7. - С. 842-854.

140. Курганова И.Н. Эмиссия и баланс диоксида углерода в наземных экосистемах России: Автореф. дис. ... д-ра биол. наук. - Пущино, 2010. - 48 с.

141. Евдокимов И.В., Ларионова А.А., Шмитт М, Лопес де Гереню В.О., Бан М. Определение вклада дыхания корней растений в эмиссию СО2 из почвы методом субстратно-индуцированного дыхания // Почвоведение. - 2010. - № 3. - С. 349-355.

142. Hanson P.J., Edwards N.T., Garten C.T., Andrews J.A. Separating root and soil microbial contributions to soil respiration: A review of methods and observations // Biogeochemistry. - 2000. - V. 48, No 1. - P. 115-146. - doi: 10.1023/A:1006244819642.

143. Ларионова А.А., Евдокимов И.В., Курганова И.Н., Сапронов Д.В., Кузнецова Л.Г., Лопес Де Гереню В.О. Дыхание корней и его вклад в эмиссию СО2 из почвы // Почвоведение. - 2003. - № 2. - С. 183-194.

144. Sun W.J., Huang Y., Chen S.T., Yang Z.F., ZhengX.H. CO2 emission from soil-crop system as influenced by crop growth and tissue N content // Huan Jing Ke Xue. - 2004. - V. 25, No 3. - P. 1-6. (на кит. яз.)

145. Swinnen J. Evaluation of the use of a model rhizodeposition technique to separate root and microbial respiration in soil // Plant Soil. - 1994. - V. 165, No 1. - P. 89-101. - doi: 10.1007/BF00009966.

146. Сапронов Д.В. Многолетняя динамика эмиссии СО2 из серых лесных и дерновоподзолистых почв: Автореф. дис. ... канд. биол. наук. - Пущино, 2008. - 20 с.

147. Helal H.M., Sauerbeck D. Short term determination of the actual respiration rate of intact plant roots // Plant Roots and Their Environment / Eds. McMichal B.L., Person H. - Amsterdam: Elsevier, 1991. - P. 88-92.

148. Евдокимов И.В., Рузер Р., Бюггер Ф., Маркс М., Мюнх Ж.Ш. Круговорот углерода в ризосфере при постоянном мечении растений в атмосфере C13-CO2: разделение корневого, микробного и ризомикробного дыхания // Почвоведение. - 2007. - № 9. - С. 1086-1094.

149. Da Costa J.M.N. Respiratory releases of carbon dioxide by aerial parts and roots of field-grown alfalfa and soybeans: PhD Thesis. - Lincoln: Univ. of Nebraska, 1983. - 125 p.

150. Biasi C., Pitkamaki A.S., Tavi N.M., Koponen H.T., Martikainen P.J. An isotope approach based on 13C pulse-chase labelling vs. the root trenching method to separate heterotrophic and autotrophic respiration in cultivated peatlands // Boreal Env. Res. - 2012. - V. 17, No 3-4. - Р. 184-192.

151. Орлова О.В. Активное органическое вещество как регулятор процессов трансформации азота и углерода в дерново-подзолистых почвах: Автореф. . д-ра биол. наук. - СПб., 2013. - 48 с.

152. Карелин Д.В., Замолодчиков Д.Г., Каганов В.В., Почикалов А.В., Гитарский М.Л. Микробная и корневая составляющие дыхания дерново-подзолистых почв южной тайги // Лесоведение. - 2017. - № 3. - С. 183-195.

153. Suleau M., Moureaux C., Dufranne D., Buysse P., Bodson B., Destain J.P., Heinesch B., Debacq A., AubinetM. Respiration of three Belgian crops: Partitioning of total ecosystem respiration in its heterotrophic, above- and below-ground autotrophic components // Agricult. Forest Meteorol. - 2011. - V. 151, No 5. - Р. 633-643. - doi: 10.1016/j.agrformet.2011.01.012.

154. Sadras V.O., Calderini D. Crop physiology: application for genetic improvements and agronomy. - Burlington, MA, USA: Acad. Press, 2009. - 581 p.



References

углерод биогеохимический цикл

1. IPCC, 2014: Climate Change 2014: Mitigation of Climate Change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Edenhofer O., Pichs-Madruga R., Sokona Y., Farahani E., Kadner S., Seyboth K., Adler A., Baum I., Brunner S., Eickemeier P., Kriemann B., Savolainen J., Schlomer S., von Stechow Ch., Zwickel T., Minx J.C. (Eds.). Cambridge, New York, Cambridge Univ. Press, 2014. 1435 p.

2. Poluektov R.A., Smolyar E.I., Terleev V.V., Topazh A.G. Modeli produktsionnogo protsessa sel'sko- khozyaistvennykh kul'tur [Modelling the Production Process of Agricultural Crops]. St. Petersburg, Izd. S.-Petersb. Univ., 2011. 390 p. (In Russian)

3. Ol'chev A.V. Fluxes of CO2 and H2O in forest ecosystems under climate change conditions (evaluation by using mathematical models). Extended Abstract of Doc. Biol. Sci. Diss. Moscow, 2015. 51 p. (In Russian)

4. Priputina I.V., Frolova G.G., Shanin V.N. Substantiation of optimum planting schemes for forest plantations: A computer experiment. Komp'yut. Issled. Model., 2016, vol. 8, no. 2, pp. 333-343. (In Russian)

5. Blagodatsky S.A., Yevdokimov I.V., Larionova A.A., Richter J. Microbial growth in soil and nitrogen turnover: Model calibration with laboratory data. Soil Biol. Biochem., 1998, vol. 30, no. 13, pp. 1757-1764. doi: 10.1016/S0038-0717(98)00029-7.

6. Scurlock J.M.O., Cramer W., Olson R.J., Parton W.J., Prince S.D. Terrestrial NPP: Toward a consistent data set for global model evaluation. Ecol. Appl., 1999, vol. 9, no. 3, pp. 913-919. doi: 10.2307/2641338.

7. Golubyatnikov L.L., Svirezhev Yu.M. Life-cycle model of terrestrial carbon exchange. Ecol. Modell., 2008, vol. 213, no. 2, pp. 202-208. doi: 10.1016/j.ecolmodel.2007.12.001.

8. Tonitto C., Powell T.M. Development of a spatial terrestrial nitrogen model for application to Douglas-fir forest ecosystems. Ecol. Modell., 2006, vol. 193, nos. 3-4, pp. 340-362. doi: 10.1016/j. ecolmodel.2005.08.041.

9. Tarko A.M. A model of the carbon and nitrogen biogeochemical cycle in forest ecosystem. In: Regulyatornaya rol' pochvy v funktsionirovanii taezhnykh ekosistem [The Regulatory Role of Soil in the Functioning of Taiga Ecosystems]. Dobrovol'skii G.V. (Ed.). Moscow, Nauka, 2002, pp. 215 -226. (In Russian)

10. Cox P.M., Betts R.A., Jones C.D., Spall S.A., Totterdell I.J. Modelling vegetation and the carbon cycle as interactive elements of the climate system. In: Pearce R. (Ed.) Meteorology at the Millennium. New York, Acad. Press, 2001, pp. 259-279.

11. Volodin E.M. Atmosphere-ocean general circulation model with the carbon cycle. Izv., Atmos. Oceanic Phys, 2007, vol. 43, no.3, pp. 266-280. doi: 10.1134/S0001433807030024.

12. Mokhov I.I., Eliseev A.V., Karpenko A.A. Sensitivity of the IFA RAN Global Climatic Model with an interactive carbon cycle to anthropogenic influence. Dokl. Earth Sci., 2006, vol. 407, no. 2, pp. 424-428. doi: 10.1134/S1028334X06030172.

13. Belyuchenko I.S., Smagin A.V., Popok L.B., Popok L.E. Analiz dannykh i matematicheskoe mod- elirovanie v ekologii i prirodopol 'zovanii [Data Analysis and Mathematical Modelling in Ecology and Nature Management]. Krasnodar, Izd. Kuban. Gos. Agrar. Univ., 2015. 313 p. (In Russian)

14. Solodyankina S.V., Cherkashin A.K. Geoinformation analysis and modelling of geosystem functions of carbon stock accumulation in mountain forests of the Baikal region in the changing environment. Vestn. NGU. Ser. Inf. Tekhnol., 2011, vol. 9, no. 1, pp. 44-55. (In Russian)

15. Rosenstock T.S., Rufino M.C., Butterbach-Bahl K., Wollenberg E., Richards M. (Eds.) Methods for Measuring Greenhouse Gas Balances and Evaluating Mitigation Options in Smallholder Agriculture. Springer, 2016. XV, 203 p. doi: 10.1007/978-3-319-29794-1.

16. Sukhoveeva O.E. Modelling of greenhouse gases fluxes and cycles of carbon and nitrogen in soils (overview). Zh. Estestvennonauchn. Issled., 2017, vol. 2, no. 7, pp. 61-76. (In Russian)

17. Cao M., Dent J.B., Heal O.W. Modeling methane emissions from rice paddies. Global Biogeo- chem. Cycles, 1995, vol. 9, no. 2, pp. 193-195. doi: 10.1029/94GB03231.

18. Raich J.W., Potter C.S. Global patterns of carbon dioxide emission from soils. GlobalBiogeochem. Cycles, 1995, vol. 9, no. 1, pp. 23-36. doi: 10.1029/94GB02723.

19. Tsuji G.Y., Uehara G., Balas S. DSSATv3. Honolulu, Univ. of Hawaii, 1994. 661 p.

20. Gao L., Jin Z., Huan Y. An Optimizing Decision-Making System for Rice Culture. Beijing, China Agric. Sci. Technol. Press, 1992.

21. Sellers P.J., Mintz Y., Sud Y.C., Dalcher A. A simple biosphere model (SiB) for use within general circulation models. J. Atmos. Sci., 1986, vol. 43, no. 6, pp. 505-531. doi: 10.1175/1520- 0469(1986)043<0505:ASBMFU>2.0.CO;2.

22. Penning de Vries F.W.T., Jansen D.M., Ten Berge H.F.M., Bakema A. Simulation of Ecophysio- logical Processes of Growth in Several Annual Crops. Pudoc, Wageningen, 1989. 271 p.

23. Jenkinson D.S., Hart P.B.S., Rayner J.H., Parry L.C. Modelling the turnover of organic matter in long-term experiments at Rothamsted. INTECOL Bull., 1987, no. 15, pp. 1-8.

24. Sokolov A.P., Kicklighter D.W., Melillo J.M., Felzer B.S., Schlosser C.A., Cronin T.W. Consequences of considering carbon-nitrogen interactions on the feedbacks between climate and the terrestrial carbon cycle. J. Clim., 2008, vol. 21, no. 15, pp. 3776-3796. doi: 10.1175/2008JCLI2038.1.

25. Komarov A., Chertov O., Zudin S., Nadporozhskaya M., Mikhailov A., Bykhovets S., Zudina E., Zoubkova E. EFIMOD 2 - a model of growth and elements cycling in boreal forest ecosystems. Ecol. Modell., 2003, vol. 170, pp. 373-392.

26. Parton W.J., Scurlock J.M.D., Ojima D.S., Gilmanov T.G., Scholes R.J., Schimel D.S., Kirchner T., Menaut J.C., Seastedt T., Garcia Moya E., Kamnalrut A., Kinyamario J.L. Observations and modeling of biomass and soil organic matter dynamics for the grassland biome worldwide. Global Bio- geochem. Cycles, 1993, vol. 7, no. 4, pp. 785-809. doi: 10.1029/93GB02042.

27. Li C., Frolking S., Frolking T.A. A model of nitrous oxide evolution from soil driven by rainfall events: 1. Model structure and sensitivity. J. Geophys. Res., 1992, vol. 97, no. D9, pp. 9759-9776. doi: 10.1029/92JD00509.

28. Grant R.F., Pattey E. Modelling variability in N2O emissions from fertilized agricultural fields. Soil Biol. Biochem., 2003, vol. 35, no. 2, pp. 225-243. doi: 10.1016/S0038-0717(02)00256-0.

29. Zaehle S., Friend A.D. Carbon and nitrogen cycle dynamics in the O-CN land surface model: 1. Model description, site-scale evaluation, and sensitivity to parameter estimates. Global Biogeo- chem. Cycles, 2010, vol. 24, no. 1, art. GB1005, pp. 1-13. doi: 10.1029/2009GB003521.

30. Chertov O., Komarov A., Shaw C., Bykhovets S., Frolov P., Shanin V., Grabarnic P., Priputina I., Zubkova E., Shashkov M. Romul_Hum - A model of soil organic matter formation coupling with soil biota activity. II. Parameterization of the soil food web biota activity. Ecol. Modell., 2017, vol. 345, pp. 125-139. doi: 10.1016/j.ecolmodel.2016.10.024.

31. Raich J.W., Rastetter E.B., Melillo J.M., Kicklighter D.W., Steudler P.A., Peterson B.J., Grace A.L., Moore III B., Vorosmarty C.J. Potential net primary productivity in South America: Application of a global model. Ecol. Appl., 1991, vol. 1, pp. 399-429. doi: 10.2307/1941899.

32. Blagodatsky S.A. Microbial biomass and modelling nitrogen cycle in soil. Extended Abstract of Doct. Biol. Sci. Diss. Pushchino, 2011. 51 p. (In Russian)

33. Dickinson R.E., Henderson-Sellers A., Kennedy P.J., Wilson M.F. Biosphere atmosphere transfer scheme (BATs) for NCAR community climate model. NCAR Technical Note No. NCAR/TN-275- +STR. Boulder, Colo., Natl. Cent. Atmos. Res., 1986. 82 p. doi: 10.5065/D6668B58.

34. Jain A.K., Kheshgi H.S., Wuebbles D.J. Integrated science model for assessment of climate change model. Proc. Annu. Meet. Exhib. Air Waste Manage. Assoc., Cincinnati, OH (United States), June 19-24, 1994. United States, 1994. Available at: https://www.osti.gov/servlets/purl/10151110.

35. Xu-Ri, Prentice I.C. Terrestrial nitrogen cycle simulation with a dynamic global vegetation model. Global Change Biol., 2008, vol. 14, no. 8, pp. 1745-1764. doi: 10.1111/j.1365-2486.2008.01625.x.

36. Wania R., Meissner K.J., M. Eby M., Arora V.K., Ross I., Weaver A.J. Carbon-nitrogen feedbacks in the UVic ESCM. Geosci. Model Dev., 2012, vol. 5, no. 5, pp. 1137-1160. doi: 10.5194/gmd-5-1137-2012.

37. Tarko A.M. Mathematical modelling of global biogeochemical cycles of carbon and nitrogen. Extended Abstract of Doct. Phys.-Math. Sci. Diss. Moscow, 1992. 47 p. (In Russian)

38. Elzen den M.G.J., Beusen A.H.W., Rotmans J. Modelling global biogeochemical cycles an integrated assessment approach. RIVMReportNo. 461502007. Bilthoven, the Netherlands, RIVM, 1995. 137 p.

39. Krapivin V.F., Svirezhev Yu.M., Tarko A.M. Matematicheskoe modelirovanie global'nykh biosfernykh protsessov [Mathematical Modelling of Global Biospheric Processes]. Moscow, Nauka, 1982. 272 p. (In Russian)

40. Giltrap D.L., Li C., Saggar S. DNDC: A process-based model of greenhouse gas fluxes from agricultural soils. Agric., Ecosyst. Environ., 2010, vol. 136. nos. 3-4, pp. 292-300. doi: 10.1016/j.agee.2009.06.014.

41. Leip A., Marci G., Koeble R., Kempen M., Britz W., Li C. Linking an economic model for European agriculture with a mechanistic model to estimate nitrogen and carbon losses from arable soils in Europe. Biogeosciences, 2008, vol. 5, no. 1, pp. 73-94. doi: 10.5194/bg-5-73-2008.

42. FACCE-JPI Projects Booklet: FACCE ERA-NET Plus, MACSUR and Multi-Partner Call on GHG Mitigation. Brussels, Belgium, FACCE-JPI, 2017. 42 p.

43. Smith P., Smith J.U., Powlson D.S., McGill W.B., Arah J.R.M., Chertov O.G., Coleman K., Franko U., Frolking S., Jenkinson D.S., Jensen L.S., Kelly R.H., Klein-Gunnewiek H., Komarov A.S., Li C., Molina J.A.E., Mueller T., Parton W.J., Thornley J.H.M., Whitmore A.P. A comparison of the performance of nine soil organic matter models using datasets from seven long-term experiments. Geoderma, 1997, vol. 81, nos. 1-2, pp. 153-225. doi: 10.1016/S0016-7061(97)00087-6.

44. Larionova A.A., Kurganova I.N., de Gerenyu V.O.L., Zolotareva B.N., Yevdokimov I.V., Kudeya- rov V.N. Carbon dioxide emissions from agrogray soils under climate changes. Eurasian Soil Sci., 2010, vol. 43, no. 2, pp. 168-176. doi: 10.1134/S1064229310020067.

45. Markovskaya G.K., Mel'nikova N.A., Nechaeva E.Kh. Biological activity of soil treated by different methods during spring wheat cultivation. Agrar. Nauchn. Zh., 2014, no. 2, pp. 22-25. (In Russian)

46. Kosolapov V.M., Trofimov I.A., Trofimova L.S., Yakovleva E.P. Agrolandshafty Tsentral'nogo Chernozem'ya. Raionorovanie i upravlenie [Agrolandscapes of Central Chernozem Zone: Zonation and Management]. Moscow, Nauka, 2015. 198 p. (In Russian)

47. Semenov V.M., Tulina A.S. Comparison of mineralized pool of organic matter in soils of natural and agricultural ecosystems. Agrokhimiya, 2011, no. 12, pp. 53-63. (In Russian)

48. Rees R.M., Bingham I.J., Baddeley J.A., Watson C.A. The role of plants and land management in sequestering soil carbon in temperate arable and grassland ecosystems. Geoderma, 2005. vol. 128, nos. 1-2, pp. 130-154. doi: 10.1016/j.geoderma.2004.12.020.

49. Avksent'ev A.A. Greenhouse gas emissions (C02, N20, CH4) by ordinary chernozem of the Stone Steppe. Extended Abstract of Cand. Biol. Sci. Diss. Voronezh, 2011. 21 p. (In Russian)

50. Goncharova O.Yu., Telesnina V.M. The biological activities of post-agrogenic soils (based on an example from the Moscow region). Moscow Univ. Soil Sci. Bull., 2010, vol. 65, no. 4, pp. 159-167. doi: 10.3103/S0147687410040058.

51. Gedgafova F.V., Uligova T.S., Gorobtsova O.N., Tembotov R.Kh. The biological activity of chernozems in the Central Caucasus Mountains (Terskii variant of altitudinal zonality), Kabardino-Balkaria. Eurasian Soil Sci, 2015, vol. 48, no. 12, pp. 1341-1348. doi: 10.1134/S1064229315120078.

52. Stol'nikova E.V. Microbial biomass, its structure and greenhouse gases production by soils under different land use. Extended Abstract of Cand. Biol. Sci. Diss. Pushchino, 2010. 25 p. (In Russian)

53. Kolchugina T.P., Vinson T.S., Gaston G.G., Rozhkov V.A., Schlentner S.F. Carbon pools, fluxes, and sequestration potential in soil of the Former Soviet Union. In: Lal R., Kimble J., Levine E., Stewart B.A. (Eds.) Soil Management and Greenhouse Effect. Boca Raton, London, Tokyo, Lewis Publ., 1995, pp. 25-40.

54. Lal R. Soil carbon sequestration to mitigate climate change. Geoderma, 2004, vol. 123. nos. 1-2, pp. 1-22. doi: 10.1016/j.geoderma.2004.01.032.

55. Semenov V.M., Ivannikova L.A., Kuznetsova T.V., Semenova N.A., Tulina A.S. Mineralization of organic matter and the carbon sequestration capacity of zonal soils. Eurasian Soil Sci., 2008, vol. 41, no. 7, pp. 717-730. doi: 10.1134/S1064229308070065.

56. Khokhlov V.G. Organic matter of sod-podzolic soils in the Smolensk region. Extended Abstract of Cand. Agric. Sci. Diss. Moscow, 1980. 16 p. (In Russian)

57. Shikhova L.N., Lisitsyn E.M. Carbon content and stock dynamics in humus of arable podzolic soils of the south taiga subzone in the Kirov region. Vestn. Udmurt. Univ. Ser. Biol. Nauki Zemle, 2014, no. 2, pp. 7-13. (In Russian)

58. Zavyalova N.E., Mitrofanova E.M., Kazakova I.V. Mineral fertilizers and lime influence on the content of active elements in the organic matter of sod-podzolic soil and spring wheat yield. Dostizh. Nauki Tekh. APK, 2013, no. 11, pp. 19-20. (In Russian)

59. Zinyakova N.B. Active organic matter in gray forest soil under organic and mineral fertilization systems. Cand. Biol. Sci. Diss. Pushchino, 2014. 167 p. (In Russian)

60. Bezuglova O.S., Yudina N.V. Interrelationship between the physical properties and the humus content of chernozems in the south of European Russia. Eurasian Soil Sci., 2006, vol. 39, no. 2, pp. 187-194. doi: 10.1134/S1064229306020098.

61. IPCC, 2006: 2006IPCC Guidelines for National Greenhouse Gas Inventories, Prepared by the National Greenhouse Gas Inventories Programme. Eggleston H.S., Buendia L., Miwa K., Ngara T., Tanabe K. (Eds.). Hayama, IGES, 2006. 37 p.

62. Houghton R.A., House J.I., Pongratz J., van der Werf G.R., DeFries R.S., Hansen M.C., Le Quere C., Ramankutty N. Carbon emissions from land use and land-cover change. Biogeosciences, 2012, vol. 9, no. 12, pp. 5125-5142. doi: 10.5194/bg-9-5125-2012.

63. Friedlingstein P., Jones M.W., O'Sullivan M., Andrew R.M., Hauck J., Peters G.P., Peters W., Pongratz J., Sitch S., Le Quйrй C., Bakker D.C.E., Canadell J.G., Ciais P., Jackson R.B., Anthoni P., Barbero L., Bastos A., Bastrikov V., Becker M., Bopp L., Buitenhuis E., Chandra N., Chevallier F., Chini L.P., Currie K.I., Feely R.A., Gehlen M., Gilfillan D., Gkritzalis T., Goll D.S., Gruber N., Gutekunst S., Harris I., Haverd V., Houghton R.A., Hurtt G., Ilyina T., Jain A.K., Joetzjer E., Kaplan J.O., Kato E., Klein Goldewijk K., Korsbakken J.I., Landschьtzer P., Lauvset S.K., Lefиvre N., Lenton A., Lienert S., Lombardozzi D., Marland G., McGuire P.C., Melton J.R., Metzl N., Munro D.R., Nabel J.E.M.S., Nakaoka S.-I., Neill C., Omar A. M., Ono T., Peregon A., Pierrot D., Poulter B., Rehder

G. , Resplandy L., Robertson E., Rцdenbeck C., Sйfйrian R., Schwinger J., Smith N., Tans P.P., Tian

H. , Tilbrook B., Tubiello F.N., van der Werf G.R., Wiltshire A.J., Zaehle S. Global Carbon Budget 2019. Earth Syst. Sci. Data, 2019, vol. 11, no. 4, pp. 1783-1838. doi: 10.5194/essd-11-1783-2019.

64. Zavarzin G.A. (Ed.) Puly i potoki ugleroda v nazemnykh ekosistemakh Rossii [Carbon Pools and Fluxes in Russian Terrestrial Ecosystems]. Moscow, Nauka, 2007. 315 p. (In Russian)

65. Smith J., Smith P., Wattenbach M., Gottschalk P., Romanenkov V.A., Shevtsova L.K., Sirotenko O.D., Rukhovich D.I., Koroleva P.V., Romanenko I.A., Lisovoi N.V. Projected changes in the organic carbon stocks of croplands mineral soils of European Russia and the Ukraine, 1990-2070. Global Change Biol., 2007, vol. 13, no. 2, pp. 342-356. doi: 10.1111/j.1365-2486.2006.01297.x.

66. Solodyankina S.V., Cherkashin A.K. Economic GIS assessment of the vegetation capacity for neutralization of anthropogenic emissions of carbon dioxide in the south of Eastern Siberia. Vestn. NGU. Ser. Inf. Tekhnol., 2014, vol. 12, no. 2, pp. 99-108. (In Russian)

67. Naumov A.V. Soil respiration: Constituents, ecological functions, geographical patterns. Extended Abstract of Doct. Biol. Sci. Diss. Novosibirsk, 2003. 39 p. (In Russian)

68. Smagin A.V., Sadovnikova N.B., Shcherba T.I., Shnyrev N.A. Abiotic factors of soil respiration. Ekol. Vestn. Sev. Kavk., 2010, vol. 6, no. 1, pp. 5-13. (In Russian)

69. Chen S., Zou J., Hu Z., Chen H., Lu Y. Global annual soil respiration in relation to climate, soil properties and vegetation characteristics: Summary of available data. Agric. For. Meteorol., 2014, vol. 198-199, pp. 335-346. doi: 10.1016/j.agrformet.2014.08.020.

70. Estimation of emissions from agriculture. United Nations Framework Convention on Climate Change. FCCC/SBSTA/2004/INF.4. Bonn, UNFCCC, 2004. 20 p. Available at: http://unfccc.int/ resource/docs/2004/sbsta/inf04.pdf.

71. Chertov O.G., Nadporozhskaya M.A. Models of soil organic matter dynamics: Problems and prospects. Komp 'yut. Issled. Model., 2016, vol. 8, no. 2, pp. 391-399. (In Russian)

72. Cai Z.T., Sawamoto T., Li C., Kang G., Boonjawat J., Mosier A., Wassman R., Tsuruta H. Field validation of the DNDC model for greenhouse gas emission in East Asia cropping system. Global Biochem. Cycles, 2003, vol. 17, no. 4, art. 1107, pp. 1-10. doi: 10.1029/2003GB002046.

73. Gilhespy S.L., Anthony S., Cardenas L., Chadwick D., del Prado A., Li C., Misselbrook T., Rees R.M., Salas W., Sanz-Cobena A., Smith P., Tilston E.L., Topp C.F.E., Vetter S., Yeluripati J.B. First 20 years of DNDC (DeNitrification DeComposition): Model evolution. Ecol. Modell., 2014, vol. 292, pp. 51-62. doi: 10.1016/j. ecolmodel.2014.09.004.

74. Ceglar A., Kajfez-Bogataj L.Simulation of maize yield in current and changed climatic conditions: Addressing modelling uncertainties and the importance of bias correction in climate model simulations. Eur. J. Agron., 2012, vol. 37, no. 1, pp. 83-95. doi: 10.1016/j.eja.2011.11.005.

75. Tazhibayeva K., Townsend R. The Impact of Climate Change on Rice Yields: Heterogeneity and Uncertainty: Working Paper. Cambridge, 2012. 47 p. Available at: http://www.robertmtownsend.net/ sites/default/files/files/papers/working_papers/ImpactofClimateChangeonRiceYieldsDec2012.pdf.

76. Sukhoveeva O.E., Karelin D.V. Parametrization of the DNDC model for evaluating components of the carbon biogeochemical cycle in the European part of Russia. Vestn. S.-Peterb. Univ. Nauki Zemle, 2019, vol. 64, no. 2, pp. 363-384. doi: 10.21638/spbu07.2019.211. (In Russian)

77. Mьller C., Bondeau A., Popp A., Waha K., Fader M. Climate Change Impacts on Agricultural Yields: Background Note to the World Development Report. Washington, DC, World Bank, 2010. 12 p. Available at: https://openknowledge.worldbank.org/handle/10986/9065.

78. Cantelaube P., Terres J.M. Seasonal weather forecasts for crop yield modeling in Europe. Tellus, 2005, vol. 57, no. 3, pp. 476-487.

79. Oettli P., Sultan B., Baron C., Vrac M. Are regional climate models relevant for crop yield prediction in West Africa? Environ. Res. Lett., 2011, vol. 6, no. 1, art. 014008, pp. 1-9. doi: 10.1088/1748-9326/6/1/014008.

80. Sukhoveeva O.E. Evaluation of spatiotemporal variability of CO2 fluxes in agrolandscapes of the European Russia using simulation modelling. Extended Abstract of Cand. Geogr. Sci. Diss. Moscow, 2018. 27 p. (In Russian)

81. Zamolodchikov D.G., Karelin D.V., Gitarskii M.L., Blinov V.G. (Eds.) Monitoring potokov par- nikovykh gazov v prirodnykh ekosistemakh [Monitoring Greenhouse Gases Fluxes in Natural Ecosystems]. Saratov, Amirit, 2017. 279 p. (In Russian)

82. Tarko A.M. Antropogennye izmeneniya global'nykh biosfernykh protsessov. Matematicheskoe modelirovanie [Anthropogenic Changes in Global Biospheric Processes. Mathematical Modelling]. Moscow, Fizmatlit, 2005. 232 p. (In Russian)

83. Davidson Е.А., Janssens I.A., Luo Y. On the variability of respiration in terrestrial ecosystems: moving beyond Q10. Global Change Biol., 2006, vol. 12, no. 2, pp. 154-164. doi: 10.1111/j.1365- 2486.2005.01065.x.

84. Alekseeva A.A., Fomina N.V. Analysis of the reducing enzyme activity of agrogenically disturbed soils in the nursery forests of the forest-steppe zone of the Krasnoyarsk region. Vestn. Krasnoyarsk. Gos. Agrar. Univ., 2015, no. 1, pp. 32-35. (In Russian)

85. Kirschbaum M.U.F., Mueller R. Net Ecosystem Exchange. Australia, Coop. Res. Cent. Greenhouse Account., 2001. 139 p.

86. Zadorozhnyi A.N., Semenov M.V., Khodzhaeva A.K., Semenov V.M. Soil processes of production, consumption, and emission of greenhouse gases. Agrokhimiya, 2010, no. 10, pp. 75-92. (In Russian)

87. WMO Greenhouse Gas Bulletin. WMO, 2012, no. 8: The state of greenhouse gases in the atmosphere based on global observations through 2011. 8 p.

88. Khain V.E., Khalilov E.N. Global'nye izmeneniya klimata i tsiklichnost' vulkanicheskoi aktivnosti [Global Climate Changes and Volcanic Activity Cycles]. Burgas, Bulgaria, SWB, 2008. 301 p. (In Russian)

89. WMO Greenhouse Gas Bulletin. WMO, 2011, no. 7: The state of greenhouse gases in the atmosphere based on global observations through 2010. 8p.

90. WMO Greenhouse Gas Bulletin. WMO, 2018, no. 14: The state of greenhouse gases in the atmosphere based on global observations through 2017. 8 p.

91. Zavarzin G.A., Vasil'eva L.V. Methane cycle in the territory of Russia. In: Laverov N.P., Zavarzin G.A. (Eds.) Krugovorot ugleroda na territorii Rossii [Carbon Cycle in the Territory of Russia]. Moscow, 1999, pp. 202-230. (In Russian)

92. Glagolev M.V. Annotated list of literature sources on the results of CH4 and CO2 flux measurements in Russian marshlands. Din. Okruzh. Sredy Global'nye Izmen. Klim., 2010, vol. 1, no. 2, pp. 1-53. (In Russian)

93. Miltner A., Kopinke F.D., Kindler R., Selesi D., Hartmann A., Kдstner M. Non-phototrophic CO2 fixation by soil microorganisms. Plant Soil, 2005, vol. 269, nos. 1-2, pp. 193-203. doi: 10.1007/s11104-004-0483-1.

94. Santruckovв H., Bird M.I., Elhottova D., Novak J., 31. Picek T., Simek M., Tykva R. Hetero- trophic fixation of CO2 in soil. Microb. Ecol., 2005, vol. 49, no. 2, pp. 218-225.

95. Smagin A.V. The gas function of soils. Eurasian Soil Sci., 2000, vol. 33, no. 10, pp. 1061-1071.

96. Shimmel S.M. Dark fixation of carbon dioxide in an agricultural soil. Soil Sci., 1987, vol. 144, no. 1, pp. 20-23.

97. Abohassan R.A. Carbon dynamics in a temperate agroforestry system in Southern Ontario, Canada. PhD Thesis. Guelph, Canada, Univ. of Guelph, 2004. 122 p.

98. Le Mer J., Roger P. Production, oxidation, emission and consumption of methane by soils: A review. Eur. J. Soil Biol., 2001, vol. 37, no. 1, pp. 25-50. doi: 10.1016/S1164-5563(01)01067-6.

99. Kammann C., Hepp S., Lenhart K., Mьller C. Stimulation of methane consumption by endogenous CH4 production in aerobic grassland soil. Soil Biol. Biochem., 2009, vol. 41, no. 3, pp. 622-629. doi: 10.1016/j.soilbio.2008.12.025.

100. Eliseev A.V., Mokhov I.I. Carbon cycle - climate feedback sensitivity to parameter changes of a zero-dimensional terrestrial carbon cycle scheme in a climate model of intermediate complexity. Theor. Appl. Climatol., 2007, vol. 89, nos. 1-2, p. 9-24. doi: 10.1007/s00704-006-0260-6.

101. McGuire A.D., Sitch S., Clein J.S., Dargaville R., Esser G., Foley J., Heimann M., Joos F., Kaplan J., Kicklighter D.W., Meier R.A., Melillo J.M., Moore III B., Prentice I.C., Ramankutty N., Reichenau T., Schloss A., Tian H., Williams L.J., Wittenberg U. Carbon balance of the terrestrial biosphere in the twentieth century: analyses of CO2, climate and land use effects with four process-based ecosystem models. GlobalBiogeochem. Cycles, 2001, vol. 15, pp. 183-206. doi: 10.1029/2000GB001298.

102. Zavalishin N.N. Dynamic compartment approach for modeling regimes of carbon cycle functioning in bog ecosystems. Ecol. Modell., 2008, vol. 213, no. 1, pp. 16-32. doi: 10.1016/j.ecolmodel.2007.12.006.

103. Komarov A.S., Priputina I.V., Mikhailov A.V., Chertov O.G. Carbon biogeochemical cycle in forest ecosystems of the central part of European Russia and its anthropogenic changes. In: Pochvennye protsessy iprostranstvenno-vremennaya organizatsiya pochv [Soil Processes and Spatiotemporal Organization of Soils]. Kudeyarov V.N. (Ed.). Moscow, Nauka, 2006. pp. 362-377. (In Russian)

104. Golubyatnikov L.L., Mokhov I.I., Eliseev A.V. Nitrogen cycle in the earth climatic system and its modeling. Izv., Atmos. OceanicPhys., 2013, vol. 49, no. 3, pp. 229-243. doi: 10.1134/S0001433813030079.

105. Elzen M.G.J., Beusen A.H.W., Rotmans J. An integrated modeling approach to global carbon and nitrogen cycles: Balancing their budgets. Global Biogeochem. Cycles, 1997, vol. 11, no. 2, pp. 191215. doi: 10.1029/96GB03938.

106. Bazilevich N.I., Titlyanova A.A. Bioticheskii krugovorot na pyati kontinentakh: azot i zol'nye elementy v prirodnykh nazemnykh ekosistemakh [Biotic Turnover on Five Continents: Nitrogen and Ash Elements in Natural Terrestrial Ecosystems]. Novosibirsk, Izd. Sib. Otd. Ross. Akad. Nauk,

2008. 381 p. (In Russian)

107. Thornton P.E., Lamarque J.F., Rosenbloom N.A., Mahowald N.M. Influence of carbon-nitrogen cycle coupling on land model response to CO2 fertilization and climate variability. Global Biogeo- chem. Cycles, 2007, vol. 21, no. 4, art. GB4018, pp. 1-15. doi: 10.1029/2006GB002868.

108. Gerber S., Hedin L.O., Oppenheimer M., Pacala S.W., Shevliakova E. Nitrogen cycling and feedbacks in a global dynamic land model. Global Biogeochem. Cycles, 2010, vol. 24, no. 1, art. GB1001, pp. 1-15. doi: 10.1029/2008GB003336.

109. Jain A., Yang X., Kheshgi H., McGuire A.D., Post W., Kicklighter D. Nitrogen attenuation of terrestrial carbon cycle response to global environmental factors. Global Biogeochem. Cycles,

2009, vol. 23, no. 4, art. GB4028, pp. 1-13. doi: 10.1029/2009GB003474.

110. Thornton P.E., Doney S.C., Lindsay K., Moore J.K., Mahowald N., Randerson J.T., Fung I., Lamarque J.F., Feddema J.J., Lee Y.H. Carbon-nitrogen interactions regulate climate-carbon cycle feedbacks: results from an atmosphere-ocean general circulation model. Biogeosciences, 2009, vol. 6, no. 10, pp. 2099-2120. doi: 10.5194/bg-6-2099-2009.

111. Titlyanova A.A., Chuprova V.V. Changes in the carbon cycle as related to different land use practices (case studies in Krasnoyarsk region). Eurasian Soil Sci., 2003, vol. 36, no. 2, pp. 201-208.

112. Ganzhara N.F., Borisov B.A. Gumusoobrazovanie i agronomicheskaya otsenka organicheskogo veshchestvapochv [Humus Formation and Agronomic Assessment of Soil Organic Matter]. Moscow, Agrokonsalt, 1997. 82 p. (In Russian)

113. Gougoulias C., Clark J.M., Shaw L.J. The role of soil microbes in the global carbon cycle: tracking the below-ground microbial processing of plant-derived carbon for manipulating carbon dynamics in agricultural systems. J. Sci. FoodAgric., 2014, vol. 94, no. 12, pp. 2362-2371. doi: 10.1002/jsfa.6577.

114. Lopes de Gerenyu V.O., Kurganova I.N., Ermolaev A.M., Kuzyakov Ya.V. Changes in soil organic carbon pools during the self-restoration of arable soils. Agrokhimiya, 2009, no. 5, pp. 5-12. (In Russian)

115. Degtyarev V.V., Panasenko O.S., Nedbaev V.N. Content of humus colloidal particles in structural aggregates of chernozems typical for different forest-steppe conditions of Ukraine. Vestn. Kursk. Gos. S-kh. Akad., 2013, no. 5, pp. 60-62. (In Russian)

116. Chuprova V.V. Mineralized pool of organic matter in agrochernozems of the southern part of Central Siberia. Vestn. Krasnoyarsk. Gos. Agrar. Univ., 2013, no. 9, pp. 83-89. (In Russian)

117. Sharkov I.N., Samokhvalova L.M., Mishina P.V., Shepelev A.G. Effect of crop residues on the organic matter composition of a leached chernozem in the Western Siberian forest-steppe. Eurasian Soil Sci., 2014, vol. 47, no. 4, pp. 304-309. doi: 10.1134/S1064229314040085.

118. Kuznetsova T.V., Udaltsov S.N., Demkin V.A. Active organic matter mineralization in modern and buried chestnut soils of the dry steppe zone. Vestn. Tambov. Univ. Ser. Estestv. Nauki, 2013, vol. 18, no. 3, pp. 978-981. (In Russian)

119. Kogut B.M., Yashin M.A., Semenov V.M., Avdeeva T.N., Markina L.G., Lukin S.M., Tarasov S.I. Distribution of transformed organic matter in structural units of loamy sandy soddy-podzolic soil. Eurasian Soil Sci., 2016, vol. 49, no. 1, pp. 45-55. doi: 10.1134/S1064229316010075.

120. Tsybul'ko N.N., Shapsheeva T.P., Arastovich T.V., Zaitsev A.A. Mineralization capacity of organic matter in peat soils and 137Cs efflux into perennial grasses. Melioratsiya, 2010, no. 2, pp. 109-122. (In Russian)

121. Muller T., Hoper H. Soil organic matter turnover as a function of the soil clay content: Consequences for model application. Soil Biol. Biochem., 2004, vol. 36, no. 6, pp. 877-888. doi: 10.1016/j. soilbio .2003.12.015.

122. Schwendenmann L., Pendal E. Response of organic matter dynamics to conversion from tropical forest to grassland as determined by long-term incubation. Biol. Fertil. Soils, 2008, vol. 44, no. 8, pp. 1053-1062. doi: 10.1007/s00374-008-0294-2.

123. Ivanov I.V., Pesochina L.S., Semenov V.M. Biological mineralization of organic matter in the modern virgin and plowed chernozems, buried chernozems, and fossil chernozems. Eurasian Soil Sci., 2009, vol. 42, no. 10, pp. 1109-1119. doi: 10.1134/S1064229309100056.

124. Bond-Lamberty B., Thompson A. Temperature associated increases in the global soil respiration record. Nature, 2010, vol. 464, pp. 579-582. doi: 10.1038/nature08930.

125. Kuzyakov Y. Sources of CO2 efflux from soil and review of partitioning methods. Soil Biol. Biochem., 2006, vol. 38, no. 3, p. 425-448. doi: 10.1016/j.soilbio.2005.08.020.

126. Luo Y., Zhou X. Soil Respiration and the Environment. Burlington, Acad. Press, 2006. 316 p.

127. Raich J.W., Potter C.S., Bhagawatti D. Interannual variability in global soil respiration, 1980-94. Global Change Biol., 2002, vol. 8, no. 8, pp. 800-812. doi: 10.1046/j.1365-2486.2002.00511.x.

128. Stepanov A.L. Mikrobnaya transformatsiya parnikovykh gazov v pochvakh [Microbial Transformation of Greenhouse Gases in Soils]. Moscow, GEOS, 2011. 192 p. (In Russian)

129. Bardgett R.D. Plant-soil interactions in a changing world. Biol. Rep., 2011, vol. 3, art. 16, pp. 1-6. doi: 10.3410/B3-16.

130. Larionova A.A., Sapronov D.V., Lopez de Gerenyu V.O., Kuznetsova L.G., Kudeyarov V.N. Contribution of plant root respiration to the CO2 emission from soil. Eurasian Soil Sci., 2006, vol. 39, no. 10, pp. 1127-1135. doi: 10.1134/S1064229306100103.

131. Zavarzin G.A., Kudeyarov V.N. Soil as the main source of carbon dioxide and a pool of organic carbon in the territory of Russia. Vestn. Ross. Akad. Nauk, 2006, vol. 76, no. 1, pp. 14-29 (In Russian)

132. Sapronov D.V., Kuzyakov Ya.V. Separation of root and microbial respiration: Comparison of three methods. Eurasian Soil Sci., 2007, vol. 40, no. 7, pp. 775-784. doi: 10.1134/S1064229307070101.

133. Kuzyakov Ya.V., Larionova A.A. Contribution of rhizomicrobial and root respiration to the CO2 emission from soil (A review). Eurasian Soil Sci., 2006, vol. 39, no. 7, pp. 753-764. doi: 10.1134/S106422930607009X.

134. Kurganova I.N. Emission and balance of carbon dioxide in terrestrial ecosystems of Russia. Extended Abstract of Doct. Biol. Sci. Diss. Pushchino, 2010. 48 p. (In Russian)

135. Yevdokimov I.V., Larionova A.A., Lopes de Gerenyu V.O., Schmitt M., Bahn M. Determination of root and microbial contributions to the CO2 emission from soil by the substrate-induced respiration method. Eurasian Soil Sci., 2010, vol. 43, no. 3, pp. 321-327. doi: 10.1134/S 1064229310030105.

136. Hanson P.J., Edwards N.T., Garten C.T., Andrews J.A. Separating root and soil microbial contributions to soil respiration: A review of methods and observations. Biogeochemistry, 2000, vol. 48, no. 1, pp. 115-146. doi: 10.1023/A:1006244819642.

137. Larionova A.A., Yevdokimov I.V., Kurganova I.N., Sapronov D.V., Kuznetsova L.G., Lopes de Gerenju V.O. Root respiration and its contribution to the CO2 emission from soil. Eurasian Soil Sci., 2003, vol. 36, no. 2, pp. 173-184.

138. Sun W.J., Huang Y., Chen S.T., Yang Z.F., Zheng X.H. CO2 emission from soil-crop system as influenced by crop growth and tissue N content. Huan Jing Ke Xue, 2004, vol. 25, no. 3, pp. 1-6. (In Chinese)

139. Swinnen J. Evaluation of the use of a model rhizodeposition technique to separate root and microbial respiration in soil. Plant Soil, 1994, vol. 165, no. 1, pp. 89-101. doi: 10.1007/BF00009966.

140. Sapronov D.V. Long-term dynamics of CO2 emission from gray forest and sod-podzolic soils. Extended Abstract of Cand. Biol. Sci. Diss. Pushchino, 2008. 20 p. (In Russian)

141. Helal H.M., Sauerbeck D. Short term determination of the actual respiration rate of intact plant roots. In: McMichal B.L., Person H. (Eds.) Plant Roots and Their Environment. Amsterdam, Elsevier, 1991. pp. 88-92.

142. Yevdokimov I.V., Ruser R., Buegger F., Marx M., Munch J.C. Carbon turnover in the rhizosphere under continuous plant labeling with 13CO2: Partitioning of root, microbial, and rhizomicrobial respiration. Eurasian Soil Sci., 2007, vol. 40, no. 9, pp. 969-977. doi: 10.1134/S1064229307090074.

143. Da Costa J.M.N. Respiratory releases of carbon dioxide by aerial parts and roots of field-grown alfalfa and soybeans. PhD Thesis. Lincoln, Univ. of Nebraska, 1983. 125 p.

144. Biasi C., Pitkamaki A.S., Tavi N.M., Koponen H.T., Martikainen P.J. An isotope approach based on 13C pulse-chase labelling vs. the root trenching method to separate heterotrophic and autotrophic respiration in cultivated peatlands. Boreal Environ. Res., 2012, vol. 17, nos. 3-4, pp. 184-192.

145. Orlova O.V. Active organic matter as a regulator of nitrogen and carbon transformation processes in sod-podzolic soils. Extended Abstract of Doct. Biol. Sci. Diss. St. Petersburg, 2013. 48 p. (In Russian)

146. Karelin D.V., Zamolodchikov D.G., Pochikalov A.V., Kaganov V.V., Gitarskii M.L. Microbial and root components of respiration of sod-podzolic soils in boreal forest. Contemp. Probl. Ecol., 2017, vol. 10, no. 7, pp. 717-727. doi: 10.1134/S199542551707006X.

147. Suleau M., Moureaux C., Dufranne D., Buysse P., Bodson B., Destain J.P., Heinesch B., Debacq A., Aubinet M. Respiration of three Belgian crops: Partitioning of total ecosystem respiration in its heterotrophic, above- and below-ground autotrophic components. Agric. For. Meteorol., 2011, vol. 151, no. 5, pp. 633-643. doi: 10.1016/j.agrformet.2011.01.012.

148. Sadras V.O., Calderini D. Crop Physiology: Application for Genetic Improvements and Agronomy. Burlington, MA, USA, Acad. Press, 2009. 581 p.

Размещено на Allbest.ru

...