Three-source partitioning of soil respiration by 13C natural abundance and its variation with soil depth in a plantation

Wenchen Song , Xiaojuan Tong , Jinsong Zhang , Ping Meng

Journal of Forestry Research ›› 2015, Vol. 27 ›› Issue (3) : 533 -540.

PDF
Journal of Forestry Research ›› 2015, Vol. 27 ›› Issue (3) : 533 -540. DOI: 10.1007/s11676-015-0206-x
Original Paper

Three-source partitioning of soil respiration by 13C natural abundance and its variation with soil depth in a plantation

Author information +
History +
PDF

Abstract

Partitioning soil respiration into three components is vital to identify CO2 sink or source and can help us better understand soil carbon dynamics. However, knowledge about the influences of soil depth and the priming effect on soil respiration components under field has been limited. Three components of soil respiration (root respiration, rhizomicrobial respiration and basal respiration) in a plantation in the hilly area of the North China were separated by the 13C natural abundance method. The results showed that the average proportions of rhizomicrobial respiration, root respiration and basal respiration at the 25–65 cm depths were about 14, 23 and 63 %, respectively. Three components of soil respiration varied with soil depth, and root respiration was the main component of soil respiration in deeper soil. The priming effect was obvious for the deep soil respiration, especially at the 40–50 cm depth. Thus, depth and priming effect should be taken into account to increase the accuracy of estimations of soil carbon flux.

Keywords

Soil respiration / Rhizosphere respiration / Rhizomicrobial respiration / Root respiration / 13C natural abundance / Soil depth

Cite this article

Download citation ▾
Wenchen Song, Xiaojuan Tong, Jinsong Zhang, Ping Meng. Three-source partitioning of soil respiration by 13C natural abundance and its variation with soil depth in a plantation. Journal of Forestry Research, 2015, 27(3): 533-540 DOI:10.1007/s11676-015-0206-x

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Atarashi-Andoh M, Koarashi J, Ishizuka S, Hirai K. Seasonal patterns and control factors of CO2 effluxes from surface litter, soil organic carbon, and root-derived carbon estimated using radiocarbon signatures. Agr For Meteorol, 2012, 152: 149-158.

[2]

Bengtson P, Barker J, Grayston SJ. Evidence of a strong coupling between root exudation, C and N availability, and stimulated SOM decomposition caused by rhizosphere priming effects. Ecol Evol, 2012, 2: 1843-1852.

[3]

Bowling DR, Pataki DE, Randerson JT. Carbon isotopes in terrestrial ecosystem pools and CO2 fluxes. New Phytol, 2008, 178: 24-40.

[4]

Brunn M, Spielvogel S, Sauer T, Oelmann Y. Temperature and precipitation effects on δ13C depth profiles in SOM under temperate beech forests. Geoderma, 2014, 235: 146-153.

[5]

De Graaff M-A, Jastrow JD, Gillette S, Johns A, Wullschleger SD. Differential priming of soil carbon driven by soil depth and root impacts on carbon availability. Soil Biol Biochem, 2014, 69: 147-156.

[6]

Ding P, Shen CD, Wang N, Yi WX, Ding XF, Fu DP, Liu KX, Zhao P. Carbon isotopic composition, turnover and origins of soil CO2 in a monsoon evergreen broad leaf forest in Dinghushan Biosphere Reservoir, South China. Chin Sci Bull, 2010, 55(9): 779-787.
[7]

Dixon RK, Solomon AM, Brown S, Houghton RA, Trexier MC, Wisniewski J. Carbon pools and flux of global forest ecosystems. Science, 1994, 263: 185-190.

[8]

Eilers KG, Debenport S, Anderson S, Fierer N. Digging deeper to find unique microbial communities: the strong effect of depth on the structure of bacterial and archaeal communities in soil. Soil Biol Biochem, 2012, 50: 58-65.

[9]

Fang JY, Guo ZD, Piao SL, Chen AP. Terrestrial vegetation carbon sinks in China, 1981-2000. Sci China Ser D, 2007, 50: 1341-1350.

[10]

Guo ZD, Hu HF, Li P, Li NY, Fang JY. Spatio-temporal changes in biomass carbon sinks in China’s forests from 1977 to 2008. Sci China Life Sci, 2013, 56: 661-671.

[11]

Högberg P, Read DJ. Towards a more plant physiological perspective on soil ecology. Trends Ecol Evol, 2006, 21: 548-554.

[12]

Huang Y, Sun WJ, Zhang W, Yu YQ. Changes in soil organic carbon of terrestrial ecosystems in China: a mini-review. Sci China Life Sci, 2010, 53: 766-775.

[13]

IPCC (2007) Climate change 2007: the physical science basis. Contribution of working group I to the fourth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge
[14]

Kelting DL, James AB, Gerry SE. Estimating root respiration, microbial respiration in the rhizosphere, and root- free soil respiration in forest soils. Soil Biol Biochem, 1998, 30(7): 961-968.

[15]

Kramer C, Gleixner G. Soil organic matter in soil depth profiles: distinct carbon preferences of microbial groups during carbon transformation. Soil Biol Biochem, 2008, 40: 425-433.

[16]

Kuzyakov Y. Separating microbial respiration of exudates from root respiration in non-sterile soils: a comparison of four methods. Soil Biol Biochem, 2002, 34: 1621-1631.

[17]

Kuzyakov Y. Theoretical background for partitioning of root and rhizomicrobial respiration by 13C of microbial biomass. Eur J Soil Biol, 2005, 41(1/2): 1-9.

[18]

Kuzyakov Y. Sources of CO2 efflux from soil and review of partitioning methods. Soil Biol Biochem, 2006, 38(3): 425-448.

[19]

Kuzyakov Y. Response to the comments by Peter Högberg, Nina Buchmann and David J. Read on the review “Sources of CO2 efflux from soil and review of partitioning methods”. Soil Biol Biochem, 2006, 38(9): 2999-3000.

[20]

Kuzyakov Y. Priming effects: interactions between living and dead organic matter. Soil Biol Biochem, 2010, 42: 1363-1371.

[21]

Kuzyakov Y, Larionova AA. Root and rhizomicrobial respiration: a review of approaches to estimate respiration by autotrophic and heterotrophic organisms in soil. J Plant Nutr Soil Sci, 2005, 168: 503-520.

[22]

Kuzyakov Y, Larionova AA. Contribution of rhizomicrobial and root respiration to the CO2 emission from soil (a review). Eurasian Soil Sci, 2006, 39(7): 753-764.

[23]

Kuzyakov Y, Xu X. Competition between roots and microorganisms for nitrogen: mechanisms and ecological relevance. New Phytol, 2013, 198: 656-669.

[24]

Li P, Yang Y, Fang J. Variations of root and heterotrophic respiration along environmental gradients in Chinas forests. J Plant Ecol, 2013, 6(5): 358-367.

[25]

Millard P, Midwood AJ, Hunt JE, Barbour MM, Whitehead D. Quantifying the contribution of soil organic matter turnover to forest soil respiration, using natural abundance δ13C. Soil Biol Biochem, 2010, 42: 935-943.

[26]

Nazzari M, Sciarra A, Quattrocchi F. A simple and sensitive gas chromatography–electron capture detection method for analyzing perfluorocarbon tracers in soil gas samples for storage of carbon dioxide. Int J Greenh Gas Con, 2013, 14: 60-64.

[27]

O’Leary MH. Carbon isotopes in photosynthesis. Bioscience, 1988, 38: 328-336.

[28]

Pan YD, Birdsey RA, Fang JY, Houghton R, Kauppi PE, Kurz WA, Phillips OL, Shvidenko A, Lewis SL, Canadell JG. A large and persistent carbon sink in the world’s forests. Science, 2011, 333: 988-993.

[29]

Pataki DE, Ehleringer JR, Flanagan LB, Yakir D, Bowling DR, Still CJ, Buchmann N, Kaplan JO, Berry JA. The application and interpretation of Keeling plots in terrestrial carbon cycle research. Glob Biogeochem Cycles, 2003, 17 1 1022

[30]

Pausch J, Kuzyakov Y. Soil organic carbon decomposition from recently added and older sources estimated by δ13C values of CO2 and organic matter. Soil Biol Biochem, 2012, 55: 40-47.

[31]

Pinheiro EAR, Costa CAG, de Araujo JC (2013) Effective root depth of the Caatinga biome. J Arid Environ 89:1–4
[32]

Phillips DL, Gregg JW. Uncertainty in source partitioning using stable isotopes. Oecologia, 2001, 127: 171-179.

[33]

Posada RH, Madrinan S, Rivera EL. Relationships between the litter colonization by saprotrophic and arbuscular mycorrhizal fungi with depth in a tropical forest. Fungal Biol, 2012, 116: 747-755.

[34]

Susfalk RB, Cheng WX, Johnson DW, Walker RF, Verburg P, Fu S. Lateral diffusion and atmospheric CO2 mixing compromise estimates of rhizosphere respiration in a forest soil. Can J For Res, 2002, 32: 1005-1015.

[35]

Tefs C, Gleixner G. Importance of root derived carbon for soil organic matter storage in a temperate old-growth beech forest—evidence from C, N and 14C content. For Ecol Manag, 2012, 263: 131-137.

[36]

Wang CK, Yang JY. Rhizospheric and heterotrophic components of soil respiration in six Chinese temperate forests. Glob Change Biol, 2007, 13: 123-131.

[37]

Wang WJ, Wang HM, Zu YG. Temporal changes in SOM, N, P, K, and their stoichiometric ratios during reforestation in China and interactions with soil depths: importance of deep-layer soil and management implications. For Ecol Manag, 2014, 325: 8-17.

[38]

Werth M, Kuzyakov Y. Three-source partitioning of CO2 efflux from maize field soil by 13C natural abundance. J Plant Nutr Soil Sci, 2009, 172: 487-499.

[39]

Werth M, Subbotina I, Kuzyakov Y. Three-source partitioning of CO2 efflux from soil planted with maize by 13C natural abundance fails due to inactive microbial biomass. Soil Biol Biochem, 2006, 38: 2772-2781.

[40]

Wynn JG, Harden JW, Fries TL. Stable carbon isotope depth profiles and soil organic carbon dynamics in the lower Mississippi Basin. Geoderma, 2006, 131: 89-109.

[41]

Zhao N, Meng P, Zhang JS, Lu S, Cheng ZQ. Comparison of soil respiration under various land uses in hilly area of Northern China. Sci Silv Sin, 2014, 50(2): 1-7. in Chinese, Abstract in English
AI Summary AI Mindmap
PDF

178

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/