Carbon dioxide efflux density from the floor of a central Siberian pine forest

Total and forest floor carbon dioxide flux densities ( F CO 2 ) and environmental variables were measured for 18 consecutive mid-summer days during July 1996 in a 215-year-old stand of Pinus sylvestris L. trees located 40 km southwest of the village of Zotino in central Siberia, Russia (61°N, 89°E,...

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Bibliographic Details
Published in:	Agricultural and forest meteorology Vol. 94; no. 3; pp. 217 - 232
Main Authors:	Kelliher, F.M., Lloyd, J., Arneth, A., Lühker, B., Byers, J.N., McSeveny, T.M., Milukova, I., Grigoriev, S., Panfyorov, M., Sogatchev, A., Varlargin, A., Ziegler, W., Bauer, G., Wong, S.-C., Schulze, E.-D.
Format:	Journal Article
Language:	English
Published:	Elsevier B.V 03-05-1999
Subjects:	AIR DU SOL AIRE DEL SUELO BOSQUE DE CONIFERAS CARBON DIOXIDE Carbon dioxide efflux CONIFEROUS FORESTS DIOXIDO DE CARBONO DIOXYDE DE CARBONE Eddy covariance FORET RESINEUSE LOSSES FROM SOIL PERDIDAS DESDE SUELOS PERTE DES LES SOLS PINUS SYLVESTRIS Pinus sylvestris forest Siberia SOIL AIR Soil water Zotino, Russian Federation in Asia Soil water Pinus sylvestris forest Eddy covariance Carbon dioxide efflux Siberia
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Summary:	Total and forest floor carbon dioxide flux densities ( F CO 2 ) and environmental variables were measured for 18 consecutive mid-summer days during July 1996 in a 215-year-old stand of Pinus sylvestris L. trees located 40 km southwest of the village of Zotino in central Siberia, Russia (61°N, 89°E, 160 m asl). Forest floor F CO 2 was regulated by surface soil water content, related to the limited storage capacity of the sandy soil equivalent to only 4 mm water per 100 mm depth of soil. Following 12 mm rainfall, forest floor F CO 2 increased by 52% to a maximum value of 4.1 μmol m −2 s −1. However, the rate had returned to the general lower level by the next day in response to rapid drying of the surface soil. There was little correspondence between forest floor F CO 2 and the distributions of root and soil carbon or soil temperature. However, for soil samples returned to the laboratory, sieved to remove roots and re-watered, microbial respiration rate was positively and exponentially related to temperature. Measurements of forest floor F CO 2 by eddy covariance were in good agreement with the chamber data during the daytime when the atmosphere was regularly mixed by turbulence. Micrometeorological flux measurements at the forest floor and above the trees showed how, on average, 77% of the carbon sequestered by tree canopy photosynthesis was lost to the atmosphere by root and soil microbial respiration during the observation period. On a daily basis, the boreal forest was generally a modest net sink (−75 mmol m −2 per day), but also a small carbon source on hot and dry days.
Bibliography:	1999004109 P40 F40 ObjectType-Article-2 SourceType-Scholarly Journals-1 ObjectType-Feature-1 content type line 23
ISSN:	0168-1923 1873-2240
DOI:	10.1016/S0168-1923(99)00014-3