Biogeosciences www.biogeosciences.net 1726-4170 1726-4189 6 9 2009 10.5194/bg-6-1849-2009 http://www.biogeosciences.net/6/1849/2009/ http://www.biogeosciences.net/6/1849/2009/bg-6-1849-2009.html http://www.biogeosciences.net/6/1849/2009/bg-6-1849-2009.pdf 1849 1864 2009-09-02 Forest floor carbon exchange of a boreal black spruce forest in eastern North America O. Bergeron onil.bergeron@mcgill.ca H. A. Margolis C. Coursolle Centre d'étude de la forêt, Faculté de foresterie, de géographie et de géomatique, Université Laval, Québec, Québec, Canada now at: Department of Natural Resource Sciences, McGill University, Montréal, Québec, Canada This study reports continuous automated measurements of forest floor carbon (C) exchange over feathermoss, lichen, and sphagnum micro-sites in a black spruce forest in eastern North America during snow-free periods over three years. The response of soil respiration (<i>R_s-</i>auto) and forest floor photosynthesis (<i>P_ff</i>) to environmental factors was determined. The seasonal contributions of scaled up <i>R_s-</i>auto adjusted for spatial representativeness (<i>R_s-</i>adj) and <i>P_ff</i> (<i>P_ff</i>-eco) relative to that of total ecosystem respiration (<i>R_e</i>) and photosynthesis (<i>P</i>_eco), respectively, were also quantified. <br><br> Shallow (5 cm) soil temperature explained 67–86% of the variation in <i>R_s-</i>auto for all ground cover types, while deeper (50 and 100 cm) soil temperatures were related to <i>R_s-</i>auto only for the feathermoss micro-sites. Base respiration was consistently lower under feathermoss, intermediate under sphagnum, and higher under lichen during all three years. The <i>R_s-</i>adj/<i>R_e</i> ratio increased from spring through autumn and ranged from 0.85 to 0.87 annually for the snow-free period. The <i>R_s-</i>adj/<i>R_e</i> ratio was negatively correlated with the difference between air and shallow soil temperature and this correlation was more pronounced in autumn than summer and spring. <br><br> Maximum photosynthetic capacity of the forest floor (<i>P_ff</i>-max) saturated at low irradiance levels (~200 μmol m^&minus;2 s^&minus;1) and decreased with increasing air temperature and vapor pressure deficit for all three ground cover types, suggesting that <i>P_ff</i> was more limited by desiccation than by light availability. <i>P_ff</i>-max was lowest for sphagnum, intermediate for feathermoss, and highest for lichen for two of the three years. <i>P_ff</i> normalized for light peaked at air temperatures of 5–8&deg;C, suggesting that this is the optimal temperature range for <i>P_ff</i>. The <i>P_ff</i>-eco/<i>P</i>_eco ratio varied from 13 to 24% over the snow-free period and reached a minimum in mid-summer when both air temperature and <i>P</i>_eco were at their maximum. 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