水保所知识产出(1956---)知识库

Although forests account for only 27% of the total land area, they store approximately 80% of the aboveground
carbon (C) and 40% of soil C globally. However, there is currently little information regarding the input and
distribution of photoassimilates of trees in plant–soil systems. To quantify the belowground C input and allo-
cation to plant–soil pools, we pulse labeled 5-year-old pioneer (Populus davidiana) and climax (Quercus
wutaishanica) species with 13 CO 2 under field conditions. The 13 C allocation dynamics were traced in the leaves,
branches, roots, and soil microorganisms, rhizosphere and bulk soil under Populus davidiana and Quercus
wutaishanica over 21 days. 13 C recovery (% of assimilated 13 C) in the leaves of Populus davidiana and Quercus
wutaishanica decreased from nearly 90% at 6 h after labeling to 40% and 45% at 21 days, respectively.
Continuous assimilate allocation from above- to belowground increased 13 C recovery in roots from 0.4% at 6 h
after labeling to 9.5% in Populus davidiana and from 1.5% to 15% in Quercus wutaishanica at 21 days after la-
beling. The recently assimilated C was detected in the soil immediately after labeling. The 13 C amounts in the
bulk and rhizosphere soil of the climax species Quercus wutaishanica was two-fold greater than that under the
pioneer species Populus davidiana. The total belowground net C input (including that in roots) by Populus
davidiana and Quercus wutaishanica was 109 and 283 g C m −2 yr −1 (top 20 cm of soil), respectively, including
rhizodeposition of 4.2 and 28 g C m −2 yr −1 . Consequently, the belowground C allocation and soil C sequestration
increase from pioneer to climax tree species.