%0 Journal Article %A ZHANG Xin %A XING Ya-Juan %A YAN Guo-Yong %A WANG Qing-Gui %T Response of fine roots to precipitation change: A meta-analysis %D 2018 %R 10.17521/cjpe.2017.0203 %J Chinese Journal of Plant Ecology %P 164-172 %V 42 %N 2 %X

Aims The response of fine roots to soil moisture is very sensitive. Climate change scenarios predict changes in precipitation which influence soil moisture directly. Plants optimize resource acquisition by fine root morphological plasticity and biomass redistribution when soil moisture changes. Therefore, it is important to study the effect of precipitation increase and decrease on fine roots and reveal the response of ecosystem carbon cycling to global climate change.

Methods We collected 202 sets of data from 48 published domestic and foreign articles, and analized the responses of fine root biomass, production, turnover, root length density, specific root length and soil microbial biomass carbon which reflects fine root decomposition dynamic to precipitation change by the meta-analysis. RR++ (weighted response ratio) was used to quantify the effect size of the response of fine roots to precipitation change.

Important findings (1) The significance and magnitude of the precipitation effects on fine roots varied among plant types. Shrub fine roots had stronger response than tree fine roots. (2) The response of fine roots differed across soil depth. Fine root had most significant responses when the precipitation increased or decreased 50%. A 50% increase in precipitation had a significant positive impact on both fine root biomass in 20-40 cm soil and specific root length in 0-10 cm soil depth. A 50% decreased in precipitation had a significant negative impact on fine root production in 20-40 cm soil but positive impact on root length density in 0-10 cm soil. (3) The duration of experiment affected the response of fine roots, fine roots responded to precipitation changes (increase and decrease) by morphological plasticity in short-term experiments, and by biomass redistribution in long-term experiments. (4) Increasing precipitation contributed to the nutrient release of fine roots, because soil microbes accelerated the decomposability of fine roots due to sufficient substrate resources stimulated their own activity.

%U https://www.plant-ecology.com/EN/10.17521/cjpe.2017.0203