Page 137 - 《广西植物》2026年第2期
P. 137

2 期           杨帆等: 增温对川西亚高山冷杉林凋落叶分解过程中有机碳含量的短期影响                                            3 3 1

               (2): 269-275. [孟凡栋ꎬ 汪诗平ꎬ 白玲ꎬ 2014. 青藏高原         XU Sꎬ OU Jꎬ QIAO X Xꎬ et al.ꎬ 2024. Experimental warming
               气候变化与高寒草地 [J]. 广西植物ꎬ 34(2): 269-275.]             affects soil carbon dynamics in boreal and temperate forests:
            OSONO Tꎬ TAKEDA Hꎬ 2006. Fungal decomposition of Abies  a meta ̄analysis [ J ]. Environmental Research Lettersꎬ
               needle and Betula leaf litter [ J]. Mycologiaꎬ 98(2):  19(10): 103002.
               172-179.                                        XU Z Fꎬ PU X Zꎬ YIN H Jꎬ et al.ꎬ 2010a. Warming effects on
            OUYANG Wꎬ WU Z Sꎬ CUI X Tꎬ et al.ꎬ 2022. Forest leaf litter  the early decomposition of three litter typesꎬ Eastern Tibetan
               nutrient discharge patterns in snowmelt surface runoff and  Plateauꎬ China [ J]. European Journal of Soil Scienceꎬ
               watershed scale remote sensed simulation [J]. Science of the  63(3): 360-367.
               Total Environmentꎬ 839: 156356.                 XU Z Fꎬ WAN Cꎬ XIONG Pꎬ et al.ꎬ 2010b. Initial responses of
            PRIETO Iꎬ ALMAGRO Mꎬ BASTIDA Fꎬ et al.ꎬ 2019. Altered  soil CO efflux and Cꎬ N pools to experimental warming in
                                                                      2
               leaf litter quality exacerbates the negative impact of climate  two contrasting forest ecosystemsꎬ Eastern Tibetan Plateauꎬ
               change on decomposition [J]. Journal of Ecologyꎬ 107(5):  China [J]. Plant and Soilꎬ 336(1/ 2): 183-195.
               2364-2382.                                      YANG Fꎬ NI X Yꎬ ZENG Xꎬ et al.ꎬ 2021. Short ̄term winter
            SANG C Pꎬ XIA Z Wꎬ SUN L Fꎬ et al.ꎬ 2021. Responses of  snow reduction stimulates soil nutrient leaching without
               soil microbial communities to freeze - thaw cycles in a  changing the microbial biomass in an alpine fir forest
               Chinese temperate forest [J]. Ecological Processesꎬ 10: 66.  [J]. Global Ecology and Conservationꎬ 25: e01434.
            SCHNEIDER Tꎬ KEIBLINGER K Mꎬ SCHMID Eꎬ et al.ꎬ     YANG W Qꎬ WU F Zꎬ TAN Bꎬ et al.ꎬ 2021. Ecosystem
               2012. Who is who in litter decomposition? Metaproteomics  processes and management of the subalpine coniferous forest
               reveals major microbial players and their biogeochemical  in the upper reaches of the Yangtze River [ M]. Beijing:
               functions [J]. The ISME Journalꎬ 6(9): 1749-1762.  Science Press. [杨万勤ꎬ 吴福忠ꎬ 谭波ꎬ 等ꎬ 2021. 长江上
            SIERRA C Aꎬ TRUMBORE S Eꎬ DAVIDSON E Aꎬ et al.ꎬ      游亚高山针叶林生态系统过程与管理 [M]. 北京: 科学
               2015. Sensitivity of decomposition rates of soil organic matter  出版社.]
               with respect to simultaneous changes in temperature and  YIN Rꎬ QIN W Kꎬ WANG X Dꎬ et al.ꎬ 2023. Warmer
               moisture [ J ]. Journal of Advances in Modeling Earth  temperature promotes the contribution of invertebrate fauna to
               Systemsꎬ 7(1): 335-356.                           litter components release in an alpine meadow on the
            SUN Bꎬ 2024. Research on the effects of global warming on  Qinghai ̄Tibetan Plateau [J]. Catenaꎬ 231: 107334.
               forest litter decomposition [J]. Applied and Computational  YUE Kꎬ PENG C Hꎬ YANG W Qꎬ et al.ꎬ 2015. Study type and
               Engineeringꎬ 59(1): 9-13.                         plant litter identity modulating the response of litter
            TENENHAUS Mꎬ VINZI V Eꎬ CHATELIN Y Mꎬ et al.ꎬ        decomposition to warmingꎬ elevated CO ꎬ and elevated O :
                                                                                              2            3
               2025. PLS path modeling [ J]. Computational Statistics &  A meta ̄analysis [ J ]. Journal of Geophysical Research:
               Data Analysisꎬ 48(1): 159-205.                    Biogeosciencesꎬ 120(3): 441-451.
            VENABLES W Nꎬ RIPLEY B Dꎬ VENABLES W Nꎬ 2002.      YUE Kꎬ YANG W Qꎬ PENG C Hꎬ et al.ꎬ 2016. Foliar litter
               Modern applied statistics with S [M]. 4th ed. New York:  decomposition in an alpine forest meta ̄ecosystem on the
               Springer.                                         eastern Tibetan Plateau [ J ]. Science of the Total
            WANG Hꎬ LIU S Rꎬ WANG J Xꎬ et al.ꎬ 2013. Dynamics and  Environmentꎬ 566/ 567: 279-287.
               speciation of organic carbon during decomposition of leaf  ZHANG Fꎬ FENG Y Hꎬ SONG S Sꎬ et al.ꎬ 2021. Temperature
               litter and fine roots in four subtropical plantations of China  sensitivity of plant litter decomposition rate in China’ s
               [J]. Forest Ecology and Managementꎬ 300: 43-52.   forests [J]. Ecosphereꎬ 12(6): e03541.
            WICKHAM Hꎬ 2016. ggplot2: Elegant graphics for data analysis  ZHANG L Xꎬ GUO W Jꎬ CHEN Y Lꎬ et al.ꎬ 2024. Simulated
               [M]. Berlin: Springer Nature.                     warming increases litter decomposition and release rates of
            WIEDER W Rꎬ CLEVELAND C Cꎬ TOWNSEND A Rꎬ             some metallic elements and recalcitrant components in
               2009. Controls over leaf litter decomposition in wet tropical  different ̄aged Chinese  fir  plantations [ J ].  Forestsꎬ
               forests [J]. Ecologyꎬ 90(12): 3333-3341.          15(12): 2151.
            WU Qꎬ NI X Yꎬ SUN Xꎬ et al.ꎬ 2025. Substrate and climate
               determine terrestrial litter decomposition [J]. Proceedings of               (责任编辑  邓斯丽)
               the National Academy of Sciencesꎬ 122(7): e2420664122.
   132   133   134   135   136   137   138   139   140   141   142