植物质量、模拟增温及生境对凋落物分解的相对贡献

doi:10.13287/j.1001-9332.201802.002

应用生态学报 ›› 2018, Vol. 29 ›› Issue (2): 474-482.doi: 10.13287/j.1001-9332.201802.002

植物质量、模拟增温及生境对凋落物分解的相对贡献

王行^1,2, 闫鹏飞¹, 展鹏飞¹, 张晓宁¹, 刘振亚¹, 郭玉静¹, 肖德荣^1*

¹西南林业大学国家高原湿地研究中心/湿地学院, 昆明 650224;
²浙江大学环境与资源学院环境科学研究所, 杭州 310058

收稿日期:2017-06-26 出版日期:2018-02-18 发布日期:2018-02-18
通讯作者: E-mail: 362821519@qq.com
作者简介:王行, 男, 1987年生, 博士, 副研究员. 主要从事土壤学和微生物生态研究. E-mail: hwang17@163.com
基金资助:
本文由国家自然科学基金项目(31500409,31370497)和云南省高原湿地科学省创新团队项目(2012HC007)资助

The relative contributions of plant quality, simulated rising temperature, and habitat to litter decomposition.

WANG Hang^1,2, YAN Peng-fei¹, ZHAN Peng-fei¹, ZHANG Xiao-ning¹, LIU Zhen-ya¹, GUO Yu-jing¹, XIAO De-rong^1*

¹National Plateau Wetlands Research Center/Wetlands College, Southwest Forestry University, Kunming 650224, China;
²Institute of Environmental Science, College of Environment and Resources, Zhejiang University, Hangzhou 310058, China

Received:2017-06-26 Online:2018-02-18 Published:2018-02-18
Contact: E-mail: 362821519@qq.com
Supported by:
This work was supported by the National Natural Science Foundation of China (31500409, 31370497) and the Yunnan Innovative Research Team of Plateau Wetland Science (2012HC007).

摘要/Abstract

摘要： 采用凋落物袋法对比研究了茭草和杉叶藻两种初始质量差异显著的湿地植物凋落物,在模拟增温(1.5～2.0 ℃)及不同生境(大气、大气-水界面与水-土界面)下的质量残留率和不同化学组分的含量变化.结果表明: 在一年的分解周期内,凋落物残留率表现出季节性变化特征,并与环境因子之间存在显著的交互作用.各因子对凋落物分解的贡献大小不同,植物质量解释了28.8%的变异,模拟增温解释了6.3%的变异,而生境解释了34.9%的变异.随着分解时间的延长,凋落物中不同组分(难、易分解)的含量发生明显变化.杉叶藻中氮含量在分解后期显著降低了53.1%,而木质素含量显著增加了45.4%.生境是影响凋落物分解最重要的环境因子,其次是植物质量,而模拟增温对凋落物分解的影响程度较小.

Abstract: With litter bag methods, we examined mass loss rates and different chemical fractions of litters from two wetland plant species, Zizania caduciflora and Hippuris vulgaris. Those two species examined here varied significantly in their initial litter chemical traits. Experiment was performed under simulated rising temperature (1.5-2.0 ℃), and under three different habitats (air, air-water interface and water-soil interface). The results showed that, during one-year decomposition period, the mass resi-dual rates exhibited distinct seasonal dynamics, and there were strong interactive effects between seasonal dynamics and environmental factors. Different factors contributed differently for the variation of litter decomposition, 28.8% of which being explained by litter quality, 6.3% of which being explained by rising temperature, and 34.9% being explained by habitat. Along with the decomposition, the contents of different chemical fractions (easy or hard to decompose) varied greatly. Among them, nitrogen contents in H. vulgaris decreased by 53.1%, while the lignin contents increased by 45.4%. Overall, habitat was the most important factor driving litter decomposition, the second was litter quality, and rising temperature had minor effect.

王行, 闫鹏飞, 展鹏飞, 张晓宁, 刘振亚, 郭玉静, 肖德荣. 植物质量、模拟增温及生境对凋落物分解的相对贡献[J]. 应用生态学报, 2018, 29(2): 474-482.

WANG Hang, YAN Peng-fei, ZHAN Peng-fei, ZHANG Xiao-ning, LIU Zhen-ya, GUO Yu-jing, XIAO De-rong. The relative contributions of plant quality, simulated rising temperature, and habitat to litter decomposition.[J]. Chinese Journal of Applied Ecology, 2018, 29(2): 474-482.

参考文献

[1] Wang F-Y (王凤友). Forest litter quality research review. Advances in Ecology (生态学进展), 1989, 6(2): 82-89 (in Chinese)
[2] Peng S-L (彭少麟), Liu Q (刘强). The dynamics of forest litter and its responses to global warming. Acta Ecologica Sinica (生态学报), 2002, 22(9): 1534-1544 (in Chinese)
[3] Berg B, McClaugherty C. Nitrogen and phosphorus release from decomposing litter in relation to the disappearance of lignin. Canadian Journal of Botany, 1989, 67: 1148-1156
[4] Parton W, Silver WL, Burke IC, et al. Global-scale similarities in nitrogen release patterns during long-term decomposition. Science, 2007, 315: 361-364
[5] Marty C, Houle D, Gagnon C. Variation in stocks and distribution of organic C in soils across 21 eastern Canadian temperate and boreal forests. Forest Ecology and Management, 2015, 345: 29-38
[6] Guo X-H (郭绪虎), Tian K (田昆), Xiao D-R (肖德荣), et al. A study on lakeside dominant plants litter decomposition characteristics in Napahai plateau wetland in northwest Yunnan. Ecological Science (生态科学), 2013, 32(2): 200-205 (in Chinese)
[7] Huang J-X (黄锦学), Huang L-M (黄李梅), Lin Z-C (林智超), et al. Controlling factors of litter decomposition rate in China’s forests. Journal of Subtropical Resources and Environment (亚热带资源与环境学报), 2010, 5(3): 56-63 (in Chinese)
[8] Tang S-S (唐仕姗), Yang W-Q (杨万勤), Yin R (殷睿), et al. Spatial characteristics in decomposition rate of foliar litter and controlling factors in Chinese forest ecosystems. Chinese Journal of Plant Ecology (植物生态学报), 2014, 38(6): 529-539 (in Chinese)
[9] Song P (宋飘), Zhang N-L (张乃莉), Ma K-P (马克平), et al. Impacts of global warming on litter decomposition. Acta Ecologica Sinica (生态学报), 2014, 34(6): 1327-1339 (in Chinese)
[10] Xu X-F (徐小峰), Tian H-Q (田汉勤), Wan S-Q (万师强). Climate warming impacts on carbon cycling in terrestrial ecosystems. Chinese Journal of Plant Ecology (植物生态学报), 2007, 31(2): 75-188 (in Chinese)
[11] Ge J-L (葛结林), Xiong G-M (熊高明), Li J-X (李家湘), et al. Litter standing crop of shrubland ecosystem in southern China. Chinese Journal of Plant Ecology (植物生态学报), 2017, 41(1): 5-13 (in Chinese)
[12] Wang Y-H (王忆慧), Gong J-R (龚吉蕊), Liu M (刘敏), et al. Effects of grassland-use on soil respiration and litter decomposition. Chinese Journal of Plant Ecology (植物生态学报), 2015, 39(3): 239-248 (in Chinese)
[13] Fan ZX, Brauning A, Thomas A, et al. Spatial and temporal temperature tends on the Yunnan plateau (Southwest China) during 1961-2004. International Journal of Climatology, 2011, 31: 2078-2090
[14] Knacker T, Forster B, Rombke J, et al. Assessing the effects of plant protection products on organic matter breakdown in arable fields-litter decomposition test systems. Soil Biology & Biochemistry, 2003, 35: 1269-1287
[15] Bao S-D (鲍士旦). Soil and Agricultural Chemistry Analysis. Beijing: China Agriculture Press, 2000 (in Chinese)
[16] Berg B, Laskowski R. Litter Decomposition: A Guide to Carbon and Nutrient Turnover. London: Academic Press, 2006
[17] Hu F-Q (胡凤琴), Li S (李硕), Mu P (牟溥). Suggestions for data analysis and use of statistics. Chinese Journal of Plant Ecology (植物生态学报), 2013, 37(6): 583-588 (in Chinese)
[18] Aerts R. Climate, leaf litter chemistry and leaf litter decomposition in terrestrial ecosystems: A triangular relationship. Oikos, 1997, 79: 439-449
[19] Gholz HL, Wedin DA, Smitherman SM, et al. Long-term dynamics of pine and hardwood litter in contrasting environments: Toward a global model of decomposition. Global Change Biology, 2000, 6: 751-765
[20] Zhang DQ, Hui DF, Luo YQ, et al. Rates of litter decomposition in terrestrial ecosystems: Global patterns and controlling factors. Journal of Plant Ecology, 2008, 1: 85-93
[21] Polyakova O, Billor N. Impact of deciduous tree species on litterfall quality, decomposition rates and nutrient circulation in pine stands. Forest Ecology and Management, 2007, 253: 11-18
[22] Zhou S-X (周世兴), Huang C-D (黄从德), Xiang Y-B (向元彬), et al. Effects of simulated nitrogen deposition on lignin and cellulose degradation of foliar litter in natural evergreen broad-leaved forest in rainy area of western China. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(5): 1368-1374 (in Chinese)
[23] Cusack DF, Chou WW, Yang WH, et al. Controls on long-term root and leaf litter decomposition in neotropical forests. Global Change Biology, 2010, 15: 1339-1355
[24] Berg B. Decomposition patterns for foliar litter: A theory for influencing factors. Soil Biology & Biochemistry, 2014, 78: 222-232
[25] Yue K (岳楷), Yang W-Q (杨万勤), Peng Y (彭艳), et al. Effects of streams on lignin degradation during foliar litter decomposition in an alpine forest. Chinese Journal of Plant Ecology (植物生态学报), 2016, 40(9): 893-901 (in Chinese)
[26] Aerts R. The freezer defrosting: Global warming and litter decomposition rates in cold biomes. Journal of Ecology, 2006, 94: 713-724
[27] Xu Z-F (徐振峰), Yin H-J (尹华军), Zhao C-Z (赵春章), et al. A review of responses of decomposition in terrestrial ecosystems to global warming. Chinese Journal of Plant Ecology (植物生态学报), 2009, 33(6): 1208-1219 (in Chinese)
[28] Dorrepaal E, Cornelissen JH, Aerts R, et al. Are growth forms consistent predictors of leaf litter quality and decomposability across peatlands along a latitudinal gradient? Journal of Ecology, 2005, 93: 817-828
[29] Song Y (宋影), Zhang X-R (章夕容), Yan H-Z (严海之), et al. Dynamics of microbes and enzyme activities during litter decomposition of Pinus massoniana forest in mid-subtropical area. Environmental Science (环境科学), 2014, 35(3): 1151-1158 (in Chinese)
[30] Singh KP, Singh PK, Tripathi SK. Litterfall, litter decomposition and nutrient release patterns in four native tree species raised on coal mine spoil at Singrauli, India. Biology and Fertility of Soils, 1999, 29: 371-378
[31] Willcock J, Magan N. Impact of environmental factors on fungal respiration and dry matter losses in wheat straw. Journal of Stored Products Research, 2001, 37: 35-45
[32] Liu G, Cornwell WK, Pan X, et al. Decomposition of 51 semidesert species from wide-ranging phylogeny is faster in standing and sand-buried than in surface leaf litters: Implications for carbon and nutrient dynamics. Plant and Soil, 2015, 396: 175-187
[33] Wang X-E (王相娥), Xue L (薛立), Xie T-F (谢腾芳). A review on litter decomposition. Chinese Journal of Soil Science (土壤通报), 2009, 40(6): 1473-1478 (in Chinese)
[34] Liu R-L (刘瑞龙), Yang W-Q (杨万勤), Tan B (谭波), et al. Effects of soil fauna on N and P dynamics at different stages during the first year of litter decomposition in subalpine and alpine forests of western Sichuan. Chinese Journal of Plant Ecology (植物生态学报), 2013, 37(12): 1080-1090 (in Chinese)
[35] Groffman PM, Driscooll CT, Fahey TJ, et al. Effects of mild winter freezing on soil nitrogen and carbon dyna-mics in northern hardwood forest. Biogeochemistry, 2001, 56: 191-213
[36] Guo X-H (郭绪虎), Xiao D-R (肖德荣), Tian K (田昆), et al. Biomass production and litter decomposition of lakeshore plants in Napahai wetland Northwestern Yunnan Plateau China. Acta Ecologica Sinica (生态学报), 2013, 33(5): 1425-1432 (in Chinese)
[37] Zhang C (张川), Yang W-Q (杨万勤), Yue K (岳楷), et al. Soluble nitrogen and soluble phosphorus dynamics during foliar litter decomposition in winter in alpine forest stream. Chinese Journal of Applied Ecology, (应用生态学报), 2015, 26(6): 1601-1608 (in Chinese)
[38] Yang Z-J (杨曾奖), Zeng J (曾杰), Xu D-P (徐大平), et al. The processes and dominant factors of forest litter decomposition: A review. Ecology and Environment (生态环境), 2007, 16(2): 649-654 (in Chinese)
[39] Yue K (岳楷), Yang W-Q (杨万勤), Peng Y (彭艳), et al. Foliar litter mass loss in winter in an alpine forest river in the upper reaches of the Minjiang River. Resources and Environment in the Yangtze Basin (长江流域资源与环境), 2015, 24(7): 1177-1184 (in Chinese)
[40] Adair EC, Parton WJ, del Grosso SJ, et al. Simple three-pool model accurately describes patterns of long-term litter decomposition in diverse climates. Global Change Biology, 2008, 14: 2636-2660

植物质量、模拟增温及生境对凋落物分解的相对贡献

The relative contributions of plant quality, simulated rising temperature, and habitat to litter decomposition.

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