CHENG Gong,LIU Tingxi,WANG Guanli,et al.Characteristics of CO2, CH4 and N2O Fluxes in Horqin Dune-Meadow Cascade Ecosystem[J].Research of Soil and Water Conservation,2019,26(04):96-104,110.
科尔沁沙丘-草甸梯级生态系统CO2,CH4和N2O通量特征
- Title:
- Characteristics of CO2, CH4 and N2O Fluxes in Horqin Dune-Meadow Cascade Ecosystem
- Keywords:
- Horqin; greenhouse gases flux; organic matter; soil temperature; soil moisture
- 分类号:
- S152;X16
- 摘要:
- 为了明确科尔沁沙丘—草甸梯级生态系统中不同生态系统生育期内温室气体通量变化规律及其影响因素,采用静态箱—气相色谱法,于2017年5—10月对呈梯级分布的半流动沙丘、半固定沙丘、人工林地、农田(玉米)和草甸湿地CO2,CH4和N2O通量进行了原位观测,并同步测量取样点的土壤温度、土壤含水量、土壤总有机质含量、总磷含量和总氮含量。对温室气体通量及其影响因子之间进行了相关分析,结果表明:科尔沁沙丘—草甸梯级生态系统上温室气体通量均具有明显的季节性变化,温室气体通量受到土壤含水量和土壤温度的显著影响,二者共同作用促进了温室气体通量的吸收或排放。在干旱半干旱地区,土壤含水量显著影响着土壤温室气体通量对土壤温度的敏感性,土壤温室气体通量随着温度的增加而增大,同时土壤含水量超过田间持水率时,土壤温室气体通量又会随着土壤含水量的增大而降低,从而影响土壤温室气体通量对土壤温度的响应。CO2通量的温度敏感性(Q10)表现为:农田(4.18)> 草甸湿地(2.87)> 人工林地(2.51)> 半固定沙丘(2.41)> 半流动沙丘(2.36)。CO2排放峰值出现在水热条件较好的7月、8月,其中8月22日附近的排放峰值明显高于7月21日附近的排放峰值。3种温室气体通量均值呈现出梯级变化(换算为CO2):半流动沙丘[181.65 mg/(m2·h)] < 半固定沙丘[242.16 mg/(m2·h)] < 人工林地[348.33 mg/(m2·h)] < 农田[405.72 mg/(m2·h)] < 草甸湿地[(487.63 mg/(m2·h)]。试验区土壤总有机质含量、总磷含量也呈现出相同的梯级变化,生育期CO2通量与土壤中总有机质含量和总磷含量呈极显著正相关(p < 0.01)。生育期内N2O通量的变异对土壤温度的响应更强烈。
- Abstract:
- In order to study the variation pattern of greenhouse gas fluxes and the influencing factors in different areas of Horqin sand dune-meadow cascade ecological belt, we used the static chamber-GC technique and conducted in situ observations of CO2, CH4 and N2 O fluxes in semi-mobile dunes, semi-fixed dunes, artificial forest land, farmland (maize) and meadows from May to October, 2017, and simultaneously measured soil temperature, soil moisture, total carbon, total phosphorus and total nitrogen. Correlation analysis on greenhouse gas fluxes and the influencing factors showed that the greenhouse gas fluxes in the Horqin sand dune-meadow ecological belt had obvious seasonal changes, which was significantly affected by soil moisture and soil temperature. The combination of the two promoted the absorption or emission of greenhouse gas fluxes. In arid and semi-arid regions, the sensibility of soil greenhouse gas fluxes to soil temperature is highly dependent on soil moisture. The soil greenhouse gas fluxes increase with the increase of the temperature. When soil moisture exceeds the field water holding capacity, the soil greenhouse gas fluxes will decrease with the increase of soil moisture, which affects the response of the soil greenhouse gas fluxes to soil temperature. Temperature sensitivity of CO2 (Q10) decreased in the order: farmland (4.18) > meadow (2.87) > artificial forest land (2.51) > semi-fixed sand dune (2.41) > semi-mobile dune (2.36). The peak of CO2 emission appeared in July and August when the hydrothermal condition was better, and the peak around August 22 was significantly higher than that around July 21. The average roll of three greenhouse gas fluxes (converted to CO2) increased in the order: semi-mobile dunes [181.65 mg/(m2·h)] < semi-fixed dunes [242.16 mg/(m2·h)] < artificial forest land [348.33 mg/(m2·h)] < farmland [405.72 mg/(m2·h)] < meadows [487.63 mg/(m2·h)]. Organic matter and total phosphorus of the soil in the test area also showed the same change. The CO2 flux in the growing season showed significantly positive correlation with organic matter and total phosphorus of the soil (p < 0.01). Soil N2O flux is more responsive to soil temperature in the growing season.
参考文献/References:
[1] Kim Y S, Makoto K, Takakai F, et al. Greenhouse gas emissions after a prescribed fire in white birch-dwarf bamboo stands in northern Japan, focusing on the role of charcoal[J]. European Journal of Forest Research, 2011,130(6):1031-1044.
[2] Alston M. Gender and climate change in Australia and the Pacific[J]. Journal of Sociology, 2010,5(1):73-87.
[3] Mitchell J F B, Johns T C, Gregory J M, et al. Climate response to increasing levels of greenhouse gases and sulphatea erosols[J]. Nature, 1995,376(6540):501-504.
[4] Roberts D. Prioritizing climate change adaptation and local level resilience in Durban, South Africa[J]. Environment and Urbanization, 2010, 22(2):397-413.
[5] Raich J W, Schlesinger W H. The global carbon dioxide flux in soil respiration and its relationship to vegetation and climate[J]. Tellus Series B:Chemical & Physical Meteorology, 1992,44(2):81-99.
[6] Jayne Belnap. The potential roles of biological soil crusts in dryland hydrologic cycles[J]. Hydrological Processes, 2010,20(15):3159-3178.
[7] Smith K A. Exchange of greenhouse gases between soil and atmosphere:interactions of soil physical factors and biological processes[J]. European Journal of Soil Science, 2003,54(4):779-791.
[8] 陈静,张建国,赵英,等.秸秆和生物炭添加对关中地区玉米-小麦轮作农田温室气体排放的影响[J].水土保持研究,2018,25(5):170-178.
[9] 马钢,王平,王冬雪,等.高寒灌丛土壤温室气体释放对添加不同形态氮素的响应[J].草业学报,2015,24(3):20-29.
[10] Jones S K, Rees R M, Skiba U M, et al. Greenhouse gas emissions from a managed grassland[J]. Global & Planetary Change, 2005,47(2):201-211.
[11] 郭艳亮,王丹丹,郑纪勇,等.生物炭添加对半干旱地区土壤温室气体排放的影响[J].环境科学,2015(9):3393-3400.
[12] 徐世晓,赵亮,李英年,等.降水对青藏高原高寒灌丛冷季CO2通量的影响[J].水土保持学报,2007,21(3):193-195.
[13] Hou L Y, Wang Z P, Wang J M, et al. Growing season in situ uptake of atmospheric methane by desert soils in a semiarid region of northern China[J]. Geoderma, 2012,189/190:415-422.
[14] Zhongwu Wang, Xiying Hao, Dan Shan, et al. Influence of increasing temperature and nitrogen input on greenhouse gas emissions from a desert steppe soil in Inner Mongolia[J]. Soil Science & Plant Nutrition, 2011,57(4):508-518.
[15] Huang L, Zhang Z, Li X. Soil CO2, concentration in biological soil crusts and its driving factors in a revegetated area of the Tengger Desert, Northern China[J]. Environmental Earth Sciences, 2014,72(3):767-777.
[16] 禹朴家,徐海量,王炜,等.沙丘不同部位土壤呼吸对人工降水的响应[J].中国沙漠,2012,32(2):437-441.
[17] Brussaard L, Pcde R, Brown G G. Soil biodiversity for agricultural sustainability[J]. Agriculture Ecosystems & Environment, 2007,121(3):233-244.
[18] Raich J W, Tufekciogul A. Vegetation and soil respiration:Correlations and controls[J]. Biogeochemistry, 2000,48(1):71-90.
[19] Zhang L H, Chen Y N, Li W H, et al. Seasonal variation of soil respiration under different land use/land cover in arid region[J]. Science in China, 2007,50(1):76-85.
[20] Pete Smith. Global climate change and pedogenic carbonates[J]. Geoderma, 2001,104(1):180-182.
[21] Ma A, Lu J, Wang T. Effects of elevation and vegetation on methane emissions from a freshwater estuarine wetland[J]. Journal of Coastal Research, 2012,285(6):1319-1329.
[22] Taylor J L A. On the temperature dependence of soil respiration[J]. Functional Ecology, 1994,8(3):315-323.
[23] Boone R D, Nadelhoffer K J. Roots exert a strong influence on the temperature sensitivity of soil respiration[J]. Nature,1998,396(6711):570-572.
[24] Manzoni S, Schimel J P, Porporato A. Responses of soil microbial communities to water stress:results from a meta-analysis[J]. Ecology, 2012,93(4):930-938.
[25] Linn D M, Doran J W. Effect of water-filled pore space on carbon dioxide and nitrous oxide production in tilled and nontilled soils[J]. Soil Science Society of America Journal, 1984,48(3):647-653.
[26] Or D, Smets B F, Wraith J M, et al. Physical constraints affecting bacterial habitats and activity in unsaturated porous media:A review[J]. Advances in Water Resources, 2007,30(6):1505-1527.
[27] Taylor J P, Wilson B, Mills M S, et al. Comparison of microbial numbers and enzymatic activities in surface soils and subsoils using various techniques[J]. Soil Biology and Biochemistry, 2002,34(3):387-401.
[28] 周丽艳,贾丙瑞,周广胜,等.中国北方针叶林生长季碳交换及其调控机制[J].应用生态学报,2010,21(10):2449-2456.
[29] 郑循华,王明星,王跃思,等.稻麦轮作生态系统中土壤湿度对N2O产生与排放的影响[J].应用生态学报,1996,7(3):273-279.
[30] 徐华,蔡祖聪,李小平,等.冬作季节土地管理对水稻土CH4排放季节变化的影响[J].应用生态学报,2000,11(2):215-218.
[31] Dilustro J J, Collins B, Duncan L, et al. Moisture and soil texture effects on soil CO2, efflux components in southeastern mixed pine forests[J]. Forest Ecology & Management, 2005,204(1):87-97.
[32] Zoellick B W, Ulmschneider H M, Cade B S, et al. Isolation of Snake River islands and mammalian predation on waterfowl nests[J]. Journal of Wildlife Management, 2004,68(3):650-662.
[33] Bond-Lamberty B, Thomson A. Temperature-associated increases in the global soil respiration record[J]. Nature, 2010,464(7288):579-582.
[34] Leon E, Vargas R, Bullock S, et al. Hot spots, hot moments, and spatio-temporal controls on soil CO2 efflux in a water-limited ecosystem[J]. Soil Biology & Biochemistry, 2014,77(7):12-21.
[35] Einola J K M, Kettunen R H, Rintala J A. Responses of methane oxidation to temperature and water content in cover soil of a boreal landfill[J]. Soil Biology and Biochemistry, 2007,39(5):1156-1164.
[36] Trumbore S, Costa E S D, Nepstad D C, et al. Dynamics of fine root carbon in Amazonian tropical ecosystems and the contribution of roots to soil respiration[J]. Global Change Biology, 2010,12(2):217-229.
[37] Ingwersen J, Butterbachbahl K, Gasche R, et al. Barometric process separation:New method for quantifying nitrification, denitrification, and nitrous oxide sources in soils[J]. Soil Science Society of America Journal, 1999,63(1):117-128.
[38] Holland M E A. Biospheric trace gas fluxes and their control over tropospheric chemistry[J]. Annual Review of Ecology and Systematics, 2001,32:547-576.
[39] Davidson E A, Belk E, Boone R D. Soil water content and temperature as independent or confounded factors controlling soil respiration in a temperate mixed hardwood forest[J]. Global Change Biology, 2010,4(2):217-227.
[40] Gulledge J, Schimel J P. Controls on soil carbon dioxide and methane fluxes in a variety of taiga forest stands in interior Alaska[J]. Ecosystems, 2000,3(3):269-282.
[41] Orchard V A, Cook F J. Relationship between soil respiration and soil moisture[J]. Soil Biology & Biochemistry, 1983,15(4):447-453.
[42] Manzoni S, Schimel J P, Porporato A. Responses of soil microbial communities to water stress:results from a meta-analysis[J]. Ecology, 2012,93(4):930-938.
[43] 齐玉春,董云社.土壤氧化亚氮产生、排放及其影响因素[J].地理学报,1999,54(6):534-542.
[44] 郑循华,金继生.华东稻麦轮作生态系统的N2O排放研究[J].应用生态学报,1997,8(5):495-499.
[45] Wagnera D, Pfeifferb E M. Two temperature optima of methane production in a typical soil of the Elbe river marshland[J]. FEMS Microbiology Ecology, 2010,22(2):145-153.
[46] 朱玫,田洪海.大气甲烷的源和汇[J].环境保护科学,1996(2):5-9.
[47] 丁维新,蔡祖聪.土壤有机质和外源有机物对甲烷产生的影响[J].生态学报,2002,22(10):1672-1679.
[48] Yao Z, Wolf B, Chen W, et al. Spatial variability of N2O, CH4 and CO2, fluxes within the Xilin River catchment of Inner Mongolia, China:a soil core study[J]. Plant & Soil,2010,331(1/2):341-359.
相似文献/References:
[1]孙文浩,杨世伟,高晓东,等.黄土丘陵区不同土地利用类型土壤CO2,N2O通量特征[J].水土保持研究,2017,24(01):68.
SUN Wenhao,YANG Shiwei,GAO Xiaodong,et al.Characteristics of CO2 and N2O Emissions Under Different Land-use Types in Loess Hilly Region of China[J].Research of Soil and Water Conservation,2017,24(04):68.
[2]陈静,张建国,赵英,等.秸秆和生物炭添加对关中地区玉米-小麦轮作农田温室气体排放的影响[J].水土保持研究,2018,25(05):170.
CHEN Jing,ZHANG Jianguo,ZHAO Ying,et al.Effects of Straw and Biochar Amendment on Greenhouse Gases Emission in Wheat-Maize Rotation Cropland in Guanzhong Area[J].Research of Soil and Water Conservation,2018,25(04):170.
[3]郭小伟,戴黎聪,李以康,等.不同退化程度下的高寒草甸主要温室气体通量[J].水土保持研究,2019,26(05):188.
GUO Xiaowei,DAI Licong,LI Yikang,et al.Major Greenhouse Gas Fluxes in Different Degradation Levels of Alpine Meadow on the Qinghai-Tibetan Plateau[J].Research of Soil and Water Conservation,2019,26(04):188.
备注/Memo
收稿日期:2018-10-18;改回日期:2018-11-02。
基金项目:国家自然科学基金(51620105003,51139002,51669017);教育部科技创新团队滚动发展计划(IRT_17R60);科技部重点领域创新团队(2015RA4013);内蒙古自治区草原英才创业创新人才团队、内蒙古农业大学寒旱区水资源利用创新团队(NDTD2010-6)
作者简介:程功(1993-),男,黑龙江大庆人,在读硕士研究生,研究方向为温室气体通量。E-mail:18645979803@163.com
通讯作者:刘廷玺(1966-),男,内蒙古赤峰人,教授,博士生导师,主要从事生态水文与资源环境研究。E-mail:txliu1966@163.com