应用生态学报 ›› 2020, Vol. 31 ›› Issue (11): 3906-3914.doi: 10.13287/j.1001-9332.202011.026
韩雪, 陈宝明*
收稿日期:
2020-06-07
接受日期:
2020-08-24
出版日期:
2020-11-15
发布日期:
2021-06-10
通讯作者:
* E-mail: chbaoming@163.com
作者简介:
韩 雪, 女, 1997年生, 硕士研究生。主要从事全球变化生态学研究。E-mail: 405958393@qq.com
基金资助:
HAN Xue, CHEN Bao-ming*
Received:
2020-06-07
Accepted:
2020-08-24
Online:
2020-11-15
Published:
2021-06-10
Contact:
* E-mail: chbaoming@163.com
Supported by:
摘要: 全球变暖已引起人们的广泛关注,大气温室效应气体浓度增加是导致全球变暖的主要因素之一,土壤是温室效应气体的主要来源。反过来,全球变暖对土壤温室气体的排放具有反馈作用。温度升高不仅会影响植物、动物、微生物的生长及其相互作用,还会影响土壤的物质(尤其是氮、碳)循环过程,从而影响土壤温室效应气体的排放。本文主要总结了增温对土壤主要温室气体N2O和CH4排放的影响及其微生物机制。总体来看,增温能够促进这两种温室气体的排放,其排放主要与温度对氨氧化细菌(AOB)、反硝化功能基因、甲烷产生菌和甲烷氧化菌的丰度和组成的影响有关。土壤温室气体排放也受到植物的物种特性、养分吸收和群落组成,以及土壤营养元素含量、含水量、pH值等理化性质的影响。未来应更深入地从微生物角度探讨全球变暖对土壤温室气体排放的反馈作用机制,加强不同增温模式对土壤温室气体排放的影响研究,并关注增温与其他环境因子相互作用对土壤温室气体排放的影响等,以期为全球变暖对土壤温室气体排放反馈作用的预测提供理论依据。
韩雪, 陈宝明. 增温对土壤N2O和CH4排放的影响与微生物机制研究进展[J]. 应用生态学报, 2020, 31(11): 3906-3914.
HAN Xue, CHEN Bao-ming. Progress in the effects of warming on soil N2O and CH4 emission and the underlying micro-bial mechanisms[J]. Chinese Journal of Applied Ecology, 2020, 31(11): 3906-3914.
[1] 张若玉, 何金海, 张华. 温室气体全球增温潜能的研究进展. 安徽农业科学, 2011, 39(28): 17416-17419, 17422 [Zhang R-Y, He J-H, Zhang H. Overview of researches on global warming potential of greenhouse gases. Journal of Anhui Agricultural Sciences, 2011, 39(28): 17416-17419, 17422] [2] IPCC. Climate Change 2014: Impacts, Adaptation, and Vulnerability. Cambridge: Cambridge University Press, 2014 [3] 董星丰, 陈强, 李浩, 等. 全球气候变化对我国高寒地区冻土温室气体通量的影响. 土壤与作物, 2019, 8(2): 178-185 [Dong X-F, Chen Q, Li H, et al. Effects of climate change on permafrost greenhouse gas flux in alpine region of China. Soils and Crops, 2019, 8(2): 178-185] [4] Wang X, Siciliano S, Helgason B, et al. Responses of a mountain peatland to increasing temperature: A microcosm study of greenhouse gas emissions and microbial community dynamics. Soil Biology and Biochemistry, 2017, 110: 22-33 [5] Cui Q, Song CC, Wang XW, et al. Effects of warming on N2O fluxes in a boreal peatland of permafrost region, Northeast China. Science of the Total Environment, 2018, 616: 427-434 [6] Cui PY, Fan FL, Yin C, et al. Long-term organic and inorganic fertilization alters temperature sensitivity of potential N2O emissions and associated microbes. Soil Biology and Biochemistry, 2016, 93: 131-141 [7] Du YG, Guo XW, Cao GM, et al. Simulation and prediction of nitrous oxide emission by the water and nitrogen management model on the Tibetan Plateau. Bioche-mical Systematics and Ecology, 2016, 65: 49-56 [8] Gong Y, Wu JH, Vogt J, et al. Warming reduces the increase in N2O emission under nitrogen fertilization in a boreal peatland. Science of the Total Environment, 2019, 664: 72-78 [9] Wang B, Li JL, Wan YF, et al. Responses of yield, CH4 and N2O emissions to elevated atmospheric tempe-rature and CO2 concentration in a double rice cropping system. European Journal of Agronomy, 2018, 96: 60-69 [10] Li L, Zheng Z, Wang W, et al. Terrestrial N2O emissions and related functional genes under climate change: A global meta-analysis. Global Change Biology, 2020, 26: 931-943 [11] Voigt C, Lamprecht RE, Marushchak ME, et al. Warming of subarctic tundra increases emissions of all three important greenhouse gases: Carbon dioxide, methane, and nitrous oxide. Global Change Biology, 2017, 23: 3121-3138 [12] Song A, Liang YC, Zeng XB, et al. Substrate-driven microbial response: A novel mechanism contributes significantly to temperature sensitivity of N2O emissions in upland arable soil. Soil Biology and Biochemistry, 2018, 118: 18-26 [13] Bijoor NS, Czimczik CI, Pataki DE, et al. Effects of temperature and fertilization on nitrogen cycling and community composition of an urban lawn. Global Change Biology, 2008, 14: 2119-2131 [14] Schaufler G, Kitzler B, Schindlbacher A, et al. Greenhouse gas emissions from European soils under different land use: Effects of soil moisture and temperature. European Journal of Soil Science, 2010, 61: 683-696 [15] Dobbie KE, Smith KA. The effects of temperature, water-filled pore space and land use on N2O emissions from an imperfectly drained gleysol. European Journal of Soil Science, 2001, 52: 667-673 [16] Koponen HT, Flöjt L, Martikainen PJ. Nitrous oxide emissions from agricultural soils at low temperatures: A laboratory microcosm study. Soil Biology and Biochemistry, 2004, 36: 757-766 [17] Ward SE, Ostle NJ, Oakley S, et al. Warming effects on greenhouse gas fluxes in peatlands are modulated by vegetation composition. Ecology Letters, 2013, 16: 1285-1293 [18] 李海防, 夏汉平, 熊燕梅, 等. 土壤温室气体产生与排放影响因素研究进展. 生态环境, 2007, 16(6): 1781-1788 [Li H-F, Xia H-P, Xiong Y-M, et al. Mechanism of greenhouse gases fluxes from soil and its controlling factors: A review. Ecology and Environment, 2007, 16(6): 1781-1788] [19] Gaihre YK, Wassmann R, Villegas-Pangga G. Impact of elevated temperatures on greenhouse gas emissions in rice systems: Interaction with straw incorporation studied in a growth chamber experiment. Plant and Soil, 2013, 373: 857-875 [20] Cheng W, Sakai H, Hartley A, et al. Increased night temperature reduces the stimulatory effect of elevated carbon dioxide concentration on methane emission from rice paddy soil. Global Change Biology, 2008, 14: 644-656 [21] Laine AM, Mehtatalo L, Tolvanen A, et al. Impacts of drainage, restoration and warming on boreal wetland greenhouse gas fluxes. Science of the Total Environment, 2019, 647: 169-181 [22] Turetsky MR, Kotowska A, Bubier J, et al. A synthesis of methane emissions from 71 northern, temperate, and subtropical wetlands. Global Change Biology, 2019, 20: 2183-2197 [23] Inglett KS, Inglett PW, Reddy KR, et al. Temperature sensitivity of greenhouse gas production in wetland soils of different vegetation. Biogeochemistry, 2011, 108: 77-90 [24] Chaxton JP, Bakert T. Effect of CO2 enrichment and elevated temperature on methane emissions from rice, Oryza sativa. Global Change Biology, 1999, 5: 587-599 [25] Sihi D, Inglett PW, Gerber S, et al. Rate of warming affects temperature sensitivity of anaerobic peat decomposition and greenhouse gas production. Global Change Biology, 2018, 24: e259-e274 [26] Prosser JI, Hink L, Gubry-Rangin C, et al. Nitrous oxide production by ammonia oxidizers: Physiological diversity, niche differentiation and potential mitigation strategies. Global Change Biology, 2020, 26: 103-118 [27] Oliverio AM, Bradford MA, Fierer N. Identifying the microbial taxa that consistently respond to soil warming across time and space. Global Change Biology, 2017, 23: 2117-2129 [28] 张荣涛, 隋 心, 许 楠, 等. 三江平原小叶章湿地温室气体排放及其对模拟氮沉降的响应. 应用生态学报, 2018, 29(10): 3191-3198 [Zhang R-T, Sui X, Xu N, et al. Responses of greenhouse gas emission to simulated nitrogen deposition in Calamagrostis angustifolia wetlands of Sanjiang Plain, China. Chinese Journal of Applied Ecology, 2018, 29(10): 3191-3198] [29] Zhang Y, Zhang N, Yin J, et al. Combination of warming and N inputs increases the temperature sensitivity of soil N2O emission in a Tibetan alpine meadow. Science of the Total Environment, 2020, 704: 135450 [30] Waghmode TR, Chen S, Li J, et al. Response of nitri-fier and denitrifier abundance and microbial community structure to experimental warming in an agricultural ecosystem. Frontiers in Microbiology, 2018, 9: 474 [31] Xu XY, Liu XR, Li Y, et al. High temperatures inhibited the growth of soil bacteria and archaea but not that of fungi and altered nitrous oxide production mechanisms from different nitrogen sources in an acidic soil. Soil Biology and Biochemistry, 2017, 107: 168-179 [32] van Kessel MA, Speth DR, Albertsen M, et al. Complete nitrification by a single microorganism. Nature, 2015, 528: 555-559 [33] Daims H, Lebedeva EV, Pjevac P, et al. Complete nitrification by Nitrospira bacteria. Nature, 2015, 528: 504-509 [34] 李思琦, 臧坤鹏, 宋伦. 湿地甲烷代谢微生物产甲烷菌和甲烷氧化菌的研究进展. 海洋环境科学, 2020, 39(3): 488-496 [Li S-Q, Zang K-P, Song L. Review on methanogens and methanotrophs metabolised by methane in wetland. Marine Environmental Science, 2020, 39(3): 488-496] [35] Jiao ZH, Hou AX, Shi Y, et al. Water management influencing methane and nitrous oxide emissions from rice field in relation to soil redox and microbial community. Communications in Soil Science and Plant Analysis, 2006, 37: 1889-1903 [36] Yue J, Shi Y, Liang W, et al. Methane and nitrous oxide emissions from rice field and related microorganism in black soil, northeastern China. Nutrient Cycling in Agroecosystems, 2005, 73: 293-301 [37] van Winden JF, Reichart G, McNamara NP, et al. Temperature-induced increase in methane release from peat bogs: A mesocosm experiment. PLoS One, 7(6): e39614 [38] Yvon-Durocher G, Allen AP, Bastviken D, et al. Methane fluxes show consistent temperature dependence across microbial to ecosystem scales. Nature, 2014, 507: 488-491 [39] Lu Y, Fu L, Lu YH, et al. Effect of temperature on the structure and activity of a methanogenic archaeal community during rice straw decomposition. Soil Biology and Biochemistry, 2015, 81: 17-27 [40] Allan J, Ronholm J, Mykytczuk NCS, et al. Methanogen community composition and rates of methane consumption in Canadian High Arctic permafrost soils. Environmental Microbiology Reports, 2014, 6: 136-144 [41] Chen J, Zhou ZC, Gu JD. Occurrence and diversity of nitrite-dependent anaerobic methane oxidation bacteria in the sediments of the South China Sea revealed by amplification of both 16S rRNA and pmoA genes. Applied Microbiology and Biotechnology, 2014, 98: 5685-5696 [42] Xiang X, Wang R, Wang H, et al. Distribution of Bathyarchaeota communities across different terrestrial settings and their potential ecological functions. Scientific Reports, 2017, 7: 45028 [43] Raghoebarsing AA, Pol A, van de Pas-Schoonen KT, et al. A microbial consortium couples anaerobic methane oxidation to denitrification. Nature, 2006, 440: 918-921 [44] Chang RY, Wang GX, Yang YH, et al. Experimental warming increased soil nitrogen sink in the Tibetan permafrost. Journal of Geophysical Research-Biogeosciences, 2017, 122: 1870-1879 [45] Houlton BZ, Sigman DM, Hedin LO. Isotopic evidence for large gaseous nitrogen losses from tropical rainforests. Proceedings of the National Academy of Sciences of the United States of America, 2006, 103: 8745-8750 [46] Shurpali NJ, Rannik U, Jokinen S, et al. Neglecting diurnal variations leads to uncertainties in terrestrial nitrous oxide emissions. Scientific Reports, 2016, 6: 25739 [47] Yun JL, Zhang HX, Deng YC, et al. Aerobic methanotroph diversity in Sanjiang wetland, Northeast China. Microbial Ecology, 2014, 69: 567-576 [48] Lu M, Zhou XH, Yang Q, et al. Responses of ecosystem carbon cycle to experimental warming: A meta-analysis. Ecology, 2013, 94: 726-738 [49] Lin D, Xia J, Wan S. Climate warming and biomass accumulation of terrestrial plants: A meta-analysis. New Phytologist, 2010, 188: 187-198 [50] Gorh D, Baruah KK. Estimation of methane and nitrous oxide emission from wetland rice paddies with reference to global warming potential. Environmental Science and Pollution Research, 2019, 26: 16331-16344 [51] Xia JY, Niu SL, Wan S. Response of ecosystem carbon exchange to warming and nitrogen addition during two hydrologically contrasting growing seasons in a temperate steppe. Global Change Biology, 2009, 15: 1544-1556 [52] Zhang YH, Ding WX, Cai ZC, et al. Response of methane emission to invasion of Spartina alterniflora and exogenous N deposition in the coastal salt marsh. Atmospheric Environment, 2010, 44: 4588-4594 [53] Wolkovich EM, Lipson DA, Virginia RA, et al. Grass invasion causes rapid increases in ecosystem carbon and nitrogen storage in a semiarid shrubland. Global Change Biology, 2010, 16: 1351-1365 [54] Yuan J, Ding W, Liu D, et al. Exotic Spartina alterniflora invasion alters ecosystem-atmosphere exchange of CH4 and N2O and carbon sequestration in a coastal salt marsh in China. Global Change Biology, 2015, 21: 1567-1580 [55] Gao DZ, Hou LJ, Li XF, et al. Exotic Spartina alterniflora invasion alters soil nitrous oxide emission dynamics in a coastal wetland of China. Plant and Soil, 2019, 442: 233-246 [56] Niu S, Sherry RA, Zhou XH, et al. Ecosystem carbon fluxes in response to warming and clipping in a tallgrass prairie. Ecosystems, 2013, 16: 948-961 [57] 王跃思, 薛敏, 黄耀, 等. 内蒙古天然与放牧草原温室气体排放研究. 应用生态学报, 2003, 14(3): 372-376 [Wang Y-S, Xue M, Huang Y, et al. Greenhouse gases emission or uptake in Inner Mongolia natural and free-grazing grasslands. Chinese Journal of Applied Ecology, 2003, 14(3): 372-376] [58] Tang XL, Liu SG, Zhou GY, et al. Soil-atmospheric exchange of CO2, CH4, and N2O in three subtropical forest ecosystems in southern China. Global Change Bio-logy, 2006, 12: 546-560 [59] Butterbach-Bahl K, Baggs EM, Dannenmann M, et al. Nitrous oxide emissions from soils: How well do we understand the processes and their controls? Philosophical Transactions of the Royal Society B: Biological Sciences, 2013, 368: 20130122 [60] Cai ZC, Shan YH, Xu H. Effects of nitrogen fertilization on CH4 emissions from rice fields. Soil Science and Plant Nutrition, 2007, 53: 353-361 [61] Gao Q, Bai E, Wang JS, et al. Effects of litter manipulation on soil respiration under short-term nitrogen addition in a subtropical evergreen forest. Forest Ecology and Management, 2018, 429: 77-83 [62] Li J, Nie M, Pendall E. An incubation study of tempe-rature sensitivity of greenhouse gas fluxes in three land-cover types near Sydney, Australia. Science of the Total Environment, 2019, 688: 324-332 [63] Bai E, Li S, Xu W, et al. A meta-analysis of experimental warming effects on terrestrial nitrogen pools and dynamics. New Phytologist, 2013, 199: 431-440 [64] Zhang XZ, Shen ZX, Fu G. A meta-analysis of the effects of experimental warming on soil carbon and nitrogen dynamics on the Tibetan Plateau. Applied Soil Ecology, 2015, 87: 32-38 [65] Davidson EA, Keller M, Erickson HE, et al. Testing a conceptual model of soil emissions of nitrous and nitric oxides. Bioscience, 2000, 50: 667-680 [66] Zhu GB, Wang MZ, Li YX, et al. Denitrifying anaerobic methane oxidizing in global upland soil: Sporadic and non-continuous distribution with low influence. Soil Biology and Biochemistry, 2018, 119: 90-100 [67] Matysek M, Leake J, Banwart S, et al. Impact of ferti-lizer, water table, and warming on celery yield and CO2 and CH4 emissions from fenland agricultural peat. Science of the Total Environment, 2019, 667: 179-190 [68] 刘蓓, Elberling B, 贾仲君. 不同水分条件下格陵兰岛冻土活性甲烷氧化菌群落分异规律. 土壤, 2020, 52(1): 90-96 [Liu B, Elberling B, Jia Z-J. The emergence of novel methane oxidizers in Greenland permafrost soil under periodically water saturated conditions. Soils, 2020, 52(1): 90-96] [69] 徐冰鑫, 胡宜刚, 张志山, 等. 模拟增温对荒漠生物土壤结皮-土壤系统CO2、CH4和N2O通量的影响. 植物生态学报, 2014, 38(8): 809-820 [Xu B-X, Hu Y-G, Zhang Z-S, et al. Effects of experimental warming on CO2, CH4 and N2O fluxes of biological soil crust and soil system in a desert region. Chinese Journal of Plant Ecology, 2014, 38(8): 809-820] [70] Zhang T, Wang GX, Yang Y, et al. Grassland types and season-dependent response of ecosystem respiration to experimental warming in a permafrost region in the Tibetan Plateau. Agricultural and Forest Meteorology, 2017, 247: 271-279 [71] Yu K, Faulkner SP, Patrick WH Jr. Redox potential characterization and soil greenhouse gas concentration across a hydrological gradient in a gulf coast forest. Chemosphere, 2006, 62: 905-914 [72] Potter CS, Davidson EA, Verchot LV. Estimation of global biogeochemical controls and seasonality in soil methane consumption. Chemosphere, 1996, 32: 2219-2246 [73] Dai XQ, Yuan Y, Wang HM. Changes of anaerobic to aerobic conditions but not of crop type induced bulk soil microbial community variation in the initial conversion of paddy soils to drained soils. Catena, 2016, 147: 578-585 [74] Wang C, Li X, Min QW, et al. Responses of greenhouse-gas emissions to land-use change from rice to jasmine production in subtropical China. Atmospheric Environment, 2019, 201: 391-401 [75] 郎漫, 李平, 张小川, 等. 土地利用方式和培养温度对土壤氮转化及温室气体排放的影响. 应用生态学报, 2012, 23(10): 2670-2676 [Lang M, Li P, Zhang X-C. Effects of land use type and incubation temperature on soil nitrogen transformation and greenhouse gas emission. Chinese Journal of Applied Ecology, 2012, 23(10): 2670-2676] [76] IPCC. Climate Change 2007: The Physical Science Basis. Cambridge: Cambridge University Press, 2007 [77] He JJ, Zhang PY, Jing WL, et al. Spatial responses of net ecosystem productivity of the Yellow River basin under diurnal asymmetric warming. Sustainability, 2018, 10(10): 3646 |
[1] | 解玲玲, 王邵军, 肖博, 王郑钧, 郭志鹏, 郭晓飞, 罗双, 李瑞, 夏佳慧, 兰梦杰, 杨胜秋. 蚂蚁巢穴对高檐蒲桃热带次生林土壤CH4排放通量的影响 [J]. 应用生态学报, 2024, 35(3): 678-686. |
[2] | 王婷, 牟长城, 孙梓淇, 李美霖, 王文婧, 许文, 赵海明. 长白山园池沼泽湿地碳源/汇沿湖岸至高地环境梯度变化 [J]. 应用生态学报, 2023, 34(9): 2363-2373. |
[3] | 赵月琴, 马秀静, 赵琬婧, 张治军, 孙晓新. 三江平原垦殖湿地恢复对温室气体排放的影响 [J]. 应用生态学报, 2023, 34(8): 2142-2152. |
[4] | 孔东彦, 杨灵芳, 刁静文, 郭鹏. 不同生境下氮沉降对土壤N2O通量影响的整合分析 [J]. 应用生态学报, 2023, 34(8): 2171-2177. |
[5] | 袁书禹, 谢柳娟, 叶思源, 周攀, 裴理鑫, 丁喜桂, 袁红明, 高宗军. 黄渤海湿地芦苇光合特征对增温的响应 [J]. 应用生态学报, 2023, 34(7): 1825-1833. |
[6] | 刘源豪, 杜旭龙, 黄锦学, 熊德成. 增温对林木细根寿命影响的研究进展 [J]. 应用生态学报, 2023, 34(6): 1693-1702. |
[7] | 张宇辉, 陈娟, 胥超, 熊德成, 杨智杰, 陈仕东, 毛超. 增温对亚热带格氏栲天然林凋落物可溶性有机质数量和结构的影响 [J]. 应用生态学报, 2023, 34(4): 946-954. |
[8] | 娄运生, 于玉洁, 刘燕, 杨蕙琳, 周东雪. 施硅对夜间增温下南方水稻生长、产量和品质的影响 [J]. 应用生态学报, 2023, 34(4): 985-992. |
[9] | 毛超, 林伟盛, 胥超, 刘小飞, 熊德成, 杨智杰, 陈仕东. 土壤增温降低亚热带森林土壤可溶性有机碳数量和质量 [J]. 应用生态学报, 2023, 34(3): 623-630. |
[10] | 王文婧, 牟长城, 李美霖, 孙梓淇, 王婷, 许文, 赵海明. 长白山河滨森林湿地碳源/汇空间分异规律及机制 [J]. 应用生态学报, 2023, 34(12): 3245-3255. |
[11] | 高玮, 李子双, 谢建治, 周晓琳, 杜梦扬, 王学霞, 陈延华, 曹兵. 基施控释掺混肥对夏玉米生长期活性氮损失和碳氮足迹的影响 [J]. 应用生态学报, 2023, 34(12): 3322-3332. |
[12] | 展鹏飞, 仝川. 甲烷排放部分抵消湿地生态系统碳汇功能:全球数据分析 [J]. 应用生态学报, 2023, 34(11): 2958-2968. |
[13] | 黄翯宸, 金靖昊, 沈李东, 田茂辉, 刘心, 杨王挺, 胡正华. 大气CO2浓度缓增对稻田硝酸盐型甲烷厌氧氧化过程的影响 [J]. 应用生态学报, 2022, 33(9): 2441-2449. |
[14] | 刘东, 孙剑平, 王莹莹, 宋琳琳, 李靳, 赵星涵, 刘畅, 全智, 方运霆. 工厂化堆肥温室气体排放和氨气同位素特征 [J]. 应用生态学报, 2022, 33(6): 1451-1458. |
[15] | 林志敏, 李洲, 翁佩莹, 吴冬青, 邹京南, 庞孜钦, 林文雄. 再生稻田温室气体排放特征及碳足迹 [J]. 应用生态学报, 2022, 33(5): 1340-1351. |
阅读次数 | ||||||
全文 |
|
|||||
摘要 |
|
|||||