Effect of elevated atmospheric CO2 concentration and temperature on volatile halogenated organic compound content in soils of Schima superba and Cunninghamia lanceolata seedlings.

doi:10.13287/j.1001-9332.202203.001

Abstract

Abstract: Global changes caused by the increases of atmospheric CO₂ concentration and temperature have important effects on soil biogeochemical processes. The synthesis and release of volatile halogenated organic compounds (VOXs) is an important pathway for soil to participate in the global material cycle and energy flow. In this study, Schima superba and Cunninghamia lanceolata seedlings in the southern subtropics were selected as the research objects. Four treatments, including control (CK), elevated CO₂ concentration (EC), elevated temperature (ET) and elevated both factors (EC+ET) were set up. The effects of EC and ET on soil VOXs formation were studied by an open-top chamber system coupled with a purging and trapping gas chromatography/mass spectrometry. The results showed that VOXs content in the soil of S. superba seedlings was 0.065-0.252 ng·g^-1, which was higher than that of C. lanceolata (0.038-0.136 ng·g^-1). At the EC, ET and EC+ET treatments, VOXs contents were reduced in soils of both species. The effect of ET was the most significant, with the decrease rates of 74.2% and 72.1% in both soils, respectively. The change of VOXs content with increasing temperature mainly attributed to the changes of soil moisture and nitrogen content. The content of VOXs in the soils of S. superba seedlings decreased more than that of C. lanceolata under different treatments. In CK, EC, ET and EC+ET treatment, bromodichloromethane (BDCM) (27.5%, 36.7%, 32.9%, 32.6%) and tetrachloromethane (TCM) (9.0%, 16.8%, 22.7%, 15.8%) were the main VOXs in the soil of S. superba seedlings, respectively, while BDCM and dibromomethane (DBM) were the main VOXs in the soil of C. lanceolata seedlings. BDCM accounted for 31.9%, 38.2%, 40.9% and 37.2% of the VOXs content in each treatment, and DBM accounted for 17.9%, 16.5%, 19.2% and 16.0% of the VOXs content, respectively. Simulating elevated atmospheric CO₂ concentration and temperature was conducive to more comprehensive reflection of the ecological effect of global climate change, and it could provide data support for improving the VOCs flux model.

Key words: elevated CO₂ concentration, elevated temperature, volatile halogenated organic compounds (VOXs), volatile organic compounds (VOCs)

LIU Gui-zhen, SUN Hao-zhao, ZHAO Lin, MA Fang-yuan, CHEN Lin-yi, HUANG Xing-ran, FANG Xiong, YI Zhi-gang. Effect of elevated atmospheric CO₂ concentration and temperature on volatile halogenated organic compound content in soils of Schima superba and Cunninghamia lanceolata seedlings.[J]. Chinese Journal of Applied Ecology, 2022, 33(3): 757-764.

References 29

[1]	World Meteorological Organization (WMO). The state of green house gases in the atmosphere based on global observations through 2020. WMO Greenhouse Gas Bulletin, 2021, 17: 1-25
[2]	IPCC. Climate Change 2013: The Physical Science Basis: Working Group Ⅰ Contribution to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge University Press, 2013
[3]	马娉, 李如楠, 王斌, 等. 双季稻不同生育期净同化速率对大气CO2浓度和温度升高的响应. 应用生态学报, 2020, 31(3): 872-882
[4]	肖国举, 张强, 王静. 全球气候变化对农业生态系统的影响研究进展. 应用生态学报, 2007, 18(8): 1877-1885
[5]	Wester-Larsen L, Kramshøj M, Albers CN, et al. Biogenic volatile organic compounds in arctic soil: A field study of concentrations and variability with vegetation cover. Journal of Geophysical Research: Biogeosciences, 2020, 125, doi: 10.1029/2019JG005551
[6]	Tang J, Schurgers G, Rinnan R. Process understanding of soil BVOC fluxes in natural ecosystems: A review. Reviews of Geophysics, 2019, 57: 966-986
[7]	柳秋林. 渤海和北黄海中四种挥发性卤代烃的分布与通量研究. 硕士论文. 青岛: 中国海洋大学, 2015
[8]	何真, 倪洁, 杨桂朋. 海洋中挥发性卤代烃的研究进展. 中国海洋大学学报: 自然科学版, 2020, 50(3): 27-36
[9]	Abe M, Nagai T, Kurihara M, et al. Effect of temperature on the methyl chloride production rate in a marine phytoplankton, Phaeodactylum tricornutum. Journal of Atmospheric Chemistry, 2017, 74: 157-169
[10]	Sato N, Hamamoto K, Kurihara M, et al. Methyl halide production by cultures of marine thraustochytrids, Aurantiochytrium sp., Botryochytrium radiatum, and Schizochytrium sp. Marine Chemistry, 2019, 208: 95-102
[11]	Lin X, Xu C, Zhou Y, et al. A new perspective on volatile halogenated hydrocarbons in Chinese agricultural soils. Science of the Total Environment, 2020, 703: 134646
[12]	Zogg GP, Zak DR, Ringelberg DB, et al. Compositional and functional shifts in microbial communities due to soil warming. Soil Science Society of America Journal, 1997, 61: 475-481
[13]	Wingenter OW, Haase KB, Zeigler M, et al. Unexpected consequences of increasing CO2 and ocean acidity on marine production of DMS and CH2ClI: Potential climate impacts. Geophysical Research Letters, 2007, 34: L05710
[14]	Hopkins FE, Turner SM, Nightingale PD, et al. Ocean acidification and marine trace gas emissions. Proceedings of the National Academy of Sciences of the United States of America, 2010, 107: 760-765
[15]	Hopkins FE, Kimmance SA, Stephens JA, et al. Response of halocarbons to ocean acidification in the Arctic. Biogeosciences, 2013, 10: 2331-2345
[16]	向武, 邓南圣, 吴峰. 挥发性卤代烃的天然来源及其生成机制. 上海环境科学, 2003, 22(9): 623-628
[17]	中华人民共和国环境保护部. 土壤和沉积物. 挥发性有机物的测定. 吹扫捕集/气相色谱-质谱法(HJ 605—2011). 北京: 中国环境科学出版社, 2011
[18]	刘光崧. 土壤理化分析与剖面描述. 北京: 中国标准出版社, 1996
[19]	Chu HY, Paul G. Soil microbial biomass, nutrient availability and nitrogen mineralization potential among vegetation-types in a low arctic tundra landscape. Plant and Soil, 2010, 329: 411-420
[20]	Redeker RK, Wang NY, Low JC, et al. Emissions of methyl halides and methane from rice paddies. Science, 2000, 290: 966-969
[21]	宫健. 胶州湾潮滩湿地CHBr3和CHCl3通量特征及影响因素分析. 硕士论文. 青岛: 青岛大学, 2018
[22]	何姗, 刘娟, 姜培坤, 等. 全球变化对森林土壤甲烷吸收的影响及其机制研究进展. 应用生态学报, 2019, 30(2): 677-684
[23]	Roy R, Pratihary A, Narvenkar G, et al. The relationship between volatile halocarbons and phytoplankton pigments during a Trichodesmium bloom in the coastal eastern Arabian Sea. Estuarine, Coastal and Shelf Science, 2011, 95: 110-118
[24]	黄幸然, 谢承劼, 潘若琪, 等. 氮添加对马尾松和木荷幼苗根系土壤挥发性有机化合物的影响. 森林与环境学报, 2020, 40(3): 243-250
[25]	Wang X, Nakatsubo T, Nakane K. Impacts of elevated CO2 and temperature on soil respiration in warm temperate evergreen Quercus glauca stands: An open-top chamber experiment. Ecological Research, 2012, 27: 595-602
[26]	Dubbs LL, Whalen SC. Reduced net atmospheric CH4 consumption is a sustained response to elevated CO2 in a temperate forest. Biology and Fertility of Soils, 2010, 46: 597-606
[27]	Matamala R, Schlesinger WH. Effects of elevated atmospheric CO2 on fine root production and activity in an intact temperate forest ecosystem. Global Change Biology, 2000, 6: 967-979
[28]	Tiiva P, Tang J, Michelsen A, et al. Monoterpene emissions in response to long-term night-time warming, elevated CO2 and extended summer drought in a temperate heath ecosystem. Science of the Total Environment, 2017, 580: 1056-1067
[29]	刘远, 潘根兴, 张辉, 等. 大气CO2浓度和温度升高对麦田土壤呼吸和酶活性的影响. 农业环境科学学报, 2017, 36(8): 1484-1491

Effect of elevated atmospheric CO₂ concentration and temperature on volatile halogenated organic compound content in soils of Schima superba and Cunninghamia lanceolata seedlings.

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