IMPACT OF EXTREME DROUGHT ON NET ECOSYSTEM EXCHANGE FROM LEMUS CHINENSIS STEPPE IN XILIN RIVER BASIN, CHINA

doi:10.17521/cjpe.2006.0113

Abstract

Abstract:

Background and Aims Many reports on global change have predicted major change in the temporal and spatial pattern of precipitation, which may have significant effects on temperate grasslands in arid and semi-arid regions. The responses of grasslands to environmental changes, especially amount and timing of precipitation, can be very different. Some studies indicate that drought may result in degradation of ecosystem function in NEE, even changing the ecosystem from a carbon sink to a carbon source.

Methods In order to quantify net ecosystem carbon exchange in Leymus chinensis steppe and its response to precipitation, we used the eddy covariance technique to measure carbon dioxide flux during the 2005 growing season in Xilin River Basin of Inner Mongolia Plateau in 2005. Only 126 mm precipitation fell during this growing season, far less than average; therefore, the steppe was in an extreme drought condition.

Key Results The daily pattern of CO₂ uptake in this drought year was consistent bimodal, with peaks at 8∶00 and 18∶00. In normal years, the bimodal pattern occurred only when soil water stress occurred. Maximum half-hourly average CO₂ uptake was -0.38 mg·m^-2·s^-1 in 2005, which was half that in typical growing seasons. Moreover, the ecosystem was a CO₂ source most of the growing season, releasing about 0.05 mg CO₂·m^-2·s^-1 at nighttime.

Conclusions The seasonal pattern of CO₂ uptake closely followed that of aboveground biomass and was strongly affected by soil temperature and soil water content. The ecosystem emitted 372.56 g CO₂·m^-2 during the growing season in 2005. The partial explanation is that much plant litter accumulated on the ground surface due to enclosure of the grassland since 1979, and this litter decomposed and resulted in a net release of CO₂ to atmosphere.

Key words: Extreme drought, Eddy covariance, CO₂ flux, Leymus chinensis steppe

HUANG Xiang-Zhong, HAO Yan-Bin, WANG Yan-Fen, ZHOU Xiao-Qi, HAN Xi, HE Jun-Jie. IMPACT OF EXTREME DROUGHT ON NET ECOSYSTEM EXCHANGE FROM LEMUS CHINENSIS STEPPE IN XILIN RIVER BASIN, CHINA[J]. Chin J Plant Ecol, 2006, 30(6): 894-900.

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URL: https://www.plant-ecology.com/EN/10.17521/cjpe.2006.0113

https://www.plant-ecology.com/EN/Y2006/V30/I6/894

Figures/Tables 6

Fig.1 Precipitation of the growing season in 2005 and means of 1970-2000 and the variation in soil water content in 0.2 m

Fig.2 The diurnal change of net ecosystem exchange (NEE) in 2005's growing season (we choose a typical day's data for each month)

Fig.3 The seasonal change of net ecosystem exchange (NEE) in 2005's growing season

Fig.4 The variation in the accumulative monthly NEE in 2005's growing season NEE: Net ecosystem exchange

Fig.5 The relationship between aboveground biomass and net ecosystem exchange of daytime (NEE) in 2005's growing season

Fig.6 The relationship between net ecosystem exchange (NEE) and soil temperature (Ts), photosynthetic active radiation (PAR)

References 28

[1]	Baldocchi DD (2003). Assessing the eddy covariance technique for evaluating carbon dioxide exchange rates of ecosystem :past, present and future. Global Change Biology, 9,479-492. DOI URL
[2]	Chen QS(陈全胜), Li LH(李凌浩), Han XG(韩兴国), Yan ZD(阎志丹), Wang YF(王艳芬) (2004). Temperature sensitivity of soil respiration in relation to soil moisture in 11 communities of typical temperate steppe in Inner Mongolia. Acta Ecologica Sinica(生态学报), 24,831-836. (in Chinese with English abstract)
[3]	Chen QS(陈全胜), Li LH(李凌浩), Han XG(韩兴国), Yan ZD(阎志丹), Wang YF(王艳芬), Yuan ZY(袁志友) (2003). Influence of temperature and soil moisture on soil respiration of a degraded steppe community in the Xilin River Basin of Inner Mongolia. Acta Phytoecologica Sinica(植物生态学报), 27,202-209. (in Chinese with English abstract)
[4]	Cui XY(崔骁勇), Du ZC(杜占池), Wang YF(王艳芬) (2000). Photosynthetic characteristics of a semi-arid sandy grassland community in Inner Mongolia. Acta Phytoecologica Sinica(植物生态学报), 24,541-546. (in Chinese with English abstract)
[5]	Dong YS(董云社), Zhang S(章申), Qi YC(齐玉春), Chen ZZ(陈佐忠), Geng YB(耿元波) (2000). The synchronous measurement and diurnal change of CO₂, N₂O, CH₄ over a typical steppe in Inner Mongolia. Chinese Science Bulletin(科学通报), 45,318-322. (in Chinese)
[6]	Dugas WA, Heuer ML, Mayeux HS (1999). Carbon dioxide fluxes over bermudagrass, native prairie, and sorghum. Agricultural and Forest Meteorology, 93,121-139. DOI URL
[7]	Du R(杜睿), Wang GC(王庚辰), Lu DR(吕达仁), Kong QX(孔琴心), Liu GR(刘广仁), Wan XW(万小伟), Zhang B(张斌), Wang YF(王艳芬), Ji BM(季宝明) (2001). A study of chamber method for in-site measurements of greenhouse gases emissions from grassland. Chinese Journal of Atmospheric Sciences (大气科学), 25,61-70. (in Chinese with English abstract) DOI URL
[8]	Du ZC(杜占池), Yang ZG(杨宗贵) (1988). A research on internal cause of photosynthetic reduction during midday period in Aneurolepidium chinense and Stipa grandis under drought soil condition. Research on Grassland Ecosystem(草原生态系统研究), 2,82-92. (in Chinese with English abstract)
[9]	Du ZC(杜占池), Yang ZG(杨宗贵) (1989). The reasons of midday photosynthetic depression in Aneurolepidium chinense and Stipa grandis under sufficient moisture in the soil. Acta Phytoecologica et Geobotanica Sinica(植物生态学与地植物学学报), 13,106-113. (in Chinese with English abstract)
[10]	Du ZC(杜占池), Yang ZG(杨宗贵) (1990). Reasons for midday photosynthetic depression for Aneurolepidium chinense and Stipa grandis. Reports from the Inner Mongolia Grassland Ecosystem Research Station of Academia Sinica (中国科学院内蒙古草原生态系统定位研究站报告). Science Press, Beijing, 181-185. (in Chinese with English abstract)
[11]	Falge E, Baldocchi DD, Olson R (2001) Gap filling strategies for defensible annual sums of net ecosystem exchange. Agricultural and Forest Meteorology, 107,43-69. DOI URL
[12]	Fay PA, Carlisle JD, Knapp AK, Blair JM, Collins SL (2003). Productivity responses to altered rainfall patterns in a C₄-dominated grassland. Oecologia, 137,245-251. URL PMID
[13]	GouldenML, MungerJW, FanSM (1996). Exchange of carbon dioxide by a deciduous forest: response to interannual climate variability. Science, 271,1576-1578. DOI URL
[14]	Hunt JE, Kelliher FM, McSeveny TM, Byers JN (2002). Evapotranspiration and carbon dioxide exchange between the atmosphere and a tussock grassland during a summer drought. Agricultural and Forest Meteorology, 11,65-82.
[15]	Jiang S(姜恕) (1985). An introduction on the Inner Mongolia grassland ecosystem research station, academia sinica. Reports from the Inner Mongolia Grassland Ecosystem Research Station of Academia Sinica (中国科学院内蒙古草原生态系统定位研究站报告). Science Press, Beijing, 1-11. (in Chinese with English abstract)
[16]	Kim J, Verma SB (1990). Carbon dioxide exchange in a temperate grassland ecosystem. Boundary-Layer Meteorology, 52,135-149. DOI URL
[17]	Li MF(李明峰), Dong YS(董云社), Qi YC(齐玉春), Geng YB(耿元波) (2004). Impact of extreme drought on the fluxes of CO₂, CH₄ and N₂O from temperate steppe ecosystems. Resources Science(资源科学), 26(3),89-95. (in Chinese with English abstract)
[18]	Meyers TP (2001). A comparison of summertime water and CO₂ fluxes over rangeland for well watered and drought conditions. Agricultural and Forest Meteorology, 106,205-214. DOI URL
[19]	Miranda AC, Miranda HS, Lloyd J, Grace J, Francey RJ, McIntyre JA, Meir P, Riggan P, Lockwood R, Brass J (1997). Fluxes of carbon, water and energy over Brazilian cerrado: an analysis using eddy covariance and stable isotopes. Plant, Cell and Environment, 20,315-328. DOI URL
[20]	Ojima DS, Dirks BOM, Glenn EP, Owensby CE, Scurlock JO (1993). Assessment of C budget for grasslands and drylands of the world. Water, Air, Soil Pollution, 70,95-109.
[21]	Sims PL, Bradford JA (2001). Carbon dioxide fluxes in a southern plains prairie. Agricultural and Forest Meteorology, 109,117-134. DOI URL
[22]	Valentini R, Matteucci G, Dolman AJ (2000). Respiration as the main determinant of carbon balance in European forests. Nature, 404,861-865. URL PMID
[23]	Webb EK, Pearman GI, Leuning R (1980). Correction of flux measurement for density effects due to heat and water vapour transfer. Quarterly Journal of the Royal Meteorological Society, 106,85-100. DOI URL
[24]	Weltzin JF, Loik ME, Williams SD, Fay PA (2003). Assessing the response of terrestrial ecosystems to potential changes in precipitation. BioScience, 53,941-952. DOI URL
[25]	Wilczak JM, Oncley SP, Stage SA (2001). Sonic anemometer tilt correction algorithms. Boundary-Layer Meteorology, 99,127-150. DOI URL
[26]	Xiao XM, Jiang S, Wang YF, Ojima DS, Bonham CD (1996). Temporal variation in aboveground biomass of Leymus chinense steppe from species to community levels in Xilin River Basin, Inner Mongolia, China. Vegetatio, 123,1-12. DOI URL
[27]	Xu LK, Baldocchi DD (2004). Seasonal variation in carbon dioxide exchange over a Mediterranean annual grassland in California. Agriculture and Forest Meteorology, 1232,79-96.
[28]	Xu SX(徐世晓), Zhao XQ(赵新全), Li YN(李英年), Zhao L(赵亮), Cao GM(曹广明), Tang YH(唐艳鸿), Gu S(古松), Wang QX(王勤学), Du MY(杜明远) (2004). Carbon dioxide exchange during growing season and dormant season of an alpine shrub on the Qinghai-Tibetan Plateau. Science in China Ser. D(中国科学D辑), 34(Suppl. Ⅱ),118-124.