温带草地蒸散发及波文比观测与比较:涡动相关及波文比系统

doi:10.11733/j.issn.1007-0435.2017.03.002

草地学报 ›› 2017, Vol. 25 ›› Issue (3): 453-459.DOI: 10.11733/j.issn.1007-0435.2017.03.002

温带草地蒸散发及波文比观测与比较:涡动相关及波文比系统

王佩^1,2, 马琪顺², 王家琪², 黄洁钰², 李炜², 张赐成²

1. 北京师范大学地表过程与资源生态国家重点实验室, 北京 100875;
2. 北京师范大学地理科学学部资源学院, 北京 100875

收稿日期:2015-06-12 修回日期:2017-04-13 出版日期:2017-06-15 发布日期:2017-08-29
作者简介:王佩(1979-),男,甘肃张掖人,博士,副教授,研究方向为生态水文学,E-mail:peiwang@bnu.edu.cn
基金资助:
国家自然科学基金（41671019，41301014）资助

Comparison of Evapotranspiration and Bowen Ratio Measured by Eddy Correlation and Bowen Ratio System in a Temperate Grassland

WANG Pei^1,2, MA Qi-shun², WANG Jia-qi², HUANG Jie-yu², LI Wei², ZHANG Ci-cheng²

1. State Key Laboratory of Earth Surface Processes and Resource Ecology, Beijing Normal University, Beijing 100875, China;
2. School of Natural Resources, Faculty of Geographical Science, Beijing Normal University, Beijing 100875, China

Received:2015-06-12 Revised:2017-04-13 Online:2017-06-15 Published:2017-08-29

摘要/Abstract

摘要：

蒸散发的精确观测及估算是水资源管理及水文遥感验证的基础。该文利用已有的涡动塔观测数据集，配合波文比系统进行了同步观测，对二者观测的结果进行了对比分析。结果表明：涡动相关法和波文比方法估算的蒸散发均值及季节变动分别为298.73 ±128.58 W·m^-2 和 272.37 ±116.87 W·m^-2，整体而言这两种方法所观测的蒸散发较为一致，决定系数R²=0.75，平均相对误差小于6%。较涡动相关法，波文比方法估算潜热较低。生长季内，植被在生长初期及割草期出现明显的差别，表明波文比系统在植被生长旺盛期测量潜热效果更为稳定。两种方法估算的波文比具有相似的日变化及季节变动趋势。波文比存在明显的日变化及季节变动，其变动均值及标准差为0.21 ±0.42；其日变化与太阳辐射相关度较强（R²变动为0.41~0.52），其季节变化与叶面积指数（LAI）具有较高的非线性相关性（R²=0.65），而土壤水分对季节变动影响较小。该研究表明：在温带湿润草地生态系统，植被的生长很大程度上调节着该系统能量的分配。以上研究结果对波文比系统的实际应用具有一定的参考价值。

Abstract:

A reliable measurement for evapotranspiration and bowen ratio is critical to the development and validation of land surface models and remote sensing algorithms. To evaluate the two methods of estimating evapotranspiration rate and bowen ratio and its controls for a temperate-grassland ecosystem throughout a growing season, a comparative study was made using the methods of Energy Balanced Eddy Covariance (EBEC) and Energy Balanced Bowen-Ratio (BREB) to measure the evapotranspiration and bowen ratio. The results showed that:the average evapotranspiration and standard deviation measured by Eddy Covariance and BREB was 298.73±128.58 W·m^-2 and 272.37±116.87 W·m^-2, respectively, the error of BREB relative to Eddy Covariance was less than 6%, and the correlation between their half-hourly total evapotranspiration was significant (R²=0.75), suggesting that BREB was in good agreement with Eddy Covariance in the temperate grassland evapotranspiration measurement. Agreement between them demonstrated good performance of two approaches. The results suggested that the majority of daily latent heat fluxes was underestimated by EBBR method during growing season. The larger discrepancy was detected during the initial period and a period after grass cutting, which indicated that EBBR method was more stable during fast growing period. The bowen ratio estimated by EBBR and EBEC method displayed consistent diurnal and seasonal variations. Bowen ratio was mainly controlled by short-wave radiation at a diurnal timescale. Also, leaf area index was the primary controlling factor for bowen ratio at a seasonal timescale. Soil moisture at the study site was a minor factor with the moderately humid conditions. Our results emphasize that energy flow paths (i.e., latent heat flux) from temperate grasslands to the atmosphere are strongly controlled by the physiological responses of plants to solar radiation on a diurnal timescale and vegetation growth on a seasonal timescale. The above mentioned results provide scientific support for the practical application of the Bowen system.

Key words: Diurnal variations, Eddy Covariance (EC), Energy Balanced Bowen-Ratio (EBBR), Evapotranspiration, Seasonal variations

中图分类号:

S812

王佩, 马琪顺, 王家琪, 黄洁钰, 李炜, 张赐成. 温带草地蒸散发及波文比观测与比较:涡动相关及波文比系统[J]. 草地学报, 2017, 25(3): 453-459.

WANG Pei, MA Qi-shun, WANG Jia-qi, HUANG Jie-yu, LI Wei, ZHANG Ci-cheng. Comparison of Evapotranspiration and Bowen Ratio Measured by Eddy Correlation and Bowen Ratio System in a Temperate Grassland[J]. Acta Agrestia Sinica, 2017, 25(3): 453-459.

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参考文献

[1] Katul G G, R Oren, S Manzoni, et al. Evapotranspiration:A process driving mass transport and energy exchange in the soil-plant-atmosphere-climate system[J]. Reviews of Geophysics,2012,50(3):185-201
[2] Wang P, Yamanaka T. Application of a two-source model for partitioning evapotranspiration and assessing its controls in temperate grasslands in central Japan[J]. Ecohydrology,2014,7:345-353
[3] Yang D W, Gao B, Jiao Y, et al. A distributed scheme developed for eco-hydrological modeling in the upper Heihe River[J]. Science China:Earth Sciences,2015,58:36-45
[4] 肖春旺. 模拟降水量对毛乌素沙柳幼苗蒸发蒸腾的潜在影响[J]. 草地学报,2001,9(2):121-127
[5] 郭晓寅,程国栋. 遥感技术应用于地表面蒸散发的研究进展[J]. 地球科学进展,2004,01:107-114
[6] 吴炳方,熊隽,闫娜娜,等. 基于遥感的区域蒸散量监测方法——ETWatch[J]. 水科学进展,2008,05:671-678
[7] 张巧凤,刘桂香,于红博,等. 基于MOD16A2的锡林郭勒草原近14年的蒸散发时空动态[J]. 草地学报,2016,24(2):286-293
[8] Cheng G, Li X, Zhao W Z, et al. Integrated study of the water-ecosystem-economy in the Heihe River Basin[J]. National Science Review,2014,1(3):413-428
[9] Fisher J B, Melton F, Middleton E, et al. The Future of Evapotranspiration:Global requirements for ecosystem functioning,carbon and climate feedbacks,agricultural management,and water resources[J]. Water Resources Research,2017
[10] 杨学军,武菊英,滕文军,等. 负水头亏缺灌溉下4种苔草耗水量及抗旱性研究[J]. 草地学报,2011,19(4):607-611
[11] 邱国玉. 陆地生态系统中的绿水资源及其评价方法[J]. 地球科学进展,2008,07:713-722
[12] 司建华,冯起,张小由,等. 植物蒸散耗水量测定方法研究进展[J]. 水科学进展,2005,03:450-459
[13] Wilson K B, Hanson P J, Mulholland P J, et al. A comparison of methods for determining forest evapotranspiration and its components:sap-flow,soil water budget,eddy covariance and catchment water balance[J]. Agricultural & Forest Meteorology,2001,106(2):153-168
[14] Lee X, Black T A, Hartog G D, et al. Carbon dioxide exchange and nocturnal processes over a mixed deciduous forest[J]. Agricultural & Forest Meteorology,1996,81(1-2):13-29
[15] Pauwels V R N, Samson R. Comparison of different methods to measure and model actual evapotranspiration rates for a wet sloping grassland[J]. Agricultural Water Management,2006,82(1-2):1-24
[16] Horst T W, Weil J C. Footprint estimation for scalar flux measurements in the atmospheric surface layer[J]. Boundary-Layer Meteorology,1992,59(3):279-296
[17] Liu S M, Xu Z W, Wang W Z, et al. A comparison of eddy-covariance and large aperture scintillometer measurements with respect to the energy balance closure problem[J]. Hydrology & Earth System Sciences,2011,15(4):1291-1306
[18] Wang P, Yamanaka T, Li X Y, et al. Partitioning evapotranspiration in a temperate grassland ecosystem:Numerical modeling with isotopic tracers[J]. Agricultural & Forest Meteorology,2015,208:16-31
[19] Barr A G, King K M, Gillespie T J, et al. A comparison of bowen ratio and eddy correlation sensible and latent heat flux measurements above deciduous forest[J]. Boundary-Layer Meteorology,1994,71(1):21-41
[20] Shi T, Guan D, Wu J, et al. Comparison of methods for estimating evapotranspiration rate of dry forest canopy:Eddy covariance,Bowen ratio energy balance,and Penman-Monteith equation[J]. Journal of geophysical research-atmosphere,2008,113(D19):1050-1054
[21] Tang Y, Wen X, Sun X, et al. Interannual variation of the Bowen ratio in a subtropical coniferous plantation in southeast China,2003-2012[J]. Plos One,2014,9(2):e88267
[22] Hiyama T, Sugita M, Mikami M. Comparisons of the latent heat fluxes evaluated by a weighing lysimeter and an energy balance method[J]. Bulletin of the Environmental Research Center, the University of Tsukuba,1993,18:41-53
[23] Li S G, Lai C T, Lee G, et al. Evapotranspiration from a wet temperate grassland and its sensitivity to microenvironmental variables[J]. Hydrological Processes,2005,19(2):517-532
[24] Kyaw T P U, Baldocchi D D, Meyers T P, et al. Correction of eddy-covariance measurements incorporating both advective effects and density fluxes[J]. Boundary-Layer Meteorology,2000,97(3):487-511
[25] Schuepp P H, Leclerc M Y, Macpherson J I, et al. Footprint Prediction of Scalar Fluxes From Analytical Solutions of the Diffusion Equation[J]. Boundary-Layer Meteorology,1990,50(1):355-373
[26] Qiu G Y, Li C, Yan C. Characteristics of soil evaporation, plant transpiration and water budget of Nitraria,dune in the arid Northwest China[J]. Agricultural & Forest Meteorology,2015,203:107-117

温带草地蒸散发及波文比观测与比较:涡动相关及波文比系统

Comparison of Evapotranspiration and Bowen Ratio Measured by Eddy Correlation and Bowen Ratio System in a Temperate Grassland

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