[1] Zeng J. The Characteristics and Parameterization of Land Surface Processes and Its Relationship with Climate over Northern China[D](2011).

[2] Swinbank W C. The measurement of vertical transfer of heat and water vapor by eddies in the lower atmosphere[J]. Journal of Atmospheric Sciences, 8, 135-145(1951).

[3] Han X. Research on Variation Law of Sensible Heat Flux in Typical Farmland Based on Large Aperture Scintillometer[D](2017).

[4] Liu S M, Li X W, Shi S J et al. Measurement, analysis and application of surface energy and water vapor fluxes at large scale[J]. Advances in Earth Science, 25, 1113-1127(2010).

[5] Zhang G. Research on Kilometer-Scale Evapotranspiration of A Hilly Plantation in North China[D](2019).

[6] Komarudin N A, June T, Meijide A. Sensible heat flux of oil palm plantation: Comparing aerodynamic and Penman-Monteith methods[J]. IOP Conference Series: Earth and Environmental Science, 54, 12007(2017).

[7] Vendrame N, Tezza L, Pitacco A. Comparison of sensible heat fluxes by large aperture scintillometry and eddy covariance over two contrasting-climate vineyards[J]. Agricultural and Forest Meteorology, 288, 108002(2020).

[8] Liu Y, Qiu G, Zhang H et al. Shifting from homogeneous to heterogeneous surfaces in estimating terrestrial evapotranspiration: Review and perspectives[J]. Science China (Earth Sciences), 65, 197-214(2022).

[9] Ochs G R, Wilson J J[M]. A Second-Generation Large-Aperature Scintillometer, 11(1993).

[10] Beyrich F, De Bruin H A R, Meijninger W M L et al. Results from one-year continuous operation of a large aperture scintillometer over a heterogeneous land surface[J]. Boundary-Layer Meteorology, 105, 85-97(2002).

[11] Wesely M L. The combined effect of temperature and humidity fluctuations on refractive index[J]. Journal of Applied Meteorology, 15, 43-49(1976).

[12] Bai J, Liu S M, Ding X P et al. A study of the processing method of large aperture scintillometer observation data[J]. Advances in Earth Science, 25, 1148-1165(2010).

[13] Qi F F, Liu Y Q, Ali M et al. Estimation of surface energy flux using surface energy system (SEBS) in the Taklimakan Desert regions[J]. Journal of Arid Land Resources and Environment, 33, 128-133(2019).

[14] Guo Y, Zuo H. Impact of mesoscale motions on Monin‐Obukhov similarity and surface energy balance over a homogeneous surface[J]. Advances in Meteorology, 2017, 6425695(2017).

[15] Dyer A J. A review of flux-profile relationships[J]. Boundary-Layer Meteorology, 7, 363-372(1974).

[16] Lu L, Liu S M, Xu Z W et al. Results from measurements of large aperture scintillometer over different surfaces[J]. Journal of Applied Meteorological Science, 20, 171-178(2009).

[17] Zhang Y, Jia Z Z, Liu S M et al. Advances in validation of remotely sensed land surface evapotranspiration[J]. Journal of Remote Sensing, 24, 975-999(2020).

[18] Von Randow C, Kruijt B, Holtslag A A M et al. Exploring eddy-covariance and large-aperture scintillometer measurements in an Amazonian rain forest[J]. Agricultural and Forest Meteorology, 148, 680-690(2008).

[19] Zheng N. Forest Ecosystem Turbulent Analysis for Improving Calculation Accuracy of Sensible Flux With Scintillometers Method[D](2013).

[20] Zhang Q, Yue Q H, Dong X H et al. The application of remote sensing data to the SWAT model enhances its accuracy of evapotranspiration and runoff simulations[J]. Journal of Water Resources and Water Engineering, 31, 37-44(2020).

[21] He T, Shao Q Q. Spatial-temporal variation of terrestrial evapotranspiration in China from 2001 to 2010 using MOD16 products[J]. Journal of Geo-Information Science, 16, 979-988(2014).