[1] L Aguillaume, S Izquieta-Rojano, H García-Gómez et al. Dry deposition and canopy uptake in Mediterranean holm-oak forests estimated with a canopy budget model: A focus on N estimations. Atmospheric Environment, 152, 191-200(2017).
[2] I J Allan, B Vrana, R Greenwood et al. Strategic monitoring for the European water framework directive. Trends in Analytical Chemistry, 25, 704-715(2006).
[3] H V Andersen, M F Hovmand. Review of dry deposition measurements of ammonia and nitric acid to forest. Forest Ecology & Management, 114, 5-18(1999).
[4] B T Aulenbach, R P Hooper. The composite method: An improved method for stream-water solute load estimation. Hydrological Processes, 20, 3029-3047(2006).
[5] A R Baker, T Lesworth, C Adams et al. Estimation of atmospheric nutrient inputs to the Atlantic Ocean from 50°N to 50°S based on large-scale field sampling: Fixed nitrogen and dry deposition of phosphorus. Global Biogeochemical Cycles, 24, 1-16(2010).
[7] T J Battin, K Besemer, M M Bengtsson et al. The ecology and biogeochemistry of stream biofilms. Nature Reviews Microbiology, 14, 251-263(2016).
[8] N Baumgartner, G W Parkin, D E Elrick. Soil water content and potential measured by hollow time domain reflectometry probe. Soil Science Society of America Journal, 58, 315-318(1994).
[9] K Beven. Interflow: Unsaturated Flow in Hydrologic Modeling. Dordrecht: Springer, 275, 191-219(1989).
[11] W C Boughton. A review of the USDA SCS curve number method. Soil Research, 27, 511(1989).
[12] G Böttcher, H J Brumsack, H Heinrichs et al. A new high-pressure squeezing technique for pore fluid extraction from terrestrial soils. Water Air & Soil Pollution, 94, 289-296(1997).
[13] F M Brandi-Dohrn, M Hess, J S Selker et al. Field evaluation of passive capillary samplers. Soil Science Society of America Journal, 60, 1705-1713(1996).
[14] N Brauer, A O’Geen, R A Dahlgren. Temporal variability in water quality of agricultural tailwaters: Implications for water quality monitoring. Agricultural Water Management, 96, 1001-1009(2009).
[15] D W Cao. The pollution load flux estimation of Huanxiang River basin based on ArcGIS and MikeBasin model. Water Sciences and Engineering Technology, 64-67(2015).
[16] N W Chen, H S Hong, J Xiao et al. Dry deposition of atmospheric nitrogen to Jiulong River watershed in southeast China. Acta Ecologica Sinica, 26, 2602-2607(2006).
[17] Q Chen, S Gou, D Y Qin et al. An efficient method for automatic calibration of SWAT model parameters. Journal of Hydraulic Engineering, 39, 113-119(2010).
[19] A I Coppola, D B Wiedemeier, V Galy et al. Global-scale evidence for the refractory nature of riverine black carbon. Nature Geoscience, 11, 584-588(2018).
[20] J L W Cowan, W R Boynton. Sediment-water oxygen and nutrient exchanges along the longitudinal axis of Chesapeake Bay: Seasonal patterns, controlling factors and ecological significance. Estuaries, 19, 562-580(1996).
[22] Vries W de, H J Wieggers, D J Brus. Impacts of sampling design and estimation methods on nutrient leaching of intensively monitored forest plots in the Netherlands. Journal of Environmental Monitoring, 12, 1515-1523(2010).
[23] Vecchio J Del, K A Lang, C R Robins et al. Storage and weathering of landslide debris in the eastern San Gabriel Mountains, California, USA: Implications for mountain solute flux. Earth Surface Processes and Landforms, 43, 2724-2737(2018).
[24] C Demetriou, J F Punthakey. Evaluating sustainable groundwater management options using the MIKE SHE integrated hydrogeological modelling package. Environmental Modelling & Software, 14, 129-140(1998).
[25] F Dentener, J Drevet, J F Lamarque et al. Nitrogen and sulfur deposition on regional and global scales: A multimodel evaluation. Global Biogeochemical Cycles, 20, 1-21(2006).
[26] X Ding, Z Shen, Q Hong et al. Development and test of the export coefficient model in the upper reach of the Yangtze River. Journal of Hydrology, 383, 233-244(2010).
[28] A Eng, T Harner, K Pozo. A prototype passive air sampler for measuring dry deposition of polycyclic aromatic hydrocarbons. Environmental Science & Technology Letters, 1, 77-81(2013).
[29] J L Fan, Z Y Hu, T J Wang et al. Dynamics of dry deposition velocities of atmospheric nitrogen compounds in a broadleaf forestland. China Environmental Science, 29, 574-577(2009).
[30] J L Fan, Z Y Hu, S Y Zhuang et al. Observation of atmospheric nitrogen deposition into forestland. China Environmental Science, 27, 7-9(2007).
[31] M E Fenn, M A Poth. Monitoring nitrogen deposition in throughfall using ion exchange resin columns: A field test in the San Bernardino Mountains. Journal of Environmental Quality, 33, 2007-2014(2004).
[32] I R Ferguson. River loads underestimated by rating curves. Water Resources Research, 22, 74-76(1986).
[33] L Gao, J Y Chen, A P Zhu et al. Calculation of masses flux in a transboundary catchment based on SCS model: A case study in Shima River catchment, Dongguan City. China Environmental Science, 35, 925-933(2015).
[34] Q Z Gao, C D Shen. Study on river carbon flux and land erosion. Advances in Earth Science, 13, 369-375(1998).
[35] Q Z Gao, C D Shen, Y M Sun et al. A preliminary study on the organic carbon weathering fluxes in Beijiang River Drainage. Environmental Science, 22, 12-18(2001).
[37] Y Gao, Y L Jia, G R Yu et al. Anthropogenic reactive nitrogen deposition and associated nutrient limitation effect on gross primary productivity in inland water of China. Journal of Cleaner Production, 208, 530-540(2019).
[38] Y Gao, G Yu. Biogeochemical cycle and its hydrological coupling processes and associative controlling mechanism in a watershed. Acta Geographica Sinica, 73, 1381-1393(2018).
[41] R Giesler, U S Lundström, H L Grip. Comparison of soil solution chemistry assessment using zero‐tension lysimeters or centrifugation. European Journal of Soil Science, 47, 395-405(2010).
[43] B Grizzetti, F Bouraoui, K Granlund et al. Modelling diffuse emission and retention of nutrients in the Vantaanjoki watershed (Finland) using the SWAT model. Ecological Modelling, 169, 25-38(2003).
[44] J Grossmann, P Udluft. The extraction of soil water by the suction-cup method: A review. European Journal of Soil Science, 42, 83-93(2006).
[45] W C Gu. Principle and Application of Seepage Calculation.(2000).
[46] F Gui, G Yu, L Z Wang. Preliminary study on flux modeling of exogenous nitrogen and phosphorus into the upper reaches of Taihu Lake Basin. Resources and Environment in the Yangtze Basin, 23, 1265-1274(2014).
[47] P Gundersen, B A Emmett, O J Kjønaas et al. Impact of nitrogen deposition on nitrogen cycling in forests: A synthesis of NITREX data. Forest Ecology & Management, 101, 37-55(1998).
[48] C L Hao, Y X Deng, Y H Wang et al. Study on the selection and error analysis of riverine pollutant flux estimation methods. Acta Scientiae Circumstantiae, 32, 1670-1676(2012).
[51] B B Hicks, D D Baldocchi, T P Meyers et al. A preliminary multiple resistance routine for deriving dry deposition velocities from measured quantities. Water Air & Soil Pollution, 36, 311-330(1987).
[52] B B Hicks, M L Wesely, R L Coulter et al. An experimental study of sulfur and NO x fluxes over grassland. Boundary-Layer Meteorology, 34, 103-121(1986).
[56] W A House, F H Denison. Exchange of inorganic phosphate between river waters and bed-sediments. Environmental Science & Technology, 36, 4295-4301(2002).
[57] J Huang, Y Liu, T M Holsen. Comparison between knife-edge and frisbee-shaped surrogate surfaces for making dry deposition measurements: Wind tunnel experiments and computational fluid dynamics (CFD) modeling. Atmospheric Environment, 45, 4213-4219(2011).
[58] M Huettel, P Berg, J E Kostka. Benthic exchange and biogeochemical cycling in permeable sediments. Annual Review of Marine Science, 6, 23(2014).
[59] S Jan. The European carbon budget: A gap. Science, 302, 1681-1681(2003).
[60] P J Johnes. Evaluation and management of the impact of land use change on the nitrogen and phosphorus load delivered to surface waters: The export coefficient modelling approach. Journal of Hydrology, 183, 323-349(1996).
[61] P J Johnes. Uncertainties in annual riverine phosphorus load estimation: Impact of load estimation methodology, sampling frequency, baseflow index and catchment population density. Journal of Hydrology, 332, 241-258(2007).
[62] H Johnsson, L Bergstrom, P Jansson et al. Simulated nitrogen dynamics and losses in a layered agricultural soil. Agriculture Ecosystems & Environment, 18, 333-356(1987).
[63] A J Kettner, J P M Syvitski. HydroTrend v.3.0: A climate-driven hydrological transport model that simulates discharge and sediment load leaving a river system. Computers & Geosciences, 34, 1170-1183(2008).
[64] P M Kienzler, F Naef. Temporal variability of subsurface stormflow formation. Hydrology & Earth System Sciences Discussions, 4, 257-265(2008).
[65] M G Kim, Y M Hong, M H Kang et al. Estimation of dry deposition by using a filter pack method at Chunchon, Korea. Water Air & Soil Pollution, 130, 565-570(2001).
[66] J M Klopatek, M J Barry, D W Johnson. Potential canopy interception of nitrogen in the Pacific Northwest, USA. Forest Ecology & Management, 234, 344-354(2006).
[68] J Kovács, J Korponai, I S Kovács et al. Introducing sampling frequency estimation using variograms in water research with the example of nutrient loads in the Kis-Balaton Water Protection System (W Hungary). Ecological Engineering, 42, 237-243(2012).
[69] B Kronvang, A Bruhn. Choice of sampling strategy and estimation method for calculating nitrogen and phosphorus transport in small lowland streams. Hydrological Processes, 10, 1483-1501(1996).
[70] X M Lai, K H Liao, H H Feng et al. Responses of soil water percolation to dynamic interactions among rainfall, antecedent moisture and season in a forest site. Journal of Hydrology, 540, 565-573(2016).
[71] N Lambrecht, S Katsev, C Wittkop et al. Biogeochemical and physical controls on methane fluxes from two ferruginous meromictic lakes. Geobiology, 18, 54-69(2020).
[72] M S Landis, G J Keeler. Atmospheric mercury deposition to Lake Michigan during the Lake Michigan mass balance study. Environmental Science & Technology, 36, 4518-4524(2002).
[74] Z D Lei, S X Yang, S C Xie. Soil Water Dynamics(1988).
[75] A Li, Y Li, W Cheng et al. Caculation of agricultural non-point source of nitrogen and phosphorus loading from Tangxun lake watershed into the lake. Environmental Science & Technology, 113-117(2016).
[77] H J Li, A Jargon, Y Cheng et al. Estimating sediment flux in the Xinjiang River based on the load duration curve method. China Rural Water and Hydropower, 13-15(2012).
[78] J Z Li, T P Pei. Simulation and model of interflow on hillslope of forest catchment. Scientia Silvae Sinicae, 35, 2-8(1999).
[79] N Li, H Sheng, C J He et al. Estimation of pollutant flux in Baoxiang River based on LOADEST. Journal of Basic Science and Engineering, 20, 355-366(2012).
[80] Y Li, H P Li. Influence of landscape characteristics on non-point source pollutant output in Taihu upper-river basin. Environmental Science, 29, 1319-1324(2008).
[81] Y H Li, S Gregory. Diffusion of ions in sea water and in deep-sea sediments. Geochimica et Cosmochimica Acta, 38, 703-714(1974).
[82] Y S Liao, M N Zhuo, D Q Li et al. Estimation of urban non-point source pollution loading and its factor analysis in the Pearl River Delta. Environmental Science, 34, 3019-3024(2013).
[83] H-H Liu, L-J Bao, E Y Zeng. Recent advances in the field measurement of the diffusion flux of hydrophobic organic chemicals at the sediment-water interface. Trends in Analytical Chemistry, 54, 56-64(2014).
[84] L Liu. Study on atmospheric sedimentation flux in Taihu Lake of Jiangsu Province. China Resources Comprehensive Utilization, 36, 175-176, 179(2018).
[85] S Liu, W A Reiners, M Keller et al. Simulation of nitrous oxide and nitric oxide emissions from tropical primary forests in the Costa Rican Atlantic Zone. Environmental Modelling & Software, 15, 727-743(2000).
[86] W H Liu, C L Yang, Q Fu et al. Study on the flux of nutrients transporting into Dianchi Lake through Panlongjiang River. Environmental Protection and Technology, 17, 33-36(2011).
[87] G M Lovett. Atmospheric deposition of nutrients and pollutants in North America: An ecological perspective. Ecological Applications, 4, 630-650(1994).
[88] Y Lu, Y Gao, J J Jia et al. C and N transport flux and associated change of water quality parameters from multiscale subtropical watershed in Poyang Lake areas. Environmental Science, 40, 2696-2704(2019).
[89] W Ludwig, J-L Probst, S Kempe. Predicting the oceanic input of organic carbon by continental erosion. Global Biogeochemical Cycles, 10, 23-41(1996).
[90] S N Lyman, M S Gustin, E M Prestbo et al. Estimation of dry deposition of atmospheric mercury in Nevada by direct and indirect methods. Environmental Science & Technology, 41, 1970-1976(2007).
[91] J T Mao, X Z Hu. Measurement of dry deposition velocity of some pollutants in Nanchang Province of China. Meteorological Science and Technology, 36-42(1996).
[92] R Marques, J Ranger, D Gelhaye et al. Comparison of chemical composition of soil solutions collected by zero-tension plate lysimeters with those from ceramic-cup lysimeters in a forest soil. European Journal of Soil Science, 47, 407-417(2010).
[94] C Y Miao, D X Kong, J W Wu et al. Functional degradation of the water-sediment regulation scheme in the lower Yellow River: Spatial and temporal analyses. Science of the Total Environment, 551/552, 16-22(2016).
[95] D T Monteith, J L Stoddard, C D Evans et al. Dissolved organic carbon trends resulting from changes in atmospheric deposition chemistry. Nature, 450, 537-540(2007).
[97] P Moutonnet, J Pagenel, J Fardeau. Simultaneous field measurement of nitrate-nitrogen and matric pressure head. Soil Science Society of America Journal, 57, 1458-1462(1993).
[100] S Nishino, Y Kawaguchi, A Fujiwara et al. Biogeochemical anatomy of a cyclonic warm‐core eddy in the Arctic Ocean. Geophysical Research Letters, 45, 284-11,292(2018).
[101] F X Niu, S B Xiao, Y C Wang et al. Estimation of releasing fluxes of sediment phosphorous in the Three Gorges Reservoir during late autumn and early winter. Environmental Science, 34, 1308-1314(2013).
[102] C J Ottley, R M Harrison. The atmospheric input flux of trace metals to the North Sea: A review and recommendations for research. Science of the Total Environment, 100, 301-318(1991).
[104] Y Park, B Engel. Use of pollutant load regression models with various sampling frequencies for annual load estimation. Water, 6, 1685-1697(2014).
[105] Y Park, B Engel, J Frankenberger et al. A web-based tool to estimate pollutant loading using LOADEST. Water, 7, 4858-4868(2015).
[106] B A Pellerin, B A Bergamaschi, R J Gilliom et al. Mississippi River nitrate loads from high frequency sensor measurements and regression-based load estimation. Environmental Science & Technology, 48, 12612-12619(2014).
[109] N N Rabalais. Nitrogen in Aquatic Ecosystems. AMBIO: A Journal of the Human Environment, 31, 102-112(2002).
[110] S Rekolainen, M Posch, J Kämäri et al. Evaluation of the accuracy and precision of annual phosphorus load estimates from two agricultural basins in Finland. Journal of Hydrology, 128, 237-255(1991).
[112] K R Rolfhus, H E Sakamoto, L B Cleckner et al. Distribution and fluxes of total and methylmercury in Lake Superior. Environmental Science & Technology, 37, 865(2003).
[113] E Rydin. Potentially mobile phosphorus in Lake Erken sediment. Water Research, 34, 2037-2042(2000).
[114] I R Santos, B D Eyre, M Huettel. The driving forces of porewater and groundwater flow in permeable coastal sediments: A review. Estuarine Coastal & Shelf Science, 98, 1-15(2012).
[115] W H Schlesinger, J M Melack. Transport of organic carbon in the world’s rivers. Tellus, 33, 172-187(1981).
[116] H Sheng, J H Gao, Q Liu et al. Variation in water discharge and sediment load in the Yalu River catchment induced by human activities and climate changes. Marine Geology & Quaternary Geology, 52-61(2018).
[117] W P Sheng, G R Yu, H J Fang et al. Observation methods for atmospheric nitrogen deposition. Journal of Ecology, 29, 1671-1678(2010).
[118] W P Sheng, G R Yu, C Jiang et al. Monitoring nitrogen deposition in typical forest ecosystems along a large transect in China. Environmental Monitoring & Assessment, 185, 833-844(2013).
[119] J Šimůnek, M T van Genuchten, M Šejna. Recent developments and applications of the HYDRUS computer software packages. Vadose Zone Journal, 15, 1-25(2016).
[120] J Singh, H V Knapp, J G Arnold et al. Hydrological modeling of the Iroquois River watershed using HSPF and SWAT. Journal of the American Water Resources Association, 41, 343-360(2005).
[122] K Son, L Lin, L Band et al. Modelling the interaction of climate, forest ecosystem, and hydrology to estimate catchment dissolved organic carbon export. Hydrological Processes, 33, 1448-1464(2019).
[124] G A Stenback, W G Crumpton, K E Schilling et al. Rating curve estimation of nutrient loads in Iowa rivers. Journal of Hydrology, 396, 158-169(2011).
[125] R O Strobl, P D Robillard. Network design for water quality monitoring of surface freshwaters: A review. Journal of Environmental Management, 87, 639-648(2008).
[127] H G Sun, J T Han, S R Zhang et al. Effect of “05-06” Xijiang River extreme flood on carbon export flux. Chinese Science Bulletin, 51, 2773-2779(2006).
[128] J P Syvitski, M D Morehead, M Nicholson. Hydrotrend: A climate-driven hydrologic-transport model for predicting discharge and sediment load to lakes or oceans. Computers & Geosciences, 24, 51-68(1998).
[129] O Taikan, K Shinjiro. Global hydrological cycles and world water resources. Science, 313, 1068-1072(2006).
[130] K J Tobin, M E Bennett. Temporal analysis of Soil and Water Assessment Tool (SWAT) performance based on remotely sensed precipitation products. Hydrological Processes, 27, 505-514(2013).
[131] M J Tonkin, M C Hill, J Doherty. MODFLOW-2000, the U.S. Geological Survey modular ground-water model-Documentation of MOD-PREDICT for predictions, prediction sensitivity analysis, and evaluation of uncertainty. US Geological Society(2003).
[132] Meerveld H J Tromp-Van, J J Mcdonnell. Threshold relations in subsurface stormflow: 1. A 147-storm analysis of the Panola hillslope. Water Resources Research, 42(2006).
[133] M G Turner, R H Gardner, R V O'neill et al. Landscape Ecology in Theory and Practice. New York: Springer(2001).
[134] T Uchida, T V Meerveld, J J Mcdonnell. The role of lateral pipe flow in hillslope runoff response: An intercomparison of non-linear hillslope response. Journal of Hydrology, 311, 117-133(2005).
[135] A Ullrich, M Volk. Influence of different nitrate-N monitoring strategies on load estimation as a base for model calibration and evaluation. Environmental Monitoring and Assessment, 171, 513-527(2010).
[137] J J Voermans, M Ghisalberti, G N Ivey. A model for mass transport across the sediment-water interface. Water Resources Research, 54, 2799-2812(2018).
[138] E L Wang, S Q Wang, N Liu. Nitrate-nitrogen output flux simulation from different sandy soils in Western Liaohe River basin. Research of Environmental Sciences, 25, 165-172(2012).
[139] H Wang. Estimation of annual flux of pollutants in water quality section of the main stream of the Huaihe River. Water Resources Protection, 20, 37-39(2004).
[140] J L Wang, G Q Jiang, X W Ren et al. Investigation of monitoring strategies estimation methods for watershed pollutant fluxes. Environmental Protection of Xinjiang, 33, 1-7(2011).
[141] T J Wang, Z K Li. A method for calculating regional dry settlement velocity distribution of pollutants. Journal of Nanjing University (Natural Science), 745-752(1994).
[142] X Wang, B Cheng, Z J Yang et al. Differences in diffusive fluxes of nutrients from sediment between the natural river areas and reservoirs in the Lancang River basin. Environmental Science, 39, 2126-2134(2018).
[143] X Y Wang, F L Qin, Y Ou et al. SWAT-based simulation on non-point source pollution in the northern watershed of Miyun Reservoir. Journal of Agro-Environment Science, 27, 1098-1105(2008).
[144] B W Webb, J M Phillips, D E Walling et al. Load estimation methodologies for British rivers and their relevance to the LOIS RACS(R) programme. Science of the Total Environment, 194, 379-389(1997).
[145] I T Webster, S V Smith, J S Parslow. Implications of spatial and temporal variation for biogeochemical budgets of estuaries. Estuaries, 23, 341-350(2000).
[146] Q Weng. Modeling urban growth effects on surface runoff with the integration of remote sensing and GIS. Environmental Management, 28, 737-748(2014).
[147] M L Wesely, Hick et al. Review of the current status of knowledge on dry deposition. Atmospheric Environment, 34, 2261-2282(2000).
[148] J J J Wiltshire, C J Wright, J J Colls et al. Effects of heat balance stem-flow gauges and associated silicone compound on ash trees. Agricultural & Forest Meteorology, 73, 135-142(1995).
[149] F Worrall, T P Burt. Impact of land-use change on watar quality at the catchment scale: The use of export coefficient and structural models. Journal of Hydrology, 221, 75-90(1999).
[152] X Xiao, H W Wu, X Y Li. Research progress and prospects of subsurface flow. Journal of Arid Meteorology, 34, 391-402(2016).
[154] Z Z Xu, Y Xu, D Yu et al. Study of nitrogen and phospheorus fluxes into the sea from sluice-controlled river in plain urban area. Marine Environmental Science, 37, 819-825(2018).
[155] Z Yan, W Tijian, H Zhengyi et al. Temporal variety and spatial distribution of dry deposition velocities of typical air pollutants over different landuse types. Climatic and Environmental Research, 9, 591-604(2004).
[158] B F Zhang, D J Chen. Dynamic response of riverine nitrate flux to net anthropogenic nitrogen inputs in a typical river in Zhejiang province over the 1980-2010 period. Environmental Science, 35, 2911-2919(2014).
[159] D Zhang, H Duan, H X Yang et al. Study on the estimation of river pollutant flux in rural area. China Biogas, 33, 95-98(2015).
[160] H J Zhang, J H Cheng, Y H Shi et al. Response of preferential flow to rainfall on the forestland slope in the granite area of Three Gorges. Journal of Beijing Forestry University, 26, 6-9(2004).
[161] L Zhang, J R Brook, R Vet. A revised parameterization for gaseous dry deposition in air-quality models. Atmospheric Chemistry and Physics, 3, 2067-2082(2003).
[162] L Zhang, S Gong, J Padro et al. A size-segregated particle dry deposition scheme for an atmospheric aerosol module. Atmospheric Environment, 35, 549-560(2001).
[163] L Zhang, C X Fan, J J Wang et al. Space-time dependent variances of ammonia and phosphorus flux on sediment-water interface in Lake Taihu. Environmental Science, 27, 1537-1543(2006).
[164] L K Zhang, X Q Qin, H Yang et al. Transported fluxes of the riverine carbon and seasonal variation in Pearl River Basin. Environmental Science, 34, 3025-3034(2013).
[165] C C Zhao, S Y Zhang, X Z Mao. Variations of annual load of TN and TP in the deep bay watershed. Environmental Science, 4111-4117(2014).
[166] H Zhao, L Zhang, S Wang et al. Features and influencing factors of nitrogen and phosphorus diffusive fluxes at the sediment-water interface of Erhai Lake. Environmental Science and Pollution Research, 25, 1933-1942(2018).
[167] S Zhao, X Shi, C Li et al. Diffusion flux of phosphorus nutrients at the sediment-water interface of the Ulansuhai Lake in northern China. Water Science and Technology, 75, 1455-1465(2017).
[168] G W Zhu, B Q Qin, L Zhang et al. Wave effects on nutrient release of sediments from Lake Taihu by flume experiments. Journal of Lake Sciences, 17, 61-68(2005).
[169] J Y Zhu, Z Y Gao, X L Wang. Specifications for Water Measurement of Irrigation Canal System(2008).
[170] Q Zhu, X F Nie, X B Zhou et al. Soil moisture response to rainfall at different topographic positions along a mixed land-use hillslope. Catena, 119, 61-70(2014).