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Journal of Geographical Sciences

, Volume 29, Issue 9, pp 1527–1547 | Cite as

Rainfall interception of typical ecosystems in the Heihe River Basin: Based on high temporal resolution soil moisture data

  • Chongyao Yang
  • Yongmei HuangEmail author
  • Engui Li
  • Zeqing Li
Article
  • 4 Downloads

Abstract

Rainfall interception is of great significance to the fully utilization of rainfall in water limited areas. Until now, studies on rainfall partitioning process of typical ecosystems in Heihe River Basin, one of the most important inland river basins in China, is still insufficient. In this study, six typical ecosystems were selected, namely alpine meadow, coniferous forest, mountain steppe, desert, cultivated crop, and riparian forest, in Heihe River Basin for investigation of the rainfall interception characteristics and their influencing factors, including rainfall amount, duration, and intensity, based on the gross rainfall and high temporal resolution soil moisture data obtained from 12 automatic observation sites. The results show that the average interception amount and average interception rate of the six ecosystems are significantly different: alpine meadow 6.2 mm and 45.9%, coniferous forest 7.4 mm and 69.1%, mountain steppe 3.5 mm and 37.3%, desert 3.5 mm and 57.2%, cultivated crop 4.5 mm and 69.1%, and riparian forest 2.6 mm and 66.7%, respectively. The rainfall amount, duration, and intensity all had impact on the process of rainfall interception. Among these three factors, the impact of rainfall amount was most significant. The responses of these ecosystems to the rainfall characteristics were also different. Analyzing rainfall interception with high temporal resolution soil moisture data is proved to be a feasible method and need further development in the future.

Keywords

rainfall interception Heihe River Basin soil moisture rainfall utilization 

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References

  1. Bellot J, Escarre A, 1998. Stemflow and throughfall determination in a resprouted Mediterranean holm-oak forest. Annales Des Sciences Forestieres, 55(7): 847–865.CrossRefGoogle Scholar
  2. Bogena H R, Herbst M, Huisman J A et al., 2010. Potential of wireless sensor networks for measuring soil water content variability. Vadose Zone Journal, 9(4): 1002–1013.CrossRefGoogle Scholar
  3. Campbell Scientific, 2006. CS616 and CS625 Water Content Reflectometers, Instruction Manual. Revison: 8/06.Google Scholar
  4. Carlyle-Moses D E, 2004. Throughfall, stemflow, and canopy interception loss fluxes in a semi-arid Sierra Madre Oriental matorral community. Journal of Arid Environments, 58(2): 181–202.CrossRefGoogle Scholar
  5. Cheng G D, Xiao H L, Fu B J et al., 2014. Advances in synthetic research on the eco-hydrological process of the Heihe River Basin. Advances in Earth Science, 29(4): 431–437. (in Chinese)Google Scholar
  6. Crockford R H, Richardson D P, 2000. Partitioning of rainfall into throughfall, stemflow and interception: Effect of forest type, ground cover and climate. Hydrological Processes, 14(16/17): 2903–2920.CrossRefGoogle Scholar
  7. David T S, Gash J H C, Valente F et al., 2006. Rainfall interception by an isolated evergreen oak tree in a Mediterranean savannah. Hydrological Processes, 20(13): 2713–2726.CrossRefGoogle Scholar
  8. Dekker C S, Rietkerk M, Bierkens F P M, 2007. Coupling microscale vegetation-soil water and macroscale vegetation-precipitation feedbacks in semiarid ecosystems. Global Change Biology, 13(3): 671–678.CrossRefGoogle Scholar
  9. Dunkerley D, 2008. Identifying individual rain events from pluviograph records: A review with analysis of data from an Australian dryland site. Hydrological Processes, 22(26): 5024–5036.CrossRefGoogle Scholar
  10. Famiglietti J S, Rudnicki J W, Rodell M, 1998. Variability in surface moisture content along a hillslope transect: Rattlesnake Hill, Texas. Journal of Hydrology, 210(1–4): 259–281.CrossRefGoogle Scholar
  11. Fan C R, Li C Y, Jia K L et al., 2015. Grass canopy interception of Hulun watershed under different grazing systems. Acta Ecologica Sinica, 35(14): 4716–4724. (in Chinese)Google Scholar
  12. Fu B J, Pan N Q, 2016. Integrated studies of physical geography in China: Review and prospects. Journal of Geographical Sciences, 26(7): 771–790.CrossRefGoogle Scholar
  13. Herbst M, Rosier P T W, McNeil D D et al., 2008. Seasonal variability of interception evaporation from the canopy of a mixed deciduous forest. Agriculture and Forest Meteorology, 148(11): 1655–1667.CrossRefGoogle Scholar
  14. Hu J Z, Li W Z, Zheng J L et al., 2004. Rainfall interception capability of canopy layer of main plant community in rehabilitation lands at southern foot of Qilian Mountain. Journal of Mountain Science, 22(4): 492–501. (in Chinese)Google Scholar
  15. Hu W, Chau H W, Qiu W W et al., 2017. Environmental controls on the spatial variability of soil water dynamics in a small watershed. Journal of Hydrology, 551. 47–55.CrossRefGoogle Scholar
  16. Li C J, Ren D X, Wang G X et al., 2009. Analysis of artificial precipitation interception over two meadow species on Qinghai-Tibet Plateau. Advances in Water Science, 20(6): 769–774. (in Chinese)Google Scholar
  17. Li X, Cheng G D, Liu S M et al., 2013. Heihe Watershed allied telemetry experimental research (HiWATER): Scientific objectives and experimental design. Bulletin of the American Meteorological Society, 94(8): 1145–1160.CrossRefGoogle Scholar
  18. Li X, Lu L, Cheng G D et al., 2001. Quantifying landscape structure of the Heihe River Basin, north-west China using FRAGSTATS. Journal of Arid Environments, 48(4): 521–535.CrossRefGoogle Scholar
  19. Li X Y, Yang Z P, Li Y T et al., 2009. Connecting ecohydrology and hydropedology in desert shrubs: Stemflow as a source of preferential flow in soils. Hydrology and Earth System Sciences, 13(7): 1133–1144.CrossRefGoogle Scholar
  20. Li X Y, Zhang S Y, Peng H Y et al., 2013. Soil water and temperature dynamics in shrub-encroached grasslands and climatic implications: Results from Inner Mongolia steppe ecosystem of north China. Agricultural and Forest Meteorology, 171/172(8): 20–30.CrossRefGoogle Scholar
  21. Liu B, Zhao W Z, 2009. Rainfall partitioning by desert shrubs in arid regions. Sciences in Cold and Arid Regions, 1(3): 215–229.Google Scholar
  22. Liu H, Zhao W Z, He Z B et al., 2015. Soil moisture dynamics across landscape types in an arid inland river basin of Northwest China. Hydrological Processes, 29(15): 3328–3341.CrossRefGoogle Scholar
  23. Liu S M, Li X, Xu Z W et al., 2018. The Heihe Integrated Observatory Network: A basin-scale land surface processes observatory in China. Vadose Zone Journal, 17. 180072.CrossRefGoogle Scholar
  24. Liu S M, Xu Z W, Wang W Z et al., 2011. A comparison of eddy-covariance and large aperture scintillometer measurements with respect to the energy balance closure problem. Hydrology and Earth System Sciences, 15(4): 1291–1306.CrossRefGoogle Scholar
  25. Liu Y Y, Peng H H, Meng W P et al., 2013. Artificial rainfall interception characteristics in alpine meadows under different grazing scenarios in the upper reach of Heihe River. Journal of Lanzhou University (Natural Sciences), 49(6): 799–806. (in Chinese)Google Scholar
  26. Liu Z W, Chen R S, Song Y X et al., 2012. Characteristics of rainfall interception for four typical shrubs in Qilian Mountain. Acta Ecologica Sinica, 32(4): 1337–1346. (in Chinese)CrossRefGoogle Scholar
  27. Llorens P, Domingo F, 2007. Rainfall partitioning by vegetation under Mediterranean conditions. A review of studies in Europe. Journal of Hydrology, 335(1/2): 37–54.CrossRefGoogle Scholar
  28. Loik M E, Breshears D D, Lauenroth W K et al., 2004. A multi-scale perspective of water pulses in dryland ecosystems: Climatology and ecohydrology of the western USA. Oecologia, 141(2): 269–281.CrossRefGoogle Scholar
  29. Ma Y J, Gao S Y, Li X Y et al., 2012. Rainfall canopy partitioning and its influencing factors of riparian shrub in the alpine region. Journal of Desert Research, 32(4): 963–971. (in Chinese)Google Scholar
  30. Martinez-Meza E, Whitford W G, 1996. Stemflow, throughfall and channelization of stemflow by roots in three Chihuahuan desert shrubs. Journal of Arid Environments, 32(3): 271–287.CrossRefGoogle Scholar
  31. Monson R K, Grant M C, Jaeger C H et al., 1992. Morphological causes for the retention of precipitation in the crowns of alpine plants. Environmental and Experimental Botany, 32(4): 319–327.CrossRefGoogle Scholar
  32. Navar J, Charles F, Jurado E, 1999. Spatial variations of interception loss components by Tamaulipan thornscrub in northeastern Mexico. Forest Ecology & Management, 124(2/3): 231–239.CrossRefGoogle Scholar
  33. Ochsner T E, Cosh M H, Cuenca R H et al., 2013. State of the art in large-scale soil moisture monitoring. Soil Science Society of America Journal, 77(6): 1888–1919.CrossRefGoogle Scholar
  34. Owens M K, Lyons R K, Alejandro C L, 2006. Rainfall partitioning within semiarid juniper communities: Effects of event size and canopy cover. Hydrological Processes, 20(15): 3179–3189.CrossRefGoogle Scholar
  35. Pan Q M, Tian S L, 2001. Water Resources in the Heihe Watershed. Zhengzhou: The Yellow River Press, 1–3. (in Chinese)Google Scholar
  36. Peng H H, Zhao C Y, Feng Z D et al., 2014. Canopy interception by a spruce forest in the upper reach of Heihe River basin, Northwestern China. Hydrological Processes, 28(4): 1734–1741.CrossRefGoogle Scholar
  37. Price A G, Carlyle-Moses D E, 2003. Measurement and modelling of growing-season canopy water fluxes in a mature mixed deciduous forest stand, southern Ontario, Canada. Agricultural and Forest Meteorology, 119(1/2): 69–85.CrossRefGoogle Scholar
  38. Shu J L, 2014. Rainfall redistribution in natural grassland community and its dominant species response in loess hilly-gully region [D]. Yangling: Northwest Agricultural and Forest University. (in Chinese)Google Scholar
  39. Soubie R, Heinesch B, Granier A et al., 2016. Evapotranspiration assessment of a mixed temperate forest by four methods: Eddy covariance, soil water budget, analytical and model. Agricultural and Forest Meteorology, 228/229: 191–204.CrossRefGoogle Scholar
  40. Staelens J, Schrijver A D, Verheyen K et al., 2008. Rainfall partitioning into throughfall, stemflow, and interception within a single beech (Fagus sylvatica L.) canopy: Influence of foliation, rain event characteristics, and meteorogly. Hydrological Processes, 22(1): 33–45.CrossRefGoogle Scholar
  41. Tan J L, Ma M G, Che T et al., 2009. A study of interception of Picea crassifolia based on different canopy closure. Advances in Earth Science, 24(7): 825–833. (in Chinese)Google Scholar
  42. Wan Y F, Liu X D, Wang S L et al., 2016. Rainfall canopy partitioning and its influencing factors of Picea cras-sifolia forest in the Qilian Mountains. Journal of Soil and Water Conservation, 30(5): 224–229. (in Chinese)Google Scholar
  43. Wang G, 2007. Effects of land-use changes on hydrological processes in the middle basin of the Heihe River, Northwest China. Hydrological Processes, 21(10): 1370–1382.CrossRefGoogle Scholar
  44. Wang T J, Liu Q, Franz E T et al., 2017. Spatial patterns of soil moisture from two regional monitoring networks in the United States. Journal of Hydrology, 552. 578–585.CrossRefGoogle Scholar
  45. Wang W Z, Xu Z W, Liu S M et al., 2009. The characteristics of heat and water vapor fluxes over different surfaces in the Heihe River Basin. Advances in Earth Science, 24(7): 714–723. (in Chinese)Google Scholar
  46. Wang X P, Li X R, Kang E S et al., 2003. The infiltration and redistribution of precipitation in revegetated sand dunes in the Tengger Desert, Shapotou, China. Acta Ecologica Sinica, 23(6): 1234–1241. (in Chinese)Google Scholar
  47. Wang X P, Li X R, Xiao H L et al., 2007. Effects of surface characteristics on infiltration patterns in an arid shrub desert. Hydrological Processes, 21(1): 72–79.CrossRefGoogle Scholar
  48. Weltzin E J, Mcpherson R G, 2000. Implications of precipitation redistribution for shifts in temperate savanna ecotones. Ecology, 81(7): 1902–1913.CrossRefGoogle Scholar
  49. Wohlfahrt G, Bianchi K, Cernusca A, 2006. Leaf and stem maximum water storage capacity of herbaceous plants in a mountain meadow. Journal of Hydrology, 319(1–4): 383–390.CrossRefGoogle Scholar
  50. Xu G C, Zhang T G, Li Z B et al., 2017. Temporal and spatial characteristics of soil water content in diverse soil layers on land terraces of the Loess Plateau, China. Catena, 158. 20–29.CrossRefGoogle Scholar
  51. Xu Z L, Feng Z D, Zhao C Y et al., 2013. The canopy rainfall interception in actual and potential distribution of Qinghai spruce (Picea crassifolia) forest. Journal of Hydrology and Hydromechanics, 61(1): 64–72.CrossRefGoogle Scholar
  52. Yang Y G, Xiao H L, Wei Y P et al., 2012. Hydrological processes in the different landscape zones of alpine cold regions in the wet season, combining isotopic and hydrochemical tracers. Hydrological Processes, 26(10): 1457–1466.CrossRefGoogle Scholar
  53. Yu K L, Pypker T G, Keim R F et al., 2012. Canopy rainfall storage capacity as affected by sub–alpine grassland degradation in the Qinghai-Tibetan Plateau, China. Hydrological Processes, 26(20): 3114–3123.CrossRefGoogle Scholar
  54. Zhang Y F, Wang X P, Hu R et al., 2015. Rainfall partitioning into throughfall, stemflow and interception loss by two xerophytic shrubs within a rain-fed re-vegetated desert ecosystem, northwestern China. Journal of Hydrology, 527. 1084–1095.CrossRefGoogle Scholar

Copyright information

© Science Press 2019

Authors and Affiliations

  • Chongyao Yang
    • 1
  • Yongmei Huang
    • 1
    Email author
  • Engui Li
    • 1
  • Zeqing Li
    • 1
  1. 1.State Key Laboratory of Earth Surface Processes and Resource Ecology, Faculty of Geographical ScienceBeijing Normal UniversityBeijingChina

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