Concept, Application, and Approaches of Watershed Hydrological Resilience Assessment

Document Type : Technical paper

Authors

1 MSc Student of Watershed Management, Department of Natural Resources, Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran

2 Assistant Professor, Department of Natural Resources, Faculty of Agriculture and Natural Resources, Member of Water Management Research Center, University of Mohaghegh Ardabili, Ardabil, Iran

3 Associate Professor, Department of Natural Resources, Faculty of Agriculture and Natural Resources, Member of Water Management Research Center, University of Mohaghegh Ardabili, Ardabil, Iran

4 Assistant Professor, Department of Natural Resources, Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran

Abstract

Today, watersheds are severely affected by natural and man-made stresses, and their ability to recover and adapt to altered conditions depends on the resilience of watersheds. Therefore, due to the importance of this issue and the necessity to explain  management models in  order to promote resilience in the country's watersheds, the present paper aims to analyze the concept, application, and methods of hydrological resilience assessment as one of the resilience dimensions in comprehensive watershed management. Studies in this field are very limited worldwide but have an upward trend. Accordingly, the methods used to evaluate hydrological resilience have so far been limited to the use of simple compilation methods such as determining the arithmetic mean of some important hydrological indicators, using the Budyko curve and the Convex model. Budyko's curve analysis was mostly based on rainfall, evapotranspiration, and runoff production. But the convex model is used by considering the failure thresholds of hydrological indicators and establishing a relation between the process of long-term changes and the failure thresholds of indicators. The indicators used are multitude and have different applications depending on the hydrological conditions of each watershed. Among the most important of them can be the ratio of drought index to runoff, temporal trend and frequency of low and high water flow, change in annual water yield, groundwater level, surface runoff intensity, river enrichment from nutrients, and heavy metals, forest degradation percentage, soil erosion, sediment yield, and saline water levels are all the result of the interaction of other influential environmental factors, such as climatic, ecological, economic, biophysical and social.

Keywords

Main Subjects

References

Adger W.N. 2000. Social and ecological resilience: are they related? Progress in Human Geography, 24: 347-364.
Black P.E. 1997. Watershed functions. Journal of the American Water Resources Association, 33(10):1-11.
Budyko M. I. 1974. Climate and life. ed. Miller, D.H. Academic Press: New York, NY, USA.
Creed I.F., Spargo A.T., Jones J.A., Buttle J.M., Adams M.B., Beall F.D., Booth E., Campbell J., Clow D., Elder K., Green M.B., Grimm N.B., Miniat C., Ramlal P., Saha A., Sebestyen S., Spittlehouse D., Sterling S., Williams M.W., Winkler R. and Yao H. 2014. Changing forest water yields in response to climate warming: results from long-term experimental watershed sites across North America. Global Change Biology, 20: 3191–3208.
De Carvalho J.W.L.T., Iensen I.R.R. and dos Santos I. 2021. Resilience of hydrologic similarity areas to extreme climate change scenarios in an urban watershed. Urban Water Journal, 1–12.
Ebel B.A. and Mirus B.B. 2014. Disturbance hydrology: Challenges and opportunities. Hydrological Processes, 28(19): 5140-5148.
Folke C., Carpenter S., Elmqvist T., Gunderson L., Holling C.S., Walker B., Bengtsson J., Berkes F., Colding J., Danell K., Falkenmark M., Gordon L., Kasperson R., Kautsky N., Kinzig A., Levin S., Maler K.G., Moberg F., Ohlsson L., Olsson P., Ostrom E., Reid W., Rockstrom J., Savenije H. and Svedin U. 2002. Resilience and sustainable development: building adaptive capacity in a world of transformations. Journal of the Human Environment, 31(5): 437-440.
Gerten D., Lucht W., Schaphoff S., Cramer W., Hickler T. and Wagner W. 2005. Hydrologic resilience of the terrestrial biosphere. Geophysical Research Letters, 32: L21408.
Green M. 2014. The Hydrological resilience of temperate forests. Resources‐Resilience‐Renewal‐Restoration. 94th Annual Winter Meeting, New England, Society of American Foresters.
Helman D., Lensky I.M., Yakir D. and Osem Y. 2017. Forests growing under dry conditions have higher hydrological resilience to drought than do more humid forests. Global Change Biology, 23: 2801–2817.
Holling C.S. 1973. Resilience and stability of ecological systems. Annual Review of Ecology and Systematics, 4: 1-23.
Holling C.S., Schindler D.W., Walker B.W. and Roughgarden J. 1995. Biodiversity in the functioning of ecosystems: an ecological synthesis. Biodiversity Loss: Economic and Ecological Issues. First Edition. Cambridge University Press, Cambridge, England.
Holling C.S. 2001, Understanding the complexity of economic, ecological, and social systems. Ecosystems, 4: 390-405.
IPCC. 2014. Climate Change 2014: Synthesis Report, in Contribution of Working Groups, I., II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, eds R.K. Pachauri, and L.A. Meyer (Geneva).
IPCC. 2018. Global Warming of 1.5°C, an IPCC Special Report on the Impacts of Global Warming of 1.5 C Above pre-Industrial levels (SR1.5). Geneva: Intergovernmental Panel on Climate Change (IPCC).
IPCC. Summary for Policymakers. In: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [Masson-Delmotte, V., P. Zhai, A. Pirani, S. L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M. I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T. K. Maycock, T. Waterfield, O. Yelekçi, R. Yu and B. Zhou (eds.)]. Cambridge University Press. Cambridge, England.
Javadinejad S., Hannah D., Krause S., Naseri M., Dara R. and Jafary F. 2020. Building socio-hydrological resilience “improving capacity for building a socio hydrological system resilience.” Safety in Extreme Environments, 2: 205–218. 
Jiang C., Ni B., Han X. and Tao Y. 2014. Non-probabilistic convex model process: a new method of time-variant uncertainty analysis and its application to structural dynamic reliability problems. Computer Methods in Applied Mechanics and Engineering, 268: 656–676.
Krievins K., Baird J., Plummer R.,  Brandes O., Curry A., Imhof J., Mitchell S., Moore M.L., Gerger Swartling A. 2015. Resilience in a Watershed Governance Context: A Primer. Environmental Sustainability Research Centre. Project report.
Kumar P., Avtar R., Dasgupta R., Johnson B.A., Mukherjee A., Ahsan M.N., Nguyen D.C.H., Nguyen H.Q., Shaw R. and Mishra, B.K., 2020. Socio-hydrology: A key approach for adaptation to water scarcity and achieving human well-being in large riverine islands. Progress in Disaster Science, 8:100134.
Liu J., Xue B.A.Y., Sun W. and Guo Q., 2020. Water balance changes in response to climate change in the upper Hailar River Basin, China. Hydrology Research, 51(5): 1023–1035.
MacDonald R., Marcotte D., Chernos M., Carlson M. and Adrain C. 2019. Strategic priorities for conservation and restoration to improve watershed resiliency in the Vermilion River Watershed. Prepared for the North Saskatchewan Watershed Alliance, Project report.
Mao F., Clark J., Karpouzoglou T., Dewulf A., Buytaert W. and Hannah, D. 2017. HESS Opinions: A conceptual framework for assessing socio-hydrological resilience under change. Hydrology and Earth System Sciences, 21: 3655–3670.
Muñoz-Villers L.E., Holwerda F., Gomez-Cardenas M., Equihua M., Asbjornsen H., Bruijnzeel L.A., Marin-Castro B.E., and Tobon C. 2012. Water balances of old growth and regenerating Montane cloud forests in central Veracruz, Mexico, Journal of Hydrology, 462–463: 53–66.
Ostrom E. 2009. A general framework for analyzing sustainability of social-ecological systems. Science, 325(5939): 419-422.
Pan S., Tian H., Dangal S.R.S., Yang Q., Yang J., Lu C., Tao B., Ren W. and Ouyang Z. 2015. Responses of global terrestrial evapotranspiration to climate change and increasing atmospheric CO2 in the 21st century, Earth’s Future, 3: 15–35.
Pelorosso R., Gobattoni F. and Leone, A. 2018. Increasing hydrological resilience employing nature-based solutions: a modelling approach to support spatial planning. Chapter, In: Papa R., Fistola R., Gargiulo C. (eds) Smart Planning: Sustainability and Mobility in the Age of Change, Green Energy and Technology. Springer, Cham.
Pimm S.L. 1991. Balance of nature? The University of Chicago Press. Chicago. First Edition. Illinois, USA.
Poff N.L., Allan J.D., Bain M.B., Karr J.R., Prestegaard K.L., Richter B.D., Sparks R.E., and Stromberg J. 1997. The natural flow regime: a paradigm for river conservation and restoration. BioScience, 47: 769–784.
Randhir T.O. 2014. Resilience of watershed systems to climate change. Journal of Earth Science and Climatic Change, 5: 6.
Sinha J., Sharma A., Khan M. and Goyal M.K. 2018. Assessment of the impacts of climatic variability and anthropogenic stress on hydrologic resilience to warming shifts in Peninsular India. Scientific Reports, 8(1): 13833.
Van Rooyen J.D. 2021. Investigating regional recharge dynamics through the use of tritium and radiocarbon isotopes to assess the hydrological resilience of groundwater in southern Africa. Stellenbosch University, PhD thesis.
Wagener T., Sivapalan M., Troch P. and Woods R. 2007. Catchment classification and hydrologic similarity. Geography Compass, 1(4): 901-931.
Xue B., Wang G., Xiao J., Helman D., Sun W., Wang J. and Liu T. 2020. Global convergence but regional disparity in the hydrological resilience of ecosystems and watersheds to drought. Journal of Hydrology, 591: 125589.‏
Xue B., Helman D., Wang G., Xu C.Y., Xiao J., Liu T. and Lei H. 2021. The low hydrologic resilience of Asian Water Tower basins to adverse climatic changes. Advances in Water Resources, 155: 103996.‏
Zhang Y., Peña-Arancibia J.L., McVicar T.R., Chiew F.H., Vaze J., Liu C., Lu X., Zheng H., Wang Y., Liu Y.Y., Miralles D.G. and Pan, M. 2016. Multi-decadal trends in global terrestrial evapotranspiration and its components. Scientific Reports, 6: 19124.
Zhang Y., Li W., Sun G. and King J.S. 2019. Coastal wetland resilience to climate variability: A hydrologic perspective. Journal of Hydrology, 568: 275-284.
Zhou Y., Zhang L., Fensholt R., Wang K., Vitkovskaya I. and Tian F. 2015. Climate contributions to vegetation variations in Central Asian Drylands: pre- and post-USSR Collapse. Remote Sensing, 7: 2449–2470.
Zhu S., Li D., Huang G., Chhipi-Shrestha G., Nahiduzzaman K.M., Hewage K. and Sadiq R. 2021. Enhancing urban flood resilience: A holistic framework incorporating historic worst flood to Yangtze River Delta, China. International Journal of Disaster Risk Reduction, 61: 102355.
Send comment about this article
CAPTCHA Image
Journal of Water and Sustainable Development
Volume 8, Issue 4 - Serial Number 22
Climate change has exacerbated extreme events
March 2022
Pages 99-110

Files

History

  • Receive Date: 16 June 2021
  • Revise Date: 30 September 2021
  • Accept Date: 02 October 2021

Share

How to cite

Statistics