The topographic wetness index (TWI), also known as the compound topographic index (CTI), is a steady state wetness index. It is commonly used to quantify topographic control on hydrological processes.[1] The index is a function of both the slope and the upstream contributing area per unit width orthogonal to the flow direction. The index was designed for hillslope catenas. Accumulation numbers in flat areas will be very large, so TWI will not be a relevant variable. The index is highly correlated with several soil attributes such as horizon depth, silt percentage, organic matter content, and phosphorus.[2] Methods of computing this index differ primarily in the way the upslope contributing area is calculated.
Definitionedit
The topographic wetness index is defined as:
where is the local upslope area draining through a certain point per unit contour length and is the local slope in radians. The TWI has been used to study spatial scale effects on hydrological processes. The topographic wetness index (TWI) was developed by Beven and Kirkby[3] within the runoff model TOPMODEL. Although the topographic wetness index is not a unitless number, it is sufficiently approximate that its interpretation doesn't rely on its physical units. Rather, it should be interpreted that areas with similar TWIs become saturated under similar moisture conditions, as described by Dr John Lindsay of the University of Guelph.[4]
Usesedit
The TWI has been used to study spatial scale effects on hydrological processes and to identify hydrological flow paths for geochemical modelling, as well as to characterize biological processes such as annual net primary production, vegetation patterns, and forest site quality.
Referencesedit
^Sørensen, R.; Zinko, U.; Seibert, J. (2006). "On the calculation of the topographic wetness index: evaluation of different methods based on field observations". Hydrology and Earth System Sciences. 10 (1): 101–112. Bibcode:2006HESS...10..101S. doi:10.5194/hess-10-101-2006.
^Moore, I.D.; Gessler, P.E.; Nielsen, G.A.; Petersen, G.A (1993). "Terrain attributes: estimation methods and scale effects.". In Jakeman, A.J.; Beck, M.B.; McAleer, M. (eds.). Modelling Change in Environmental Systems. London: Wiley. pp. 189–214.
^Beven, K.J.; Kirkby, M. J. (1979). "A physically based, variable contributing area model of basin hydrology". Hydrological Science Bulletin. 24 (1): 43–69. doi:10.1080/02626667909491834.
^Lindsay, John. "Response to: Getting Negative Topographic Wetness Index (TWI) values in SAGA GIS?". Stack Exchange Network. Retrieved 2023-07-25.
January 01, 1970
topographic, wetness, index, topographic, wetness, index, also, known, compound, topographic, index, steady, state, wetness, index, commonly, used, quantify, topographic, control, hydrological, processes, index, function, both, slope, upstream, contributing, a. The topographic wetness index TWI also known as the compound topographic index CTI is a steady state wetness index It is commonly used to quantify topographic control on hydrological processes 1 The index is a function of both the slope and the upstream contributing area per unit width orthogonal to the flow direction The index was designed for hillslope catenas Accumulation numbers in flat areas will be very large so TWI will not be a relevant variable The index is highly correlated with several soil attributes such as horizon depth silt percentage organic matter content and phosphorus 2 Methods of computing this index differ primarily in the way the upslope contributing area is calculated Definition editThe topographic wetness index is defined as ln a tan b displaystyle ln a over tan b nbsp where a displaystyle a nbsp is the local upslope area draining through a certain point per unit contour length and tan b displaystyle tan b nbsp is the local slope in radians The TWI has been used to study spatial scale effects on hydrological processes The topographic wetness index TWI was developed by Beven and Kirkby 3 within the runoff model TOPMODEL Although the topographic wetness index is not a unitless number it is sufficiently approximate that its interpretation doesn t rely on its physical units Rather it should be interpreted that areas with similar TWIs become saturated under similar moisture conditions as described by Dr John Lindsay of the University of Guelph 4 Uses editThe TWI has been used to study spatial scale effects on hydrological processes and to identify hydrological flow paths for geochemical modelling as well as to characterize biological processes such as annual net primary production vegetation patterns and forest site quality References edit Sorensen R Zinko U Seibert J 2006 On the calculation of the topographic wetness index evaluation of different methods based on field observations Hydrology and Earth System Sciences 10 1 101 112 Bibcode 2006HESS 10 101S doi 10 5194 hess 10 101 2006 Moore I D Gessler P E Nielsen G A Petersen G A 1993 Terrain attributes estimation methods and scale effects In Jakeman A J Beck M B McAleer M eds Modelling Change in Environmental Systems London Wiley pp 189 214 Beven K J Kirkby M J 1979 A physically based variable contributing area model of basin hydrology Hydrological Science Bulletin 24 1 43 69 doi 10 1080 02626667909491834 Lindsay John Response to Getting Negative Topographic Wetness Index TWI values in SAGA GIS Stack Exchange Network Retrieved 2023 07 25 Retrieved from https en wikipedia org w index php title Topographic wetness index amp oldid 1195366832, wikipedia, wiki, book, books, library,
