Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Quantification of Curve Numbers for Arid Watersheds
https://orcid.org/0000-0003-0448-6442
https://orcid.org/0009-0001-0599-4003
https://orcid.org/0000-0001-7735-1448
https://orcid.org/0000-0002-7674-0852
Although the curve number (CN) method has been widely used in rainfall and runoff models, the physical interpretation of the CN method is still challenging, for instance how to estimate the potential maximum retention. This paper analyzed the historical rainfall and runoff event data from 1975 to 2021 for two arid to semiarid watersheds, the Santa Rita and the Lucky Hills experimental watersheds in Tucson, Arizona. As is well known, a constant CN for a watershed can be back-calculated by fitting the observed rainfall and runoff. This study found this constant CN increase with the ratio of initial abstraction. On the other hand, CN can also be back-calculated for each event using the observed rainfall and runoff. The event-based CN depends on precipitation, land use, types and density of vegetation, as well as soil properties. If assuming the potential maximum retention is equal to the cumulative infiltrated water in each rainfall event, we applied the Green–Ampt infiltration model to estimate the CN for each historical event and compared with the back-calculated event-based CN. We found that 71% of the calculated CNs fell in the 10% margin of error, and 88% were within the 20% margin of error compared with the observed data. This indicated that the retention in CN can be considered as the cumulative infiltrated water in each event and calculated using the soil properties and rainfall duration. This is the first physical-based quantitative interpretation of retention in CN that will enable the determination of CN for ungauged watersheds in remote areas.
This paper presents a theoretical-based approach to estimate the CN number. The CN number for a watershed of complex land uses can be approximated using an equation presented in the paper, which is dependent on the total infiltrated water and the duration of storm event. The estimated CN numbers can be used as input to hydrologic models [i.e., hydrologic modeling system (HMS) and kinematic runoff and erosion model (KINEROS)] for simulating surface runoff from rainfall events.
Quantification of Curve Numbers for Arid Watersheds
https://orcid.org/0000-0003-0448-6442
https://orcid.org/0009-0001-0599-4003
https://orcid.org/0000-0001-7735-1448
https://orcid.org/0000-0002-7674-0852
Although the curve number (CN) method has been widely used in rainfall and runoff models, the physical interpretation of the CN method is still challenging, for instance how to estimate the potential maximum retention. This paper analyzed the historical rainfall and runoff event data from 1975 to 2021 for two arid to semiarid watersheds, the Santa Rita and the Lucky Hills experimental watersheds in Tucson, Arizona. As is well known, a constant CN for a watershed can be back-calculated by fitting the observed rainfall and runoff. This study found this constant CN increase with the ratio of initial abstraction. On the other hand, CN can also be back-calculated for each event using the observed rainfall and runoff. The event-based CN depends on precipitation, land use, types and density of vegetation, as well as soil properties. If assuming the potential maximum retention is equal to the cumulative infiltrated water in each rainfall event, we applied the Green–Ampt infiltration model to estimate the CN for each historical event and compared with the back-calculated event-based CN. We found that 71% of the calculated CNs fell in the 10% margin of error, and 88% were within the 20% margin of error compared with the observed data. This indicated that the retention in CN can be considered as the cumulative infiltrated water in each event and calculated using the soil properties and rainfall duration. This is the first physical-based quantitative interpretation of retention in CN that will enable the determination of CN for ungauged watersheds in remote areas.
This paper presents a theoretical-based approach to estimate the CN number. The CN number for a watershed of complex land uses can be approximated using an equation presented in the paper, which is dependent on the total infiltrated water and the duration of storm event. The estimated CN numbers can be used as input to hydrologic models [i.e., hydrologic modeling system (HMS) and kinematic runoff and erosion model (KINEROS)] for simulating surface runoff from rainfall events.
Quantification of Curve Numbers for Arid Watersheds
https://orcid.org/0000-0003-0448-6442
https://orcid.org/0009-0001-0599-4003
https://orcid.org/0000-0001-7735-1448
https://orcid.org/0000-0002-7674-0852
Although the curve number (CN) method has been widely used in rainfall and runoff models, the physical interpretation of the CN method is still challenging, for instance how to estimate the potential maximum retention. This paper analyzed the historical rainfall and runoff event data from 1975 to 2021 for two arid to semiarid watersheds, the Santa Rita and the Lucky Hills experimental watersheds in Tucson, Arizona. As is well known, a constant CN for a watershed can be back-calculated by fitting the observed rainfall and runoff. This study found this constant CN increase with the ratio of initial abstraction. On the other hand, CN can also be back-calculated for each event using the observed rainfall and runoff. The event-based CN depends on precipitation, land use, types and density of vegetation, as well as soil properties. If assuming the potential maximum retention is equal to the cumulative infiltrated water in each rainfall event, we applied the Green–Ampt infiltration model to estimate the CN for each historical event and compared with the back-calculated event-based CN. We found that 71% of the calculated CNs fell in the 10% margin of error, and 88% were within the 20% margin of error compared with the observed data. This indicated that the retention in CN can be considered as the cumulative infiltrated water in each event and calculated using the soil properties and rainfall duration. This is the first physical-based quantitative interpretation of retention in CN that will enable the determination of CN for ungauged watersheds in remote areas.
This paper presents a theoretical-based approach to estimate the CN number. The CN number for a watershed of complex land uses can be approximated using an equation presented in the paper, which is dependent on the total infiltrated water and the duration of storm event. The estimated CN numbers can be used as input to hydrologic models [i.e., hydrologic modeling system (HMS) and kinematic runoff and erosion model (KINEROS)] for simulating surface runoff from rainfall events.
Quantification of Curve Numbers for Arid Watersheds
J. Hydrol. Eng.
Duan, Jennifer G. (Autor:in) / Arjmandi, Ali (Autor:in) / Canfield, Evan (Autor:in) / Demaria, Eleonora (Autor:in) / Goodrich, David C. (Autor:in) / Qi, Kun (Autor:in)
01.02.2025
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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