Integration of aspect and slope in snowmelt runoff modeling in a mountain watershed

This study assessed the performances of the traditional temperature-index snowmelt runoff model (SRM) and an SRM model with a finer zonation based on aspect and slope (SRM t AS model) in a data-scarce mountain watershed in the Urumqi River Basin, in Northwest China.The proposed SRM t AS model was us...

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Published inWater Science and Engineering Vol. 9; no. 4; pp. 265 - 273
Main Authors Abudu, Shalamu, Sheng, Zhu-ping, Cui, Chun-liang, Saydi, Muatter, Sabzi, Hamed-Zamani, King, James Phillip
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.10.2016
Texas A&M AgriLife Research and Extension Center at El Paso,El Paso,TX 79927-5020,USA
Xinjiang Water Resources Research Institute,Urumqi 830049,China%Texas A&M AgriLife Research and Extension Center at El Paso,El Paso,TX 79927-5020,USA%Xinjiang Water Resources Research Institute,Urumqi 830049,China%Civil Engineering Department,New Mexico State University,Las Cruces,NM 88003-8006,USA
Elsevier
Subjects
and
area
Aspect
Aspect and slope
cover
DDF
Degree-day
Degree-day factor (DDF)
factor
Precipitation
runoff
slope
Snow
Snow cover area
Snowmelt
Snowmelt runoff model (SRM)
SRM
Temperature
Temperature
Precipitation
Aspect and slope
Snow cover area
Snowmelt runoff model (SRM)
Degree-day factor (DDF)
Online AccessGet full text
ISSN1674-2370
2405-8106
2405-8106
DOI10.1016/j.wse.2016.07.002

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Abstract This study assessed the performances of the traditional temperature-index snowmelt runoff model (SRM) and an SRM model with a finer zonation based on aspect and slope (SRM t AS model) in a data-scarce mountain watershed in the Urumqi River Basin, in Northwest China.The proposed SRM t AS model was used to estimate the melt rate with the degree-day factor (DDF) through the division of watershed elevation zones based on aspect and slope. The simulation results of the SRM t AS model were compared with those of the traditional SRM model to identify the improvements of the SRM t AS model's performance with consideration of topographic features of the watershed. The results show that the performance of the SRM t AS model has improved slightly compared to that of the SRM model. The coefficients of determination increased from 0.73, 0.69, and 0.79 with the SRM model to 0.76, 0.76, and 0.81 with the SRM t AS model during the simulation and validation periods in 2005, 2006, and 2007, respectively. The proposed SRM t AS model that considers aspect and slope can improve the accuracy of snowmelt runoff simulation compared to the traditional SRM model in mountain watersheds in arid regions by proper parameterization, careful input data selection, and data preparation.
AbstractList This study assessed the performances of the traditional temperature-index snowmelt runoff model (SRM) and an SRM model with a finer zonation based on aspect and slope (SRM + AS model) in a data-scarce mountain watershed in the Urumqi River Basin, in Northwest China. The proposed SRM + AS model was used to estimate the melt rate with the degree-day factor (DDF) through the division of watershed elevation zones based on aspect and slope. The simulation results of the SRM + AS model were compared with those of the traditional SRM model to identify the improvements of the SRM + AS model's performance with consideration of topographic features of the watershed. The results show that the performance of the SRM + AS model has improved slightly compared to that of the SRM model. The coefficients of determination increased from 0.73, 0.69, and 0.79 with the SRM model to 0.76, 0.76, and 0.81 with the SRM + AS model during the simulation and validation periods in 2005, 2006, and 2007, respectively. The proposed SRM + AS model that considers aspect and slope can improve the accuracy of snowmelt runoff simulation compared to the traditional SRM model in mountain watersheds in arid regions by proper parameterization, careful input data selection, and data preparation.
This study assessed the performances of the traditional temperature-index snowmelt runoff model (SRM) and an SRM model with a finer zonation based on aspect and slope (SRM t AS model) in a data-scarce mountain watershed in the Urumqi River Basin, in Northwest China.The proposed SRM t AS model was used to estimate the melt rate with the degree-day factor (DDF) through the division of watershed elevation zones based on aspect and slope. The simulation results of the SRM t AS model were compared with those of the traditional SRM model to identify the improvements of the SRM t AS model's performance with consideration of topographic features of the watershed. The results show that the performance of the SRM t AS model has improved slightly compared to that of the SRM model. The coefficients of determination increased from 0.73, 0.69, and 0.79 with the SRM model to 0.76, 0.76, and 0.81 with the SRM t AS model during the simulation and validation periods in 2005, 2006, and 2007, respectively. The proposed SRM t AS model that considers aspect and slope can improve the accuracy of snowmelt runoff simulation compared to the traditional SRM model in mountain watersheds in arid regions by proper parameterization, careful input data selection, and data preparation.
This study assessed the performances of the traditional temperature-index snowmelt runoff model (SRM) and an SRM model with a finer zonation based on aspect and slope (SRM + AS model) in a data-scarce mountain watershed in the Urumqi River Basin,in Northwest China.The proposed SRM + AS model was used to estimate the melt rate with the degree-day factor (DDF) through the division of watershed elevation zones based on aspect and slope.The simulation results of the SRM + AS model were compared with those of the traditional SRM model to identify the improvements of the SRM + AS model's performance with consideration of topographic features of the watershed.The results show that the performance of the SRM + AS model has improved slightly compared to that of the SRM model.The coefficients of determination increased from 0.73,0.69,and 0.79 with the SRM model to 0.76,0.76,and 0.81 with the SRM + AS model during the simulation and validation periods in 2005,2006,and 2007,respectively.The proposed SRM + AS model that considers aspect and slope can improve the accuracy of snowmelt runoff simulation compared to the traditional SRM model in mountain watersheds in arid regions by proper parameterization,careful input data selection,and data preparation.
Author Shalamu Abudu;Zhu-ping Sheng;Chun-liang Cui;Muatter Saydi;Hamed-Zamani Sabzi;James Phillip King
AuthorAffiliation Texas A&M AgriLife Research and Extension Center at El Paso, El Paso, TX 79927-5020, USA;Xinjiang Water Resources Research Institute, Urumqi 830049, China;Civil Engineering Department, New Mexico State University, Las Cruces, NM 88003-8006, USA
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Issue 4
Keywords Temperature
Precipitation
Aspect and slope
Snow cover area
Snowmelt runoff model (SRM)
Degree-day factor (DDF)
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Texas A&M AgriLife Research and Extension Center at El Paso,El Paso,TX 79927-5020,USA
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SubjectTerms and
area
Aspect
Aspect and slope
cover
DDF
Degree-day
Degree-day factor (DDF)
factor
Precipitation
runoff
slope
Snow
Snow cover area
Snowmelt
Snowmelt runoff model (SRM)
SRM
Temperature
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Title Integration of aspect and slope in snowmelt runoff modeling in a mountain watershed
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