Coupling Tank Model and Lars-Weather Generator in Assessments of the Impacts of Climate Change on Water Resources-Reference-Cited by-同舟云学术

Coupling Tank Model and Lars-Weather Generator in Assessments of the Impacts of Climate Change on Water Resources

Published:2019-03-01 Issue:1 Volume:27 Page:14-24
ISSN:1338-3973
Container-title:Slovak Journal of Civil Engineering
language:en
Short-container-title:

Author:

Mohammadzadeh Naser¹,Amiri Bahman Jabbarian¹,Endergoli Leila Eslami²,Karimi Shirin¹

Affiliation:

1. Dept. of Environmental Science , University of Tehran , Karaj , Iran

2. Griffith University , Griffith School of Environment, Nathan Campus , Queensland , Australia

Abstract

Abstract With the aim of assessing the impact of climate change on surface water resources, a conceptual rainfall-runoff model (the tank model) was coupled with LARS-WG as a weather generator model. The downscaled daily rainfall, temperature, and evaporation from LARS-WG under various IPCC climate change scenarios were used to simulate the runoff through the calibrated Tank model. A catchment (4648 ha) located in the southern basin of the Caspian Sea was chosen for this research study. The results showed that this model has a reasonable predictive capability in simulating minimum and maximum temperatures at a level of 99%, rainfall at a level of 93%, and radiation at a level of 97% under various scenarios in agreement with the observed data. Moreover, the results of the rainfall-runoff model indicated an increase in the flow rate of about 108% under the A1B scenario, 101% under the A2 scenario, and 93% under the B1 scenario over the 30-year time period of the discharge prediction.

Publisher

Walter de Gruyter GmbH

Link

https://www.sciendo.com/pdf/10.2478/sjce-2019-0003

Reference45 articles.

1. Amiri, B. J. (2017)Environmental Modeling. University of Tehran Press, No. 3883, pp. 150.

2. Amiri, B. J., Fohrer, N., Cullmann, J., Hörmann, G., Müller, F., Adamowski, J. (2016)Regionalization of Tank Model Using Landscape Metrics of Catchments. Water resources management, 30(14), pp. 5065-5085.

3. Allen, R. G., Pereira, L. S., Raes, D., Smith, M. (1998)Crop evapotranspiration - Guidelines for computing crop water requirements- FAO. Irrigation and drainage paper 56. FAO, Rome, 300(9), p. D05109.

4. Babaeian, I., Kwon, W. T. (2005)Climate change assessment over Korea using stochastic daily data. In Proceedings of the first Iran–Korea joint workshop on climate modelling.

5. Barrett, B., Charles, J. W., Temte, J. L. (2015)Climate change, human health, and epidemiological transition. Preventive medicine, 70, pp. 69-75.

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