Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2D

Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2D

Water scarcity is the most critical constraint for sustainable cotton production in Xinjiang Province, northwest China. Drip irrigation under mulch is a major water-saving irrigation method that has been widely practiced for cotton production in Xinjiang. The performance of such an irrigation syste...

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Bibliographic Details
Main Authors: Ming Han, Chengyi Zhao, Gary Feng, Yingyu Yan, Yu Sheng
Format: Article
Language:English
Published: MDPI AG 2015-05-01
Series:Water
Subjects:
HYDRUS-2D
mulch
soil water dynamic
cotton
drip irrigation
water balance
Online Access:http://www.mdpi.com/2073-4441/7/6/2622
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spelling doaj-50a20795eb4d4299a00f3b412a2af7522020-11-24T22:41:33ZengMDPI AGWater2073-44412015-05-01762622264010.3390/w7062622w7062622Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2DMing Han0Chengyi Zhao1Gary Feng2Yingyu Yan3Yu Sheng4State Key Laboratory of Oasis Desert and Ecology, Xinjiang Institute of Ecology and Geography, CAS, Urumqi 830011, ChinaState Key Laboratory of Oasis Desert and Ecology, Xinjiang Institute of Ecology and Geography, CAS, Urumqi 830011, ChinaGenetics and Precision Agriculture Research Unit, USDA-ARS, P. O. BOX 5367, 810 Highway 12 East, Mississippi State, MS 39762, USAXinjiang Monitoring Station of Water and Soil Conservation, Urumqi 830000, ChinaState Key Laboratory of Oasis Desert and Ecology, Xinjiang Institute of Ecology and Geography, CAS, Urumqi 830011, ChinaWater scarcity is the most critical constraint for sustainable cotton production in Xinjiang Province, northwest China. Drip irrigation under mulch is a major water-saving irrigation method that has been widely practiced for cotton production in Xinjiang. The performance of such an irrigation system should be evaluated for proper design and management. Therefore, a field experiment and a simulation study were conducted to (1) determine a modeling approach that can be applied to manage drip irrigation under mulch for cotton production in this region; and (2) examine the effects of irrigation amount and mulch on soil water distribution and root zone water balance components. In the experiment, four irrigation treatments were used: T1, 166.5 m3; T2, 140.4 m3; T3, 115.4 m3; and T4: 102.3 m3. The HYDRUS-2D model was calibrated, validated, and applied with the data obtained in this experiment. Soil water balance in the 0–70 cm soil profile was simulated. Results indicate that the observed soil water content and the simulated results obtained with HYDRUS-2D are in good agreement. The radius of the wetting pattern, root water uptake, and evaporation decreased as the amount of irrigation was reduced from T1 to T4, while a lot of stored soil water in the root zone was utilized and a huge amount of water was recharged from the layer below 70 cm to compensate for the decrease in irrigation amount. Mulch significantly reduced evaporation by 11.7 mm and increased root water uptake by 11.2 mm. Our simulation study suggests that this model can be applied to provide assistance in designing drip irrigation systems and developing irrigation strategies.http://www.mdpi.com/2073-4441/7/6/2622HYDRUS-2Dmulchsoil water dynamiccottondrip irrigationwater balance
collection DOAJ
language English
format Article
sources DOAJ
author Ming Han
Chengyi Zhao
Gary Feng
Yingyu Yan
Yu Sheng
spellingShingle Ming Han
Chengyi Zhao
Gary Feng
Yingyu Yan
Yu Sheng
Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2D
Water
HYDRUS-2D
mulch
soil water dynamic
cotton
drip irrigation
water balance
author_facet Ming Han
Chengyi Zhao
Gary Feng
Yingyu Yan
Yu Sheng
author_sort Ming Han
title Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2D
title_short Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2D
title_full Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2D
title_fullStr Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2D
title_full_unstemmed Evaluating the Effects of Mulch and Irrigation Amount on Soil Water Distribution and Root Zone Water Balance Using HYDRUS-2D
title_sort evaluating the effects of mulch and irrigation amount on soil water distribution and root zone water balance using hydrus-2d
publisher MDPI AG
series Water
issn 2073-4441
publishDate 2015-05-01
description Water scarcity is the most critical constraint for sustainable cotton production in Xinjiang Province, northwest China. Drip irrigation under mulch is a major water-saving irrigation method that has been widely practiced for cotton production in Xinjiang. The performance of such an irrigation system should be evaluated for proper design and management. Therefore, a field experiment and a simulation study were conducted to (1) determine a modeling approach that can be applied to manage drip irrigation under mulch for cotton production in this region; and (2) examine the effects of irrigation amount and mulch on soil water distribution and root zone water balance components. In the experiment, four irrigation treatments were used: T1, 166.5 m3; T2, 140.4 m3; T3, 115.4 m3; and T4: 102.3 m3. The HYDRUS-2D model was calibrated, validated, and applied with the data obtained in this experiment. Soil water balance in the 0–70 cm soil profile was simulated. Results indicate that the observed soil water content and the simulated results obtained with HYDRUS-2D are in good agreement. The radius of the wetting pattern, root water uptake, and evaporation decreased as the amount of irrigation was reduced from T1 to T4, while a lot of stored soil water in the root zone was utilized and a huge amount of water was recharged from the layer below 70 cm to compensate for the decrease in irrigation amount. Mulch significantly reduced evaporation by 11.7 mm and increased root water uptake by 11.2 mm. Our simulation study suggests that this model can be applied to provide assistance in designing drip irrigation systems and developing irrigation strategies.
topic HYDRUS-2D
mulch
soil water dynamic
cotton
drip irrigation
water balance
url http://www.mdpi.com/2073-4441/7/6/2622
work_keys_str_mv AT minghan evaluatingtheeffectsofmulchandirrigationamountonsoilwaterdistributionandrootzonewaterbalanceusinghydrus2d
AT chengyizhao evaluatingtheeffectsofmulchandirrigationamountonsoilwaterdistributionandrootzonewaterbalanceusinghydrus2d
AT garyfeng evaluatingtheeffectsofmulchandirrigationamountonsoilwaterdistributionandrootzonewaterbalanceusinghydrus2d
AT yingyuyan evaluatingtheeffectsofmulchandirrigationamountonsoilwaterdistributionandrootzonewaterbalanceusinghydrus2d
AT yusheng evaluatingtheeffectsofmulchandirrigationamountonsoilwaterdistributionandrootzonewaterbalanceusinghydrus2d
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