Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern China

Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern China

The increase in irrigated maize plantings in Northern China has increased the demand for irrigation water in the region, resulting in chronic water shortages in drier years. Efficient irrigation and water use are essential for the sustainable development and management of water resources in the area...

Full description

Bibliographic Details
Main Authors: Patrick Rugira, Ma Juanjuan, Zheng Lijian, Wu Chaobao, Liu Enke
Format: Article
Language:English
Published: MDPI AG 2021-04-01
Series:Agronomy
Subjects:
DSSAT model
optimum irrigation management
maize
sowing dates
Northern China
loess plateau
Online Access:https://www.mdpi.com/2073-4395/11/4/674
id doaj-357b0d072838445b8dde5ccd37c38665
record_format Article
spelling doaj-357b0d072838445b8dde5ccd37c386652021-04-02T23:01:03ZengMDPI AGAgronomy2073-43952021-04-011167467410.3390/agronomy11040674Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern ChinaPatrick Rugira0Ma Juanjuan1Zheng Lijian2Wu Chaobao3Liu Enke4College of Water Resource Science and Engineering, Taiyuan University of Technology, Taiyuan 030024, ChinaCollege of Water Resource Science and Engineering, Taiyuan University of Technology, Taiyuan 030024, ChinaCollege of Water Resource Science and Engineering, Taiyuan University of Technology, Taiyuan 030024, ChinaShanxi Provincial Central Irrigation Experiment Station, Wenshui 032100, ChinaShanxi Institute of Organic Dryland Farming, Shanxi Agricultural University, Taiyuan 030800, ChinaThe increase in irrigated maize plantings in Northern China has increased the demand for irrigation water in the region, resulting in chronic water shortages in drier years. Efficient irrigation and water use are essential for the sustainable development and management of water resources in the area. This research applied DSSAT-maize in the Loess Plateau (Fenhe basin) to determine the suitable irrigation management and optimum sowing dates to ensure the stability of spring maize production. The model was calibrated using the full irrigation treatment of 2017–2019 growing seasons. Crop data, such as plant phenological phases, aboveground biomass, crop yield, and leaf area index, were used for model calibration. The calibration showed great consistency between the measured and simulated data, with nRMSE (normalized root mean square error) ranging from 0.77% to 21.6%. The field values of crop yield, aboveground biomass, LAI, soil water content, and water use efficiency were used to evaluate the calibrated model’s performance, the model evaluation was found to be satisfactory with acceptable nRMSE ranging from 1.9% to 25.3%. Optimum simulated sowing dates for increased productivity and water efficiency were between 15 and 25 May. The optimum irrigation timing and volume of irrigation water application were 85 mm at the tasseling phase and 85 mm at the grouting phase respectively. Therefore, the yield of maize can be increased by applying irrigation and altering the sowing date in case rainfall is insufficient to satisfy the water demand of the crops in the Fenhe basin.https://www.mdpi.com/2073-4395/11/4/674DSSAT modeloptimum irrigation managementmaizesowing datesNorthern Chinaloess plateau
collection DOAJ
language English
format Article
sources DOAJ
author Patrick Rugira
Ma Juanjuan
Zheng Lijian
Wu Chaobao
Liu Enke
spellingShingle Patrick Rugira
Ma Juanjuan
Zheng Lijian
Wu Chaobao
Liu Enke
Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern China
Agronomy
DSSAT model
optimum irrigation management
maize
sowing dates
Northern China
loess plateau
author_facet Patrick Rugira
Ma Juanjuan
Zheng Lijian
Wu Chaobao
Liu Enke
author_sort Patrick Rugira
title Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern China
title_short Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern China
title_full Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern China
title_fullStr Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern China
title_full_unstemmed Application of DSSAT CERES-Maize to Identify the Optimum Irrigation Management and Sowing Dates on Improving Maize Yield in Northern China
title_sort application of dssat ceres-maize to identify the optimum irrigation management and sowing dates on improving maize yield in northern china
publisher MDPI AG
series Agronomy
issn 2073-4395
publishDate 2021-04-01
description The increase in irrigated maize plantings in Northern China has increased the demand for irrigation water in the region, resulting in chronic water shortages in drier years. Efficient irrigation and water use are essential for the sustainable development and management of water resources in the area. This research applied DSSAT-maize in the Loess Plateau (Fenhe basin) to determine the suitable irrigation management and optimum sowing dates to ensure the stability of spring maize production. The model was calibrated using the full irrigation treatment of 2017–2019 growing seasons. Crop data, such as plant phenological phases, aboveground biomass, crop yield, and leaf area index, were used for model calibration. The calibration showed great consistency between the measured and simulated data, with nRMSE (normalized root mean square error) ranging from 0.77% to 21.6%. The field values of crop yield, aboveground biomass, LAI, soil water content, and water use efficiency were used to evaluate the calibrated model’s performance, the model evaluation was found to be satisfactory with acceptable nRMSE ranging from 1.9% to 25.3%. Optimum simulated sowing dates for increased productivity and water efficiency were between 15 and 25 May. The optimum irrigation timing and volume of irrigation water application were 85 mm at the tasseling phase and 85 mm at the grouting phase respectively. Therefore, the yield of maize can be increased by applying irrigation and altering the sowing date in case rainfall is insufficient to satisfy the water demand of the crops in the Fenhe basin.
topic DSSAT model
optimum irrigation management
maize
sowing dates
Northern China
loess plateau
url https://www.mdpi.com/2073-4395/11/4/674
work_keys_str_mv AT patrickrugira applicationofdssatceresmaizetoidentifytheoptimumirrigationmanagementandsowingdatesonimprovingmaizeyieldinnorthernchina
AT majuanjuan applicationofdssatceresmaizetoidentifytheoptimumirrigationmanagementandsowingdatesonimprovingmaizeyieldinnorthernchina
AT zhenglijian applicationofdssatceresmaizetoidentifytheoptimumirrigationmanagementandsowingdatesonimprovingmaizeyieldinnorthernchina
AT wuchaobao applicationofdssatceresmaizetoidentifytheoptimumirrigationmanagementandsowingdatesonimprovingmaizeyieldinnorthernchina
AT liuenke applicationofdssatceresmaizetoidentifytheoptimumirrigationmanagementandsowingdatesonimprovingmaizeyieldinnorthernchina
_version_ 1721544600308416512

Similar Items