Analysis of soil moisture and nutrient dynamics for different crop using HYDRUS1D model: A Review
Soil moisture and nutrient dynamics of crop using HYDRUS 1D model
DOI:
https://doi.org/10.21921/jas.v11i01.14764Keywords:
Moisture, Nutrient, dynamics, cropsAbstract
HYDRUS-1D model is one of such models simulating water movement and solute transport in the soil. It has been extensively applied to the simulation of wettable soil infiltration, but very few studies have explored its applicability to the infiltration of water-repellent soil (WRS) at different depths. The results showed that the model has better accuracy in simulating NO3-N concentration followed by the simulation of NH4+-N. It also noted that more and longer rainwater storage in paddy fields increased the loss of deep percolation, which increased the risk of nitrogen (N) leaching.
References
Autovino D, Rallo G and Provenzano G. 2018. Predicting soil and plant water status dynamic in olive orchards under different irrigation systems with Hydrus-2D: Model performance and scenario analysis. Agricultural water management203: 225-235.
Beegum S, Vanderborght J, Simunek J, Herbst M, Sudheer K P and Nambi I M. 2020. Investigating atrazine concentrations in the Zwischenscholle aquifer using MODFLOW with the HYDRUS-1D package and MT3DMS. Water12(4): 1019.
Bekele E, Tilahun S, Beyene A, Asres S, Geremew B and Atinkut H. 2020. Soil water dynamics on irrigated garlic and pepper crops using Hydrus–1D model in the Lake Tana-Basin, Northwestern Ethiopia. In Advances of Science and Technology: 7th EAI International Conference, ICAST 2019, Bahir Dar, Ethiopia, August 2–4, 2019, Proceedings 7 (pp. 193-209). Springer International Publishing.
Chen K, Yu S E, Ma T, Ding J, He P, Li Y, Dai Y and Zeng, G. 2022. Modeling the water and nitrogen management practices in paddy fields with HYDRUS-1D. Agriculture12(7): 924.
Er-Raki S, Ezzahar J, Merlin O, Amazirh A, Hssaine B A, Kharrou M H, Khabba S and Chehbouni A. 2021. Performance of the HYDRUS-1D model for water balance components assessment of irrigated winter wheat under different water managements in semi-arid region of Morocco. Agricultural Water Management244: 106546.
Filipovic V, Defterdarovic J, Krevh V, Filipovic L, Ondrasek G, Kranjcec F, Magdic I, Rubinic V, Stipicevic, S, Mustac I and Gerke H H. 2021. Estimation of stagnosol hydraulic properties and water flow using uni-and bimodal porosity models in erosion-affected hillslope vineyard soils. Agronomy12(1): 33.
Ghazouani H, Autovino D, Rallo G, Douh B and Provenzano G. 2016. Using HYDRUS-2D model to assess the optimal drip lateral depth for Eggplant crop in a sandy loam soil of central Tunisia. Ital. J. Agrometeorol1: 47-58.
Gulati D, Satpute S, Kaur S and Aggarwal R. 2022. Estimation of potential recharge through direct seeded and transplanted rice fields in semi-arid regions of Punjab using HYDRUS-1D. Paddy and Water Environment 20: 79-92.
Han M, Zhao C, Simunek J and Feng G. 2015. Evaluating the impact of groundwater on cotton growth and root zone water balance using Hydrus-1D coupled with a crop growth model. Agricultural Water Management160: 64-75.
Helalia S A, Anderson R G, Skaggs T H and Simunek J. 2021. Impact of drought and changing water sources on water use and soil salinity of almond and pistachio orchards: 2. modeling. Soil Systems 5(4): 58.
Iqbal M, Kamal M R, Che Man H and Wayayok A. 2020. HYDRUS-1D simulation of soil water dynamics for sweet corn under tropical rainfed condition. Applied Sciences10(4): 1219.
Iwasaki Y, Nakamura K, Horino H and Kawashima S. 2014. Assessment of factors influencing groundwater-level change using groundwater flow simulation, considering vertical infiltration from rice-planted and crop-rotated paddy fields in Japan. Hydrogeology journal22(8): 1841-1855.
Kader M A, Nakamura K, Senge M, Mojid M A and Kawashima S. 2019. Numerical simulation of water-and heat-flow regimes of mulched soil in rain-fed soybean field in central Japan. Soil and Tillage Research191: 142-155.
Karimov A K, Hanjra M A, Simunek J and Abdurakhmannov B. 2018. Can a change in cropping patterns produce water savings and social gains: A case study from the Fergana Valley, Central Asia. Journal of Hydrology and Hydromechanics66(2): 189-201.
Li Q, LI F, Zhang Q, Qiao Y, Du K, Zhu N, Yang G, Li J and He X. 2021. Water and salt transport simulation in the wheat growing area of the North China Plain based on HYDRUS model. Chinese Journal of Eco-Agriculture29(6): 1085-1094.
Li Y, Simunek J, Jing L, Zhang Z and Ni L. 2014. Evaluation of water movement and water losses in a direct-seeded-rice field experiment using Hydrus-1D. Agricultural Water Management142: 38-46.
Liu X W, Feike T, Chen S Y, Shao L W, Sun H Y, and Zhang X Y. 2016. Effects of saline irrigation on soil salt accumulation and grain yield in the winter wheat-summer maize double cropping system in the low plain of North China. Journal of Integrative Agriculture15(12): 2886-2898.
Lu X, Zhou M and Wang P. 2016. Diurnal soil water and root water uptake/nitrogen dynamics in the wastewater-irrigated pepper field. Communications in Soil Science and Plant Analysis47(8): 989-1005.
Miller O, Helman D, Svoray T, Morin E and Bonfil D J. 2019. Explicit wheat production model adjusted for semi-arid environments. Field Crops Research231: 93-104.
Mo’allim A A, Kamal M R, Muhammed H H, Mohd Soom M A, Mohamed Zawawi M A B, Wayayok A and Che Man H B. 2018. Assessment of nutrient leaching in flooded paddy rice field experiment using Hydrus-1D. Water10(6): 785.
Moghbel F, Mosaedi A, Aguilar J, Ghahraman B, Ansari H and Gonçalves M C. 2022. Bayesian calibration and uncertainty assessment of HYDRUS-1D model using GLUE algorithm for simulating corn root zone salinity under linear move sprinkle irrigation system. Water14(24): 4003.
Mokari E, Shukla M K, Simunek J and Fernandez J L. 2019. Numerical modeling of nitrate in a flood‐irrigated pecan orchard. Soil Science Society of America Journal83(3): 555-564.
Ogundipe E O, Oniya O O, Awe G O and Abegunrinn T P. 2016. Testing of two algorithms in simulating soil water dynamics in a drip irrigated tomato under different irrigation frequencies and depths in Ogbomoso, Nigeria. Revista Brasileira de CiÊNcia do Solo16(5): 934-945.
Patle G T, Singh D K and Sarangi A. 2018. Modelling of climate-induced groundwater recharge for assessing carbon emission from groundwater irrigation. Current Science115(1): 64-73.
Roy D, Mahmud M N H, Paul P L C, Hossain M B, Yesmin M S, Kundu P K, Debnath A, Pranto M R B H and Islam M T. 2021. Paddy field water movement through soil profiles under different water management practices: A HYDRUS 1D Model Study. Bangladesh Rice Journal25(2): 57-67.
Sao D, Saito H, Kato T and Simunek, J. 2021. Numerical analysis of soil water dynamics during spinach cultivation in a soil column with an artificial capillary barrier under different irrigation managements. Water13(16): 2176.
Sepaskhah A R and Tafteh A. 2012. Yield and nitrogen leaching in rapeseed field under different nitrogen rates and water saving irrigation. Agricultural Water Management112: 55-62.
Simunek J, Sejna M, Saito H, Sakai M, van Genuchten M T, 2008. The HYDRUS-1D Software Package for Simulating the Movement of Water, Heat, and Multiple Solutes in Variably Saturated Media, Version 4.0, HYDRUS Software Series 3. Department of Environmental Sciences, University of California Riverside, Riverside, California, USA, pp. 315.
Ventrella D, Castellini M, Di Prima S, Garofalo P and Lassabatere L. 2019. Assessment of the physically-based HYDRUS-1D model for simulating the water fluxes of a Mediterranean cropping system. Water11(8): 1657.
Xu B, Shao D, Tan X, Yang X, Gu W and Li H. 2017. Evaluation of soil water percolation under different irrigation practices, antecedent moisture and groundwater depths in paddy fields. Agricultural Water Management192: 149-158.
Yang L. 2022. Modeling of Water Use in the Micro-sprinkler Irrigated Almond Orchard. HYD 243 Final Project.
Yang Y, Chen Y, Chen J, Zhang Z, Li Y and Du Y. 2021. The applicability of HYDRUS‐1D to infiltration of water‐repellent soil at different depths. European Journal of Soil Science72(5): 2020-2032.
Yurtseven E, Simunek J, Avcı S and Ozturk H S. 2013. Comparison of HYDRUS 1D simulations and ion (salt) movement in the soil profile subject to leaching. In The 4th international conference BHYDRUS software applications to subsurface flow and contaminant transport problems. Prague: Czech University of Life Sciences.
Zhu Y, Ren L, Horton R, Lu H, Wang Z and Yuan F. 2018. Estimating the contribution of groundwater to the root zone of winter wheat using root density distribution functions. Vadose Zone Journal17(1): 1-15.
