Hydrological effects of open ditch damming and controlled subsurface drainage in a Nordic agricultural field
← TakaisinTekijä | Isomäki, Kielo ; Salla, Aleksi; Salo, Heidi; Koivusalo, Harri |
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Sarja | Hydrology Research |
DOI/ISBN-numero | 10.2166/nh.2024.053 |
Päivämäärä | 2024 |
Avainsanat | macropores, modeling, Water balance, water management, water table depth |
Rahoitus | Ympäristöministeriö/Pohjois-Pohjanmaan ELY, Salaojituksen Tukisäätiö sr, Salaojayhdistys ry, Luonnonvarakeskus, Aalto-yliopisto, Sven Hallinin tutkimussäätiö sr, Maa- ja vesitekniikan tuki ry |
Organisaatio | Aalto-yliopisto, Insinööritieteiden korkeakoulu / Rakennetun ympäristön laitos / Vesi- ja ympäristötekniikka |
Volyymi | Vol 00 No 0 |
Kieli | englanti |
Saatavuus | Hydrological effects of open ditch damming and controlled subsurface drainage in a Nordic agricultural field |
Controlled drainage (CRD) is an agricultural water management practice designed to adjust the capacity of a drainage system under varying hydrological conditions. This simulation study aimed to quantify the potential of combining a controlled subsurface drainage (CS) with open ditch damming (CD) to manage the water table depth (WTD) and field water balance in Nordic conditions. Simulations with and without controlled drainage were run using a hydrological model that had been set up for a flat loamy field in Northern Ostrobothnia, Finland, for the period 2010–2021. All CRD scenarios reduced the probability of deep WTDs during growing seasons (May–Sep). The impact of CS on WTDs was greater and more uniform than CD. The CRD effects on water balance were seen in water outflow pathways, as CS reduced drain discharge while CD had the opposite effect. When both methods were applied simultaneously, annual evapotranspiration increased 5–12% compared with the free drainage scenario. The effects of CRD on evapotranspiration were greatest during the dry years indicating that CRD has potential to reduce drought in food production areas. None of the CRD scenarios could maintain optimal WTDs during the entire growing season, highlighting the complexity of optimizing field water management using CRD alone.