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Assessing the effects of management and hydro-edaphic conditions on rice in contrasting East African wetlands using experimental and modelling approaches

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Listed:
  • Grotelüschen, Kristina
  • Gaydon, Donald S.
  • Langensiepen, Matthias
  • Ziegler, Susanne
  • Kwesiga, Julius
  • Senthilkumar, Kalimuthu
  • Whitbread, Anthony M.
  • Becker, Mathias

Abstract

Lowland rice yields in East Africa remain low despite favourable hydro-edaphic conditions as benefits from improved cultural management vary between and within wetland types and interactions are poorly understood. Hence, multi-year agronomic field experiments were established to assess the differential responses of lowland rice to management (rainfed 0 and 60 kg N ha−1, and irrigated 120 kg N ha−1 + 60 kg PK ha−1) and field position within a floodplain in Tanzania (fringe and middle positions) and an inland valley in Uganda (valley-fringe, mid-valley and valley-bottom positions). We then calibrated and validated the Agricultural Production System Simulator (APSIM), evaluated the importance of external water table data as model input and assessed the relative effects of water and N stress on yield as affected by wetland type and field position. Yields of 3.2–9.2 Mg ha−1 were attained in the floodplain and of 1.9–6.3 Mg ha−1 in the inland valley, highlighting the substantial scope to boost yields beyond current regional means of around 2 Mg ha−1. The model estimated grain yields in both wetlands well within the experimental uncertainty during model validation (n = 12, r2 = 0.76, RMSEa= 0.92 Mg ha−1 in the floodplain; n = 18, r2 = 0.71, RMSEa= 0.72 Mg ha−1 in the inland valley). Results further emphasised the importance of external water table data for sound model performance as they evidently alleviated seasonal droughts. Simulated abiotic stress patterns additionally highlighted hydro-edaphic differences from field positioning within and between both wetlands. While low soil N was generally the main yield constraint, water stress was comparably more pronounced in the inland valley and supplemental irrigation thus more beneficial on yield. Hydro-edaphic field conditions favoured rice production in the floodplain’s fringe with comparably lower N stress, while large spatial-temporal variabilities prevented a distinct delineation based on toposequential field positions in the inland valley.

Suggested Citation

  • Grotelüschen, Kristina & Gaydon, Donald S. & Langensiepen, Matthias & Ziegler, Susanne & Kwesiga, Julius & Senthilkumar, Kalimuthu & Whitbread, Anthony M. & Becker, Mathias, 2021. "Assessing the effects of management and hydro-edaphic conditions on rice in contrasting East African wetlands using experimental and modelling approaches," Agricultural Water Management, Elsevier, vol. 258(C).
    • Handle: RePEc:eee:agiwat:v:258:y:2021:i:c:s0378377421004236
    DOI: 10.1016/j.agwat.2021.107146
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    1. Bouman, B. A.M. & Feng, Liping & Tuong, T.P. & Lu, Guoan & Wang, Huaqi & Feng, Yuehua, 2007. "Exploring options to grow rice using less water in northern China using a modelling approach: II. Quantifying yield, water balance components, and water productivity," Agricultural Water Management, Elsevier, vol. 88(1-3), pages 23-33, March.
    2. Nhamo, Nhamo & Rodenburg, Jonne & Zenna, Negussie & Makombe, Godswill & Luzi-Kihupi, Ashura, 2014. "Narrowing the rice yield gap in East and Southern Africa: Using and adapting existing technologies," Agricultural Systems, Elsevier, vol. 131(C), pages 45-55.
    3. Dutta, S. K & Laing, Alison M. & Kumar, S. & Gathala, Mahesh K. & Singh, Ajoy K. & Gaydon, D.S. & Poulton, P., 2020. "Improved water management practices improve cropping system profitability and smallholder farmers’ incomes," Agricultural Water Management, Elsevier, vol. 242(C).
    4. Feng, Liping & Bouman, B. A.M. & Tuong, T.P. & Cabangon, R.J. & Li, Yalong & Lu, Guoan & Feng, Yuehua, 2007. "Exploring options to grow rice using less water in northern China using a modelling approach: I. Field experiments and model evaluation," Agricultural Water Management, Elsevier, vol. 88(1-3), pages 1-13, March.
    5. Kijima, Yoko & Ito, Yukinori & Otsuka, Keijiro, 2012. "Assessing the Impact of Training on Lowland Rice Productivity in an African Setting: Evidence from Uganda," World Development, Elsevier, vol. 40(8), pages 1610-1618.
    6. Raes, D. & Kafiriti, E.M. & Wellens, J. & Deckers, J. & Maertens, A. & Mugogo, S. & Dondeyne, S. & Descheemaeker, K., 2007. "Can soil bunds increase the production of rain-fed lowland rice in south eastern Tanzania?," Agricultural Water Management, Elsevier, vol. 89(3), pages 229-235, May.
    7. Schmitter, Petra & Zwart, Sander J. & Danvi, Alexandre & Gbaguidi, Félix, 2015. "Contributions of lateral flow and groundwater to the spatio-temporal variation of irrigated rice yields and water productivity in a West-African inland valley," Agricultural Water Management, Elsevier, vol. 152(C), pages 286-298.
    8. Jones, C. A. & Dyke, P. T. & Williams, J. R. & Kiniry, J. R. & Benson, V. W. & Griggs, R. H., 1991. "EPIC: An operational model for evaluation of agricultural sustainability," Agricultural Systems, Elsevier, vol. 37(4), pages 341-350.
    9. Belder, P. & Bouman, B. A.M. & Spiertz, J.H.J., 2007. "Exploring options for water savings in lowland rice using a modelling approach," Agricultural Systems, Elsevier, vol. 92(1-3), pages 91-114, January.
    10. Worou, Omonlola Nadine & Gaiser, Thomas & Saito, Kazuki & Goldbach, Heiner & Ewert, Frank, 2013. "Spatial and temporal variation in yield of rainfed lowland rice in inland valley as affected by fertilizer application and bunding in North-West Benin," Agricultural Water Management, Elsevier, vol. 126(C), pages 119-124.
    11. Mohanty, M. & Sinha, Nishant K. & Somasundaram, J. & McDermid, Sonali S. & Patra, Ashok K. & Singh, Muneshwar & Dwivedi, A.K. & Reddy, K. Sammi & Rao, Ch. Srinivas & Prabhakar, M. & Hati, K.M. & Jha, , 2020. "Soil carbon sequestration potential in a Vertisol in central India- results from a 43-year long-term experiment and APSIM modeling," Agricultural Systems, Elsevier, vol. 184(C).
    12. Probert, M. E. & Dimes, J. P. & Keating, B. A. & Dalal, R. C. & Strong, W. M., 1998. "APSIM's water and nitrogen modules and simulation of the dynamics of water and nitrogen in fallow systems," Agricultural Systems, Elsevier, vol. 56(1), pages 1-28, January.
    13. Van Campenhout, Bjorn & Walukano, Wilberforce & Van Asten, Piet, 2016. "Addressing knowledge gaps in rice growing in eastern uganda," USSP working papers 20, International Food Policy Research Institute (IFPRI).
    14. Bouman, B.A.M. & van Laar, H.H., 2006. "Description and evaluation of the rice growth model ORYZA2000 under nitrogen-limited conditions," Agricultural Systems, Elsevier, vol. 87(3), pages 249-273, March.
    15. Alan B Dixon & Adrian P Wood, 2003. "Wetland cultivation and hydrological management in eastern Africa: Matching community and hydrological needs through sustainable wetland use," Natural Resources Forum, Blackwell Publishing, vol. 27(2), pages 117-129, May.
    16. Boling, A.A. & Bouman, B. A.M. & Tuong, T.P. & Murty, M.V.R. & Jatmiko, S.Y., 2007. "Modelling the effect of groundwater depth on yield-increasing interventions in rainfed lowland rice in Central Java, Indonesia," Agricultural Systems, Elsevier, vol. 92(1-3), pages 115-139, January.
    17. Amarasingha, R.P.R.K. & Suriyagoda, L.D.B. & Marambe, B. & Rathnayake, W.M.U.K. & Gaydon, D.S. & Galagedara, L.W. & Punyawardena, R. & Silva, G.L.L.P. & Nidumolu, U. & Howden, M., 2017. "Improving water productivity in moisture-limited rice-based cropping systems through incorporation of maize and mungbean: A modelling approach," Agricultural Water Management, Elsevier, vol. 189(C), pages 111-122.
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