Long-term effects of lowland sawah system on soil physicochemical properties and rice yield in Ashanti Region of Ghana

  • S. E. Obalum School of Agriculture, Kinki University, Nara
  • J. Oppong CSIR, Soil Research Institute, Kumasi
  • J. C. Nwite Federal College of Agriculture, Ishiagu
  • Y. Watanabe Kinki University, Nara
  • M. M. Buri Soil Research Institute, Kumasi
  • C. A. Igwe University of Nigeria, Nsukka
  • T. Wakatsuki Kinki University, Nara
DOI: https://doi.org/10.5424/sjar/2012103-566-11
Keywords: age of sawah, moisture retention, Oryza sativa, ponded sawah plot, rice grain yield, seasonal puddling, soil bulk density

Abstract

Lowland sawah is viewed as a sustainable alternative to traditional rice culture in West Africa. Sawah (a bund-demarcated, puddled, leveled, and water-regulated rice field) has received growing research attention lately, but no data exist yet on the system’s long-term agronomic impact. In a clayey inland-valley soil in southern Ghana, 10-year-old sawah plots (OSP), fresh sawah plots (FSP), and non-sawah plots (NSP) were maintained under both ponded and non-ponded conditions in 2007. The OSP enhanced soil status of exchangeable nutrients compared to NSP. There were relative improvements in soil bulk density, total porosity, and field moisture content (OSP ≥ FSP > NSP), with clear benefits of ponding over non-ponding in OSP. The NSP was so unsustainable that it showed less favourable values of these variables than an adjacent fallowed plot. These soil variables deteriorated with time, with significant differences in FSP. Soil moisture retention data for tension range of 0-300 kPa depicted the importance of puddling and ponding. During 2001-2009, OSP consistently out-yielded NSP by five times on average. During 2007-2009 when all three plots co-existed, grain yields averaged 5.80, 4.80 and 1.10 Mg ha−1 in OSP, FSP and NSP, respectively. In 2007 yields, OSP minus FSP was higher than NSP; in 2008/2009, the opposite prevailed. These results highlight the agronomic benefits of continuous sawah-based rice production. Although the positive effects of puddling on the soil hydrophysical properties were largely responsible for the wide margin in yield between sawah and traditional systems, the latter lacked other yield-enhancing factors, particularly bunds for water control, were also lacking in the latter.

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Author Biographies

S. E. Obalum, School of Agriculture, Kinki University, Nara
Research Fellow
J. Oppong, CSIR, Soil Research Institute, Kumasi
Research Fellow
J. C. Nwite, Federal College of Agriculture, Ishiagu
Chief Lecturer
Y. Watanabe, Kinki University, Nara
Research Fellow
M. M. Buri, Soil Research Institute, Kumasi
Senior Research Fellow
C. A. Igwe, University of Nigeria, Nsukka
Professor
T. Wakatsuki, Kinki University, Nara
Professor

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Published
2012-06-19
How to Cite
Obalum, S. E., Oppong, J., Nwite, J. C., Watanabe, Y., Buri, M. M., Igwe, C. A., & Wakatsuki, T. (2012). Long-term effects of lowland sawah system on soil physicochemical properties and rice yield in Ashanti Region of Ghana. Spanish Journal of Agricultural Research, 10(3), 838-848. https://doi.org/10.5424/sjar/2012103-566-11
Issue
Vol. 10 No. 3 (2012)
Section
Water management

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