Abstract
Abstract. In common with other undulating landscapes in Asia, wetland rice (Oryza sativa) on the East India Plateau (EIP) was once confined to hydrologic discharge areas or lowlands, but progressive terracing has now allowed rainfed transplanted rice to encroach upon upland recharge areas, with potential effects on both hydrology and soil fertility. Hydrologic variation down the toposequence and its implications for rice production have been well documented but not the variation in soil fertility. Measurements of soil chemical fertility in seven of 24 EIP districts were used to evaluate variation between and within small watersheds stratified down the toposequence into six land classes that reflect hydrology and land use (three with rice and three without; 36 fields per watershed). We aimed to provide a basis for future research to improve the management of soil fertility. Soils overall were acid, with 14 % of fields requiring liming (pH < 5.0) and 44 % requiring management of further acidification (pH 5.0–5.4). Organic carbon (OC, mean 0.9 %) and cation exchange capacity (CEC; mean 10.7 cmolc kg−1) were low. Available phosphorus (P) was mostly very low (mean Bray P 4.3 mg kg−1) and extractable potassium (K) low to marginal (mean 88 mg kg−1). Non-rice soils generally had lower pH, OC, and CEC than rice soils but higher P and K. Amongst rice fields, those higher in the toposequence had lower pH, OC, and CEC but more P and K. These results are discussed in the context of nutrient flows in the landscape, leading to the conclusion that terracing uplands has reduced the delivery of sediment-bound P to lowlands where, even with organic P recycling, low inputs of inorganic fertiliser have led soil P to decline and become the primary constraint to the yield of wet season crops. Soil K is on the same trajectory. P and K fertiliser use must increase substantially to sustain the system, which is a challenge for risk-averse subsistence farmers. Field-specific recommendations are needed despite systematic toposequence differences because of variability between fields within land classes.
Highlights
Much of the rainfed transplanted rice (Oryza sativa) in southern and southeastern Asia is grown in toposequences where relatively small differences in elevation can lead to differentiation in hydrological conditions, soil properties, and often yield (Homma et al, 2003; Fuwa et al, 2007; Tsubo et al, 2007; Boling et al, 2008; Cornish et al, 2010, 2015a)
This paper reports a study of soil fertility in six of the 24 districts in Jharkhand and one in western West Bengal
The East India Plateau (EIP) or Chota Nagpur Plateau is a series of plateaus, hills, and valleys in an undulating landscape with an average elevation ∼ 500 m and occasional higher peaks
Summary
Much of the rainfed transplanted (lowland) rice (Oryza sativa) in southern and southeastern Asia is grown in toposequences where relatively small differences in elevation can lead to differentiation in hydrological conditions, soil properties, and often yield (Homma et al, 2003; Fuwa et al, 2007; Tsubo et al, 2007; Boling et al, 2008; Cornish et al, 2010, 2015a). These toposequence studies agree on the hydrologic changes down the toposequences but draw varying conclusions about soil fertility. A geographically broader evaluation of soil chemical fertility is required before extending the agronomic findings of Cornish et al (2015b) regionally
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