Choudhury, I; Bhattacharya, B (2018). An assessment of satellite-based agricultural water productivity over the Indian region. INTERNATIONAL JOURNAL OF REMOTE SENSING, 39(8), 2294-2311.
Abstract
The preliminary analysis of agricultural water productivity (AWP) over India using satellite data were investigated through productivity mapping, water use (actual evapotranspiration (ETa)/effective rainfall (R-eff) mapping and water productivity mapping. Moderate Resolution Imaging Spectroradiometer data was used for generating agricultural land cover (MCD12Q1 at 500m), gross primary productivity (GPP; MOD17A2 at 1km), and ETa (MOD16A2 at 1km). R-eff was estimated at 10km using the United States Department of Agriculture soil conservation service method from daily National Oceanic and Atmospheric Administration Climate Prediction Center rainfall data. Six years' (2007-2012) data were analysed from June to October. The seasonal AWP and rainwater productivity (RWP) were estimated using the ratios of seasonal GPP (kg C m(-2)) and water use (mm) maps. The average AWP and RWP ranges from 1.10-1.30kg Cm-3 and 0.94-1.0kg C m(-3), respectively, with no significant annual variability but a wide spatial variability over India. The highest AWP was observed in northern India (1.22-1.80kg C m(-3)) and lowest in western India (0.81-1.0kg C m(-3)). Large variations in AWP (0.69-1.80 kg C m(-3)) were observed in Himachal Pradesh, Jammu and Kashmir, northeastern states (except Assam), Kerala, and Uttaranchal. The low GPP of these areas (0.0013-0.13kg C m(-2)) with low seasonal total ETa (<101mm) and R-eff (<72mm) making the AWP high that do not correspond to high productivity but possible water stress. Gujarat, Rajasthan, Maharashtra, Madhya Pradesh, Jharkhand, and Karnataka showed low AWP (0.73-1.13kg C m(-3)) despite having high ETa (261-558mm) and high R-eff (287-469mm), indicating significant scope for improving productivity. The highest RWP was observed in northern parts and Indo-Gangetic plains (0.80-1.6kg C m(-3)). The 6 years' analysis reveals the status of AWP, leading to appropriate interventions to better manage land and water resources, which have great importance in global food security analysis.
DOI:
10.1080/01431161.2017.1421792
ISSN:
0143-1161