Affiliation:
1. Department of Soil Science and Agricultural Chemistry, University of Agricultural Sciences, Dharwad 580 005, India
2. Yettinagudda Campus, University of Agricultural Sciences, Dharwad 580 005, India
Abstract
The assessment of soil quality aims to evaluate the utility and health of soils. In agricultural studies, soil productivity can be likened to soil quality. Evaluating the Soil Quality Index (SQI) solely based on surface properties offers an incomplete picture because productivity is influenced by both surface and subsurface characteristics, with the latter associated with pedogenic processes. Additionally, relying on weighted averages of soil properties from a soil profile for the SQI may offer an overall summary, but it can occasionally obscure variations that manifest across different soil horizons. Therefore, the present study was conducted to assess the SQI in the Ganjigatti sub-watershed using data from 27 soil profiles and three different methods: (1) assessment of horizon-wise SQI by subjecting the soil properties of every horizon to principal component analysis (PCA), followed by the calculation of the weighted averages of the SQI for each soil profile (SQI-1); (2) calculation of the weighted averages of the soil properties for each soil profile, subjected to PCA, and followed by an SQI assessment (SQI-2); and (3) SQI assessment considering the properties of the Ap horizon for each soil profile (SQI-3). Additionally, to validate SQI methodologies, correlation studies were conducted against major crop yields in the sub-watershed. The results showed that cation exchange capacity (CEC) has the most significant weight and contribution to the SQI determined using MDS, followed by porosity, exchangeable sodium percentage (ESP), organic carbon (OC), CN ratio, and total N. SQI-1 was most strongly correlated with crop yield; the correlation coefficient ranged from 0.69 to 0.74. Among all the three methodologies, SQI-1 and -2 were better methods for assessment of SQI compared to SQI-3. In the SQI-1 method, the soil quality of pedons ranged from 0.26 (pedon-26) to 0.74 (pedon-11). The majority of the area in the sub-watershed (72.40%) fell within the medium category of SQI (0.35–0.55), followed by the high category of SQI (>0.55), which comprised 12.92%, and the low SQI (<0.35), which comprised 6.45% of the sub-watershed.
Subject
Management, Monitoring, Policy and Law,Renewable Energy, Sustainability and the Environment,Geography, Planning and Development,Building and Construction
Reference88 articles.
1. Solutions for a cultivated planet;Foley;Nature,2011
2. UNCCD (2023, September 05). Land and Soil the Context of a Green Economy for Sustainable Development, Food Security and Poverty Eradication. The Submission of the UNCCD Secretariat to the Preparatory Process for Rio+ 20. Available online: http://www.unscd2012.org/content/documents/unccd.pdf.
3. Oldemann, L.R., Hakkeling, R.T.A., and Sombrock, W.G. (1990). World Map of the Status of Human Induced Land Degradation, International Soil Reference and Information Centre. An Explantory Note.
4. New vistas in perspective of land use planning;Sarkar;J. Indian Soc. Soil Sci.,2009
5. Soil and sanskriti;Lal;J. Indian Soc. Soil Sci.,2013