Ecological and health risk assessment of different land uses along with seasonal variation in toxic metal contamination around Varanasi city situated in Indo-Gangetic Plain.

Metal pollution load in soil environment has been enhanced during last few decades due to increasing industrialization and wide application of metals in all sectors. Due to the persistent and hazardous nature of metals, it can accumulate in the living system and cause severe risks to the ecosystem. The abundance of metals in soils from 5 different land use systems (industrial, industrial highway, brick kiln production area, residential highways and botanical gardens) in the Indo-Gangetic Plain region of India was analysed for three consecutive years (2018-2020) to evaluate the effects of metal load on soil properties and ecosystem health. Soil enzymatic activities, moisture, porosity, total nitrogen, and organic carbon were least at the industrial area of Ramnagar site and highest at Botanical garden area of BHU. Geochemical indices were calculated to compare the background status of metals in the soil where Cd, Cu, Cr, Co, Ni, Mn and Zn were increased in recent times. Contamination, enrichment and potential ecological risk factors with respect to Cu and Cd contents in soil were significantly higher at industrial area of Ramnagar and highway near industrial area. Maximum lifetime non-cancer and cancer health hazards were observed for Cd and Ni, respectively. The study clearly indicates that Cd, Cu and Ni are capable of posing health risk and cause imbalance in ecological functioning of soil due to chronic exposure of the potential toxic metals generated through change in land uses in sub-urban areas of Indo-Gangetic Plain region.

Improvements in Soil Physical, Chemical and Biological Properties at Natural Saline and Non-Saline Sites Under Different Management Practices.

Soil salinity is known to be a significant threat to food security for the increasing population, which is further aggravated under the climate change scenario. Indo-Gangetic plain (IGP) is one of the most productive in the world and is most affected by salinity. To understand the modifications in soil characteristics under different management practices followed to reclaim salinity affected land, the present study was conducted at variously reclaimed saline areas of three districts of Uttar Pradesh situated in IGP. Soil from six sites (electrical conductivity (EC) ranging from 0.89 to 10.28 mS) following different management practices, RJT (Rajatalab, rice-wheat +organic), BBN (Beerbhanpur, rice-wheat +inorganic), MZM (Mirzamurad, rice-mustard +organic), BRP (Baraipur, rice-wheat +organic), DHR (Dharahara, rice-fallow +organic) and SLM (Salempur, rice-wheat +inorganic) were assessed for physical, chemical and biological properties during the vegetative stage and after harvest of crops. Soil quality index (SQI) based on representative parameters obtained by principal component analysis and yield of crops were also calculated at saline and non-saline sites. The SLM site showed highest salinity followed by BRP, DHR, MZM, while BBN and RJT were non-saline. Total organic carbon, total nitrogen, microbial activity, and microbial biomass were low at saline compared to non-saline sites but were higher under organic matter amendment compared to inorganic. Activities of soil enzymes were negatively influenced while ß-glucosidase and alkaline phosphatase activities were enhanced under higher salinity. Organic amendments were more efficient in improving the soil properties along with SQI at saline soil resulting into a better yield in all crop combinations compared to inorganic amendments.

Assessment of physiological, biochemical and yield responses of wheat plants under natural saline and non-saline field conditions.

Soil salinity is a major threat to crop productivity all over the world including the Indo-Gangetic plain (IGP) region of India. Therefore, a field study was conducted for two consecutive years in wheat growing areas in IGP affected by salinity. Plants grown at a saline site (Salempur, SLM) and a non-saline site (Rajatalab, RJT), were analysed for selected biochemical, physiological and yield traits. Results showed that photosynthetic rate was not significantly affected, but transpiration rate and stomatal conductance declined at saline compared to non-saline site. Photosynthetic pigments increased during vegetative growth period, but decreased during reproductive stage at SLM site, while anthocyanin showed an opposite trend. Membrane damage, solute leakage, H2O2 and ·O2 - productions were intensified at saline site, SLM. Accumulation of osmolytes and antioxidants occurred in plants at saline compared to non-saline sites. K/Na and Ca/Na ratios in plants at SLM were reduced significantly compared to non-saline site, RJT. Biomass and yield also declined at SLM compared to RJT. Principle component and path analyses on the measured parameters clearly showed that defense strategies adopted by plants helped to maintain the photosynthetic rate but biomass and yield of wheat got compromised under high salinity.