Your search keyword '"Jyoti Prakash Deka"' showing total 4 results

1. Groundwater appraisal of Dhekiajuli, Assam, India: an insight of agricultural suitability and arsenic enrichment

Author

Manish Kumar, Aparna Das, Jyoti Prakash Deka, Latu Khanikar, Rashmi Rekha Gogoi, Kali Prasad Sarma, and Nilotpal Das

Subjects

Irrigation, 010504 meteorology & atmospheric sciences, Soil Science, chemistry.chemical_element, Aquifer, 010501 environmental sciences, engineering.material, 01 natural sciences, chemistry.chemical_compound, Environmental Chemistry, Arsenic, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology, Global and Planetary Change, geography, geography.geographical_feature_category, Environmental engineering, Geology, Pollution, Deposition (aerosol physics), chemistry, engineering, Carbonate, Water quality, Fertilizer, Groundwater

Abstract

The present work is an effort to develop an appraisal of the hydrogeochemical regime for the aquifers of Dhekiajuli, Sonitpur district, Assam, which is imperative considering: (i) excessive use of groundwater for irrigation; (ii) reported high arsenic (As) contamination; (iii) application of fertilizer is an inevitable process undergoing in this region to achieve higher yield owing to deteriorating water quality; and (iv) study area being the location of many tea estates of Assam, that export tea in many foreign countries. The highest As concentration of 44.39 µg/L was detected in this study (Bachasimalu and Sitalmari region), implying high As-contaminated aquifers being used for drinking and irrigation purposes in the area. The relative abundance pattern of major cations and anions was in the order of Na+ > Mg2+ > Ca2+ > K+ and HCO3 − > Cl− > SO4 2−, respectively. Majority of the samples belong to Na+–K+–Cl−–HCO3 − and mixed water type. Closer inspection of Piper plot reveals that a higher As value (>40 µg/L) was prevalent in HCO3 − water type. Results of hydrogeochemical plots suggest silicate and carbonate weathering, ion exchange and anthropogenic activities to be the dominant processes governing groundwater contamination, including As which is further supported from PCA loadings. The Singri area to the east of the affected areas and adjacent to the Brahmaputra River has oxic aquifers owing to the absence of mass deposition of younger sediments, while reducing conditions prevails in the Bachasimalu and Sitalmari region. High positive correlation between As and Fe (r = 0.83**) and a negative correlation between ORP and Fe (r = −0.68**) further add that Fe (hydr)oxides are the direct source of As release in the affected region, the mechanism being reductive hydrolysis of such (hydr)oxides. The study implies that although groundwater is suitable for irrigation use, there is a high probability of As getting into the food chain through tea and other edible plants irrigated with As-contaminated water; thus, the area has a maximum probability of facing health hazards caused by As-contaminated groundwater.

Published

2017

2. Seasonal disparity in the co-occurrence of arsenic and fluoride in the aquifers of the Brahmaputra flood plains, Northeast India

Author

Patrick J. Shea, Abhay Kumar, Jyoti Prakash Deka, Arbind Kumar Patel, Manish Kumar, Kali Prasad Sarma, Nilotpal Das, and Aparna Das

Subjects

Hydrology, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Arsenate, Soil Science, chemistry.chemical_element, Geology, Weathering, 010501 environmental sciences, 01 natural sciences, Pollution, chemistry.chemical_compound, chemistry, Piper diagram, Environmental chemistry, Environmental Chemistry, Carbonate, Sulfate, Fluoride, Arsenic, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology, Arsenite

Abstract

Arsenic (As) and fluoride (F−) in groundwater are increasing global water quality and public health concerns. The present study provides a deeper understanding of the impact of seasonal change on the co-occurrence of As and F−, as both contaminants vary with climatic patterns. Groundwater samples were collected in pre- and post-monsoon seasons (n = 40 in each season) from the Brahmaputra flood plains (BFP) in northeast India to study the effect of season on As and F− levels. Weathering is a key hydrogeochemical process in the BFP and both silicate and carbonate weathering are enhanced in the post-monsoon season. The increase in carbonate weathering is linked to an elevation in pH during the post-monsoon season. A Piper diagram revealed that bicarbonate-type water, with Na+, K+, Ca2+, and Mg2+ cations, is common in both seasons. Correlation between Cl− and NO3 − (r = 0.74, p = 0.01) in the post-monsoon indicates mobilization of anthropogenic deposits during the rainy season. As was within the 10 µg L−1 WHO limit for drinking water and F− was under the 1.5 mg L−1 limit. A negative correlation between oxidation reduction potential and groundwater As in both seasons (r = −0.26 and −0.49, respectively, for pre-monsoon and post-monsoon, p = 0.05) indicates enhanced As levels due to prevailing reducing conditions. Reductive hydrolysis of Fe (hydr)oxides appears to be the predominant process of As release, consistent with a positive correlation between As and Fe in both seasons (r = 0.75 and 0.73 for pre- and post-monsoon seasons, respectively, at p = 0.01). Principal component analysis and hierarchical cluster analysis revealed grouping of Fe and As in both seasons. F− and sulfate were also clustered during the pre-monsoon season, which could be due to their similar interactions with Fe (hydr)oxides. Higher As levels in the post-monsoon appears driven by the influx of water into the aquifer, which drives out oxygen and creates a more reducing condition suitable for reductive dissolution of Fe (hydr)oxides. An increase in pH promotes desorption of As oxyanions AsO4 3− (arsenate) and AsO3 3− (arsenite) from Fe (hydr)oxide surfaces. Fluoride appears mainly released from F−-bearing minerals, but Fe (hydr)oxides can be a secondary source of F−, as suggested by the positive correlation between As and F− in the pre-monsoon season.

Published

2017

3. Tracing phosphorous distributions in the surficial sediments of two eastern Himalayan high altitude lakes through sequential extraction, multivariate and HYSPLIT back trajectory analyses

Author

Sangeeta Singh, Jyoti Prakash Deka, Beli Baruah, Amit Prakash, M. Tamil Selvan, Pradip Bhattacharyya, Rahul Chaudhury, and Manish Kumar

Subjects

Hydrology, Global and Planetary Change, Phosphorus, Soil Science, Sediment, chemistry.chemical_element, Geology, Authigenic, Fractionation, Effects of high altitude on humans, Pollution, Nutrient, chemistry, Environmental chemistry, HYSPLIT, Environmental Chemistry, Precipitation, Earth-Surface Processes, Water Science and Technology

Abstract

Phosphorous (P) fractionation of the surficial sediment of high altitude lakes (HAL) i.e. P.T.Tso and Sella lakes of Arunachal Pradesh State, India were studied with an objective to investigate the phosphorus availability in the environment, nutrient status of the lake and the role of climate change. Moreover, the variation in phosphorous fraction was investigated through mineralogical studies like grain size analysis and X-ray diffraction. The findings revealed that the surficial sediment of lakes are least influenced by anthropogenic sources, since a slight increase in each of the P-Fractions was observed from year 2011 to 2012, except organic P. Loosely sorbed exchangeable phosphorous was found to be slightly high which was due to difference in atmospheric precipitation, which is one of the strong factors in high altitude regions. Decrease in organic fraction of P indicated that lakes became more oligotrophic in nature. Mineralogical investigation shows that illite-montmorillonite and montmorillonite are the main minerals in Sella Lake, whereas montmorillonite and graphite are main minerals in P.T.Tso lake. Factor analysis of seasonal data of P fractionation in surface sediments, along with physical parameters of Sella Lake water indicates three factors for the 2011 data principle factors are pH, EC, oxide-bound and organic P. Factor analysis of P.T.Tso lake water indicates three factors for the 2011 data with principle factors are adsorbed P and authigenic P, pH, oxide-bound P. This study shows that except organic fractions all other fractions are increasing in the following year. It implies that even at such remote high altitude locations P characteristics are changing year to year which sought for further investigation and enables HALs to show the early impacts of climate change related changes. A clear influence of long range transported air pollutants has been found through HYSPLIT back trajectory models which needs to be substantiated through long-term monitoring.

Published

2014

4. Imprints of long-range-transported pollution on high-altitude Eastern Himalayan lake water chemistry

Author

Sangeeta Singh, Jyoti Prakash Deka, Umesh Singh, Pawan Kumar Jha, and Manish Kumar

Subjects

Pollutant, Pollution, Global and Planetary Change, 010504 meteorology & atmospheric sciences, media_common.quotation_subject, Soil Science, Geology, Weathering, 010501 environmental sciences, Seasonality, medicine.disease, 01 natural sciences, Mineralization (biology), Altitude, Environmental chemistry, HYSPLIT, medicine, Environmental Chemistry, Precipitation, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology, media_common

Abstract

Pangang Teng Tso Lake, located at an altitude of 3962 m in the Eastern Lesser Himalaya, was monitored for seasonal variation in hydrogeochemical processes, major ions and levels of trace elements to understand the imprints of long-range-transported contamination. Results revealed that major cations except Na decreased, whereas major anions except NO3 − and PO4 3− increased in the post-monsoon. ANOVA indicated that pH, EC, TDS, Na+, HCO3 −, Cl− and NO3 −, PO4 3− showed significant seasonal variation in the P. T. Tso Lake. Wet precipitations of aerosols were found to be the most important source of major ions. Lake water chemistry is attributed to long-range transport of air pollutant through dry precipitation in the pre-monsoon, and by chemical weathering, biological and mineralization processes in post-monsoon. In pre-monsoon, trace elements were found to be in the order of Fe > Mn > Zn > Pb > Cu > Cr > Cd with slight change in Pb, Cd, Cr and Cu in post-monsoon. Hybrid Single-Particle Lagrangian Integrated Trajectory (HYSPLIT) model developed by NOAA’s Air Resources Laboratory was used to understand the long-range transport and depositions of aerosols. The results of HYSPLIT back-trajectory model illustrate that air arriving in the vicinity of the lake has an origin from the southeast direction and the mid-Gangetic plain during pre-monsoon and post-monsoon season, respectively. The interrelationship among trace elements in the projection of factor 1 and 2 implies that natural weathering and metal-containing aerosols transported from elsewhere may be the governing processes for lake water chemistry. The study suggests that seasonal changes in water chemistry of high-altitude lakes can reflect the imprints of change introduced through long-range-transported pollution. Long-term monitoring programs are recommended for periodic evaluation of the high-altitude lakes worldwide in order to trace climate change impacts.

Published

2016