Your search found 16 records
1 Agarwal, A. (Ed.) 1997. Homicide pesticides: What pollution does to our bodies. New Delhi, India: Centre for Science and Environment. 128p. (State of the environment series 4)
(Location: IWMI-HQ Call no: 632.95 G635 AGA Record No: H023090)
2 Er Rashid, H.; Kabir, B. 1998. Case study: Bangladesh - Water resources and population pressures in the Ganges River Basin. In de Sherbinin, A.; Dompka, V.; Bromley, L. (Eds.), Water and population dynamics: Case studies and policy implications. Report of a workshop, October 1996, Montreal, Canada. Washington, DC, USA: IUCN; PRB; USAID; AAAS. pp.171-194.
(Location: IWMI-HQ Call no: 333.91 G000 DES Record No: H025380)
3 Datta, K. K.; de Jong, C.; Singh, O. P. 2000. Reclaiming salt-affected land through drainage in Haryana, India: A financial analysis. Agricultural Water Management, 46(1):55-71.
(Location: IWMI-HQ Call no: PER Record No: H026843)
4 Rao, M. S.; Kumar, B.; Nachiappan, R. P.; Jagmohan. 2000. Identification of aquifer recharge sources and zones in parts of Ganga-Yamuna Doab using environmental isotopes. In Mehrotra, R.; Soni, B.; Bhatia, K. K. S. (Eds.), Integrated water resources management for sustainable development - Volume 1. Roorkee, India: National Institute of Hydrology. pp.271-281.
(Location: IWMI-HQ Call no: 333.91 G000 MEH Record No: H028053)
5 Shangle, A. K.; Pateria, B. D.; Pachauri, R. K. 2000. Status of pollution of Yamuna waters and remedial measures for its prevention. In Mehrotra, R.; Soni, B.; Bhatia, K. K. S. (Eds.), Integrated water resources management for sustainable development - Volume 1. Roorkee, India: National Institute of Hydrology. pp.355-364.
(Location: IWMI-HQ Call no: 333.91 G000 MEH Record No: H028060)
6 Trivedy, R. K. (Ed.) 2000. Pollution and biomonitoring of Indian Rivers. Jaipur, India: ABD Publishers. 344p.
(Location: IWMI-HQ Call no: 574.526323 G635 TRI Record No: H028408)
7 Farooqui, S. 2002. Tapping wastewater. Down to Earth, March:20-21.
(Location: IWMI-HQ Call no: P 6005 Record No: H029945)
(Location: IWMI-HQ Call no: VCD Col Record No: H035816)
9 Khanna, R. K.; Mathur, G. P. (Eds.) 2003. Proceedings, Round Table Conference on Water Quality and Wetlands: Socio- economic and Ecological Importance, New Delhi, India, 12-13 March 2003. Delhi, India: Ministry of Water Resource; Indian Water Resources Society. 225p.
(Location: IWMI HQ Call no: 333.918 G635 KHA Record No: H041291)
(Location: IWMI HQ Call no: 628.3 G635 NAR Record No: H043793)
(0.54 MB)
11 Water Channel. 2011. Water management in motion: six thematic DVDs including 60 videos, tutorials and key references. Wageningen, Netherlands: Water Channel. 6 DVDs.
(Location: IWMI HQ Call no: DVD col Record No: H044070)
12 Banerji, R. 2001. Non river: the Yamuna is a wash-out [Yamuna passes through cities, dying] Down to Earth, 200 Special:152-153.
(Location: IWMI HQ Call no: e-copy only Record No: H044445)
(0.34 MB)
13 Kloppmann, W.; Sandhu, C.; Groeschke, M.; Pandian, R. S.; Picot-Colbeau, G.; Fahimuddin, M.; Ahmed, S.; Alazard, M.; Amerasinghe, Priyanie; Bhola, P.; Boisson, A.; Elango, L.; Feistel, U.; Fischer, S.; Ghosh, N. C.; Grischek, T.; Grutzmacher, G.; Hamann, E.; Nair, I. S.; Jampani, Mahesh; Mondal, N. C.; Monninkhoff, B.; Pettenati, M.; Rao, S.; Sarah, S.; Schneider, M.; Sklorz, S.; Thiery, D.; Zabel, A. 2015. Modelling of natural water treatment systems in India: Learning from the Saph Pani case studies. In Wintgens. T.; Nattorp, A.; Elango, L.; Asolekar, S. R. (Eds.). Natural water treatment systems for safe and sustainable water supply in the Indian context: Saph Pani, London, UK: IWA Publishing. pp. 227-250.
(Location: IWMI HQ Call no: e-copy only Record No: H047553)
(12.42 MB) (3.9 MB)
(Location: IWMI HQ Call no: e-copy only Record No: H047958)
(1.10 MB)
We have determined the water quality index (WQI) of post-monsoon water samples with an aim to assess changes in Ganges river at various locations in Allahabad stretch including that from the confluence with river Yamuna. Physicochemical parameters such as temperature, pH, electrical conductivity (EC), dissolved oxygen (DO), total dissolved solids (TDS), major cations e.g. Na+ , K+ , Mg2+, Ca2+, major anions e.g. F, Cl, Br, SO4 2, NO3 , PO4 2 and alkalinity were analyzed by standard procedures. The values obtained were compared with the guideline values for drinking water by Bureau of Indian Standard (BIS) and World Health Organization (WHO). From the measured quantities, certain parameters were selected to derive WQI for the variations in water quality of each designated sampling site. Results showed considerable deterioration in quality of water at some of the sites. WQI of Ganges river water at Allahabad ranged from 86.20 to 157.69 which falls in the range of poor quality of water. Pearson’s correlation matrix was drawn to find possible interrelations among measured water quality parameters. It is shown that WQI may be a useful tool for assessing water quality and predicting trend of variation in water quality at different locations in the Ganges river.
(Location: IWMI HQ Call no: e-copy only Record No: H048716)
(0.23 MB)
The paper aims to understand how the public perceives river water quality and related risks and behaviour. Using the stratified semi-purposive sampling process, the study explores the perception of people residing along the river Yamuna in India. The method applied involved a structured questionnaire survey of 2706 respondents and four focused group discussions with people residing within two kilometres of the river bank. Non-parametric tests such as Kruskal Wallis, Mann Whitney U-test and One-Sample Wilcoxon Signed-Rank Test were used to analyse the data. The findings suggest that the majority of the respondents formulate their perceptions using non-scientific methods like sensorial and heuristics. Perception on sources of pollution is shaped by personal experiences and people do not perceive diffused sources of pollution that affect river water quality. Respondents attributed the pollution in the river to anthropogenic activities and their risk perception was found to be linked to their direct dependence on the river for their daily needs. The paper suggests behavioural change strategies to focus on social, governance, and technological drivers.
(Location: IWMI HQ Call no: e-copy only Record No: H050419)
(15.90 MB) (15.9 MB)
Northwestern India has been identified as a significant hotspot of groundwater depletion, with major implications for groundwater sustainability caused by excessive abstraction. We know relatively little about the detailed spatial and temporal changes in groundwater storage in this region, nor do we understand the interplay of factors controlling these changes. Groundwater managers and policymakers in India require such information to monitor groundwater development and make strategic decisions for the sustainable management of groundwater. Here, we characterise high-resolution spatio-temporal variability in groundwater levels and storage change across northwestern India through analysis of in situ measurements of historical groundwater level data. We note a slow gain in groundwater storage of + 0.58 ± 0.35 km3 for the pre-monsoon and + 0.40 ± 0.35 km3 for the post-monsoon period between 1974 and 2001. However, from 2002 to 2010, groundwater storage was rapidly depleted by -32.30 ± 0.34 km3 in the pre-monsoon and -24.42 ± 0.34 km3 in the post-monsoon period. Importantly, we observe marked spatial heterogeneity in groundwater levels and storage change and distinct hotspots of groundwater depletion with lateral length scales of tens of kilometers. Spatial variability in groundwater abstraction partially explains the depletion pattern, but we also find that the sedimentological heterogeneity of the aquifer system correlates broadly with long-term patterns of groundwater-level change. This correlation, along with the spatial agreement between groundwater level change and water quality, provides a framework for anticipating future depletion patterns and guiding groundwater monitoring and domain-specific management strategies.
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