- Debasish Chakraborty
- Saurav Saha
- Anup Das
- G. I. Ramkrushna
- Jayanta Layek
- A. K. Tripathi
- S. V. Ngachan
- B. U. Choudhury
- D. P. Patel
- D. J. Rajkhowa
- Debasish Chakroborty
- P. K. Ghosh
- N. Garg
- A. K. Sinha
- M. K. Sharma
- V. Gandhi
- R. M. Bhardwaj
- A. B. Akolkar
- Pawan Kumar Bharti
- Raju Joshi
- Shambhu Thakur
- A. K. Tyagi
- P. C. Moharana
- M. S. Raghuvanshi
- R. K. Bhatt
- R. K. Goyal
- H. M. Meena
- Mahesh Kumar
- Stanzin Landol
- R. H. Rizvi
- R. Vishnu
- A. K. Handa
- S. Ramanan
- M. Yadav
- A. Mehdi
- S. Londhe
- S. K. Dhyani
- J. Rizvi
- Punam
- Rameshwar Kumar
- Naved Qaisar
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z All
Singh, R. K.
- Change in Near-Surface Wind Velocity: What Implications will it have on Ecosystem and Agriculture?
Authors
1 Division of Agricultural Engineering, ICAR Research Complex for NEH Region, Umiam 793 103, IN
2 ICAR Research Complex for NEH Region, Mizoram Centre, Kolasib 796 081, IN
Source
Current Science, Vol 108, No 5 (2015), Pagination: 761-761Abstract
No Abstract.- Roof Water Harvesting in Hills - Innovations for Farm Diversification and Livelihood Improvement
Authors
1 ICAR Research Complex for NEH Region, Umiam 793 103, IN
2 ICAR-National Institute of Abiotic Stress Management, Baramati 413 115, IN
3 ICAR-Indian Grassland and Fodder Research Institute, Jhansi 284 003, IN
Source
Current Science, Vol 113, No 02 (2017), Pagination: 292-298Abstract
The north eastern region (NER) of India receives bountiful rains (>2000 mm) annually. However, there is extreme water scarcity during post- and premonsoon season (November-March). In such a situation, roof water harvesting (RWH) holds promise for multiple livelihood opportunities. RWH unit with polyfilm lined water collection tank of 37 m3 storage capacity (i.e. 5.5 x 4.5 x 1.5 m3) was demonstrated at 11 farmers fields mostly on hill tops in the Ri-Bhoi district (Meghalaya). The average demonstration area was 500 m2/farmer in the vicinity of homesteads (kitchen gardens). Volume of water harvested in a collection tank was about 53 m3 including about 16 m3 harvested during dry season due to seasonal replenishment. The cost of water harvesting was estimated at about Rs 144 and Rs 119/m3 considering lifespan of five and ten years respectively. Farmers used harvested water for diversified activities such as raising crops [maize, broccoli, French bean, laipatta (Brassica juncea), tomato, etc.] and livestock (pig or poultry) in addition to domestic use. The farmers without RWH could use land only during rainy season for crop cultivation. On an average, the net income from each RWH based model (500 m2 demonstration area) was Rs 14,910 for crop + piggery and Rs 11,410 for crop + poultry farming which was 261 and 176% higher, respectively than the normal farmers' practice. Similarly, employment and water use efficiency enhanced by 221 and 586%; and 168 and 218% under crop + piggery and crop + poultry based farming respectively.Keywords
Jalkund, Multiple Use of Water, NER Hills, Rain Water Harvesting, Silpaulin.References
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- Goswami, D. C., Flood forecasting in the Brahmaputra River, India: a case study. In Regional Cooperation for Flood Disaster Mitigation in the Hindkush Himalayas (eds Chalise, S. R. and Shreshtha, M.), ICIMOD.Internal Report, 2002, pp. 40–48.
- Sharma, B. R., Riaz, M. V., Pant, D., Adhikary, D. L., Bhatt, B. P. and Rahman, H., Water poverty in the north-eastern hill region (India): potential alleviation through multiple–use water systemscross learnings from Nepal Hills. New Delhi, India: International Water Management Institute (IWMI-NAIP Report 1), 2010, p. 44; doi:3910/2009.200.
- Mishra, A. K. and Satapathy, K. K., Food security vis-à-vis natural resources sustainability in northeastern region of India. ENVIS Bulletin: Himalayan Ecology, 11(1): GB Pant Institute of Himalayan Environment and Development, Kosi-Katarmal, Almora, India, 2003; http://gbpihed.nic.in/envis/HTML/vol 11_1/akmishra.htm
- Saha, R., Ghosh, P. K., Mishra, V. K. and Bujarbaruah, K. M.. Low-cost micro-rainwater harvesting technology (Jalkund) for new livelihood of rural hill farmers. Curr. Sci., 2007, 92(9), 1258–1265.
- Choudhury, B. U., Das, A., Ngachan, S. V., Bordoloi, L. J. and Chowdhury, P., Trend analysis of long term weather variables in midaltitude Meghalaya, North-East India. J. Agric. Phys., 2012, 12(1), 12–22.
- Das, A. et al., Integrated agricultural development in high altitude tribal areas - a participatory watershed programme in the East Indian Himalaya. Outlook Agric., 2013, 42(2), 141–144.
- Das, A., Saha, R., Ghosh, P. K., Munda, G. C. and Patel, D. P., Rainwater harvesting through Jalkund: a low cost dug-pit-cum polythene lined structure and its diversified use in NEH Region, abstract. Agriculture and forestry sciences. 96th Indian Science Congress, NEHU, Shillong, 3–7 January 2009, p. 75.
- Das, A. et al., Multiple use of pond water for enhancing water productivity and livelihood of small and marginal farmers. Indian J. Hill Fmg., 2013, 26 (1), 29–36.
- Patel, U. R., Patel, V. A., Balya, M. I. and Rajgor, H. M., Rooftop rainwater harvesting (RRWH) at SPSV campus, Vinegar: Gujarat – a case study. Int. J. Res. Eng. Technol., 2014, 03(04), 821–825.
- Samuel, M. P. and Satapathy K. K., Concerted rainwater harvesting technologies suitable agro-ecosystems of Northeast India. Curr. Sci., 2008, 95(9), 1130–1132.
- Study on the Establishment of a Diversified National Ambient Noise Monitoring Network in Seven Major Cities of India
Authors
1 CSIR-National Physical Laboratory, New Delhi 110 012, IN
2 Central Pollution Control Board, Parivesh Bhawan, East Arjun Nagar, Delhi 110 032, IN
3 Delhi Technological University, Delhi 110 042, IN
Source
Current Science, Vol 113, No 07 (2017), Pagination: 1367-1383Abstract
We describe the diversified National Ambient Noise Monitoring Network (NANMN) set up across 7 major cities of India and covering 70 stations for continuous noise monitoring throughout the year. The annual average Lday (06–22 h) and Lnight (22–06 h) values observed in 2015 for these 70 locations are described. Of these, 25 locations are in commercial zones, 12 in industrial, 16 in residential and 17 in silence zones. Each city has 10 noise monitoring stations installed for analysing environmental noise pollution levels round the clock (24 x 365 h). The long-term noise monitoring shows that ambient noise levels are very high compared to the recommended standards for some sites and thus noise abatement measures are essentially required for controlling these levels. The present study is focused on evaluation, analysis and reporting of environmental noise pollution in seven major cities of India and is instrumental in planning for the noise abatement measures for controlling noise pollution in these cities. Such a noise monitoring network established in India is unique and one of the largest noise monitoring networks of its kind across the globe.Keywords
Day Equivalent Level, Day–Night Average Sound Level, National Ambient Noise Monitoring Network, Night Equivalent Level.References
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- Metal Constituents of E-Waste Black Powder and Its Potential Utilization
Authors
1 R&D Division, IN
2 R&D Division, Shriram Institute for Industrial Research, 19, University Road, Delhi - 110 007, IN
3 Analytical Science Division, Shriram Institute for Industrial Research, 19, University Road, Delhi - 110 007, IN
4 Metal and Minerals Division, Shriram Institute for Industrial Research, 19, University Road, Delhi - 110 007, IN
Source
Current Science, Vol 116, No 1 (2019), Pagination: 104-107Abstract
Electronic waste (e-waste) generation is one of the major emerging problems of the modern era and requires consideration at the global, national and local levels. Moradabad, Uttar Pradesh, is one of the biggest hubs of e-waste recycling in India, where almost 50% of printed circuit boards (PCBs) waste of the country is being handled with the engagement of more than 50,000 people.
Black ash of PCBs is overtly dumped after carrying out recycling processes in the vicinity. The dumping is affecting the aquatic and terrestrial ecosystems of the vicinity due to this black powder ash. Analysis of ewaste black ash sample was carried out for metal content using ICP-OES. A significant amount of lead, copper, barium, tin, aluminium, silica, etc. was found in the e-waste black powder, which indicates the potential utilization of e-waste black powder in many applications. Hence there is an immediate need of an environment-friendly technology for e-waste recycling and to safeguard the environment.
Keywords
Black Powder, Electronic-Waste Recycling, Environmental Pollution, Metal Analysis.References
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- Song, Q. and Li, J., A systematic review of the human body burden of e-waste exposure in China. Environ. Int., 2014, 68, 82-93.
- Park, J. K., Hoerning, L., Watry, S., Burgett, T. and Matthias, S., Effects of electronic waste on developing countries. Adv. Recycl. Waste Manage., 2017, 2, 128; doi:10.4172/2475-7675.1000128.
- CSE, Recommendations to address the issues of informal sector involved in e-waste handling: Moradabad, Uttar Pradesh. Centre for Science and Environment, 2015, pp. 1-16.
- Garlapati, V. K., E-waste in India and developed countries: management, recycling, business and biotechnological initiatives. Renew. Sustain. Energy Rev., 2016, 54, 874-881.
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- Frost Heaves in the Cold Arid Leh–Ladakh Region: Observations on their Morphological Variability and Patterns as Indicators of Pastureland Degradation
Authors
1 ICAR-Central Arid Zone Research Institute, Jodhpur 342 003, IN
2 ICAR-National Bureau of Soil Survey and Landuse Planning, Nagpur 440 033, IN
3 ICAR-Central Arid Zone Research Institute, Regional Research Station, Leh, IN
Source
Current Science, Vol 119, No 5 (2020), Pagination: 799-807Abstract
This study analysed frost heave lands in the cold arid Leh–Ladakh region of the Himalaya, India through semi-detail field survey and remote sensing. Most of these sites are highland grasslands occurring along the alluvial plains of rivers in the Leh and Nubra valleys. The study identified the occurrence of some unique frost heave patterns whose morphometry varied from simple, isolated to complex ones with elongated, coalesced and superimposed bedforms. These lands can be further subdivided into vegetated and degraded types. The degraded forms exhibited several cracks, dry, collapsed and slump structures. Invasion of Cirsium arvense over native grass species, soil salinity and feeding pressure by livestock have been identified as major land degradation factors. C. arvense has replaced the native vegetation on frost heaves and has allowed Carex species to grow, which is known to degrade and deplete the pasture ecology.Keywords
Cold Arid Region, Frost Heaves, Morphological Variability And Patterns, Pastureland Degradation.- Mapping of Agroforestry Systems and Salix Species in Western Himalaya Agroclimatic Zone of India
Authors
1 ICAR-CSSRI Regional Research Station, Lucknow 226 005, IN
2 ICAR-Central Agroforestry Research Institute, Jhansi 284 003, IN
3 World Agroforestry, South Asia Regional Programme, New Delhi 110 012, IN
4 Himachal Pradesh Krishi Vishvidyalay, Palampur 176 062, IN
5 Sher-e-Kashmir University of Agriculture and Technology, Srinagar 190 025, IN
Source
Current Science, Vol 121, No 10 (2021), Pagination: 1347-1351Abstract
In the present study, agroforestry was mapped in nine districts from Western Himalayan Region. The agroforestry area in these nine selected districts was estimated to be 332127.55 ha (12.4%). Salix alba, an important agroforestry species, accounted for about 12% of total agroforestry area in three districts of Kashmir valleyKeywords
Agroclimatic Zone, Agroforestry Mapping, Object-Oriented Classification, Remote Sensing, Tree Species.References
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