Готові списки джерел за темами / Gangetic Plains

Добірка наукової літератури з теми "Gangetic Plains"

Автор: Grafiati
Опубліковано: 6 вересня 2023

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Статті в журналах з теми "Gangetic Plains"

1

NAVEEN P. SINGH, SURENDRA SINGH, BHAWNA ANAND, and P.C. Ranjith. "Assessing the impact of climate change on crop yields in Gangetic Plains Region, India." Journal of Agrometeorology 21, no. 4 (November 10, 2021): 452–61. http://dx.doi.org/10.54386/jam.v21i4.280.

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Against the increasing vulnerability of agriculture and farm livelihoods to climate change, the study attempted to analyse the trend in climate variables and their impact on major crop yields during the period from 1966-2011, across 4 agro-climatic zones forming Gangetic Plains Region. A rising trend was observed in annual and seasonal (kharif and rabi) mean maximum and minimum temperature across the zones. Rainfall on the other hand, showed a declining trend. Overall, climate change adversely impacted crop yield, but the magnitudes of such effects vary spatially. The results reveal that rice and wheat yield will decline in the entire Gangetic region. By 2050s, maize yield will be higher by 6 percent in Lower Gangetic Plains; pearl millet will increase by 15 percent and rapeseed & mustard by 3.8 percent in Trans-Gangetic Plains. Amongst the crops, sugarcane yield was the most impacted to climate change and is expected to reduce by 21 percent in Middle Gangetic Plains towards end of the century. Hence, there is a need to formulate sustainable adaptation measures and practices suitable to location-specific needs for enhancing climate resiliency and capacity of agricultural system to withstand climatic shocks.
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2

KASHYAPI, A., A. L. KOPPAR, and A. P. HAGE. "Crop specific requirement of growing degree days and agrometeorological indices in rice growing zones." MAUSAM 61, no. 4 (November 27, 2021): 569–76. http://dx.doi.org/10.54302/mausam.v61i4.915.

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The spatial and temporal distributions of heat unit and various agrometeorological indices for the rice crop, are studied in this paper. Eight ET – stations were selected from six rice growing zones, viz., Canning (in lower Gangetic plains), Bikramganj and Varanasi (in middle Gangetic plains), Ludhiana (in trans Gangetic plains), Ranchi, Shymakhunta (in eastern plateau and hills), Annamalai Nagar (in east coast plains and hill region) and Pattambi (in western plains and ghat region). Eleven crop growth stages were identified for this study, viz., germination, nursery seedling, transplanting, tillering, active tillering, lag phase, panicle initiation, flowering, grain formation, grain maturity and harvesting, the duration of each of the growth stages varied widely, station wise. Daily data were collected growth stagewise for latest available five years and the mean values were computed for the derived parameters, viz., the crop requirements of heat unit, agroclimatic rainfall index (ARI), yield moisture index (YMI), aridity index (AI). The study revealed that for rice crop the total degree days requirement varied from 1706 degree – days (at Ranchi) to 2815 degree – days (at Shymakhunta). It showed primary peak (with 16.7 % of total requirement) at active tillering stage. The ARI values were mostly higher than 100 per cent. The mean YMI values varied widely from 477 mm (at Bikramganj) to 1523 mm (at Pattambi). The values showed main peak at active tillering stage. The AI values showed moderate aridity at early growth stages, which increased at advanced crop growth stages.
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3

Rawat, Krishna Kumar, Afroz Alam, and Praveen Kumar Verma. "Checklist of mosses (Bryophyta) of Gangetic Plains, India." Bangladesh Journal of Plant Taxonomy 23, no. 2 (December 28, 2016): 97–106. http://dx.doi.org/10.3329/bjpt.v23i2.30818.

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An updated account of 79 taxa of mosses of Gangetic plains, representing 40 genera and 19 families, is provided. The family Pottiaceae with 17 taxa belonging to 9 genera appears most dominant and diversified family in the area while at generic level, the genus Fissidens (Fissidentaceae) with 19 species shows maximum diversity, followed by Hyophila and Physcomitrium each with five species.Bangladesh J. Plant Taxon. 23(2): 97-106, 2016 (December)
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4

TOMAR, K. P. "Chemistry of pedogenesis in Indo-Gangetic alluvial plains." Journal of Soil Science 38, no. 3 (September 1987): 405–14. http://dx.doi.org/10.1111/j.1365-2389.1987.tb02275.x.

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5

White, J. W., and A. Rodriguez-Aguilar. "An Agroclimatological Characterization of the Indo-Gangetic Plains." Journal of Crop Production 3, no. 2 (January 2001): 53–65. http://dx.doi.org/10.1300/j144v03n02_03.

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6

Nayak, Gourav, Ashwini Kumar, Srinivas Bikkina, Shani Tiwari, Suhas S. Sheteye, and A. K. Sudheer. "Carbonaceous aerosols and their light absorption properties over the Bay of Bengal during continental outflow." Environmental Science: Processes & Impacts 24, no. 1 (2022): 72–88. http://dx.doi.org/10.1039/d1em00347j.

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7

Sharma, Prashant, Manoj Singh, Kamlesh Verma, and Saroj Kumar Prasad. "Soil weed seedbank under different cropping systems of middle Indo-Gangetic Plains." Plant, Soil and Environment 68, No. 11 (November 28, 2022): 542–51. http://dx.doi.org/10.17221/162/2022-pse.

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Trees on agricultural fields can have a positive or negative impact on weed seedbank (WSB) due to diverse environmental and soil characteristics. Therefore, soil samples were drawn in six cropping systems [two agroforest systems (AFS): guava, mango; three horticulture systems (HCS): guava, mango, Indian gooseberry; and annual crop system (ACS)] at two landscape positions (lowland and upland) and two soil depths (0–15 cm and 15–30 cm) using factorial randomised block design each replicated three times. Results showed that guava-AFS had the highest WSB of different categories in general and individual weed species in particular, except for Eragrostis pilosa and Dactyloctenium aegyptium. Simultaneously, guava-AFS also showed the maximum Shannon-Weaver, species richness and Simpson index and was low in Whittaker statistics (βW). The species evenness varied non-significantly with the cropping systems. Similarly, the landscape position had no discernible effect on any weed diversity indices; however lowland landscape position was dominated by Cyperus spp. and E. pilosa, while the upland by Phyllanthus niruri. Furthermore, with the exception of βW, the WSB and diversity indices were found to be higher on the topsoil (0–15 cm). Our study establishes that the AFS system in the semi-arid sub-tropics has a more diverse WSB indicating a healthy system, as opposed to HCS, which has a dominance of certain weed species, opening the door for more severe infestation of invasive weed species.
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8

Dhatt, A. S. "PROSPECTS OF TEMPERATE FRUIT CULTIVATION IN INDO-GANGETIC PLAINS." Acta Horticulturae, no. 662 (December 2004): 107–9. http://dx.doi.org/10.17660/actahortic.2004.662.12.

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9

Saha, Pamela, and Devendra Singh. "Physcomitrium eurystomum (Bryophyta: Funariaceae) - An addition to Bryoflora of Central India." Indian Journal of Forestry 43, no. 4 (December 1, 2020): 341–44. http://dx.doi.org/10.54207/bsmps1000-2021-s04k5x.

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Анотація:
Physcomitrium eurystomum Sendtn. is recorded for the first time form Jharkhand, Central India, earlier known from West Himalayan, Western Ghats, Punjab and West Rajasthan and Gangetic Plains bryological territeries of India.
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10

Singh, S. "A new Rectolejeunea from Indian Botanic Garden, India." Indian Journal of Forestry 34, no. 3 (September 1, 2011): 341–44. http://dx.doi.org/10.54207/bsmps1000-2011-8l68j3.

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Rectolejeunea devendrae Sushil K.Singh, closely related to R. olivacea (Steph.) S.C. Srivast. and A. Agarwal, is described as a new species from Indian Botanic Garden, Howrah in Gangetic plains of West Bengal, India.
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Дисертації з теми "Gangetic Plains"

1

Duncan, John. "Assessing the vulnerability of the rice-wheat production system in the north-west Indo-Gangetic Plains to climatic drivers." Thesis, University of Southampton, 2013. https://eprints.soton.ac.uk/365371/.

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This thesis explores the spatial patterns in the vulnerability of the rice-wheat production systems of Punjab and Haryana to climate. Remote sensing monitoring is used to identify rice and wheat crop extents and to capture dynamics of the cropping system such as length of growing periods and cropland productivity. This remote sensing monitoring is integrated with analysis of climate datasets and other measures of the agricultural system to 1) identify the exposure of rice-wheat croplands to harmful climate drivers, 2) capture the sensitivity of the rice-wheat croplands to climate and to 3) inform targeted adaptations to improve climate resilience, ensure environmental sustainability and sufficient levels of production, the pillars of a climate-smart landscape. Across all India, including Punjab and Haryana, there was a fragmented spatial pattern in the occurrence, and sign, in trends of monsoon precipitation. This highlights the need for locally sensitive water resources management. Over 5 million ha of rice-wheat croplands in Punjab and Haryana were exposed to unfavourable trends in facets of monsoon precipitation; this was mainly exposure to increasing recurrence of drought years and increasing inter-annual variability in monsoon precipitation. However, crop yield-climate regression models indicated that precipitation is not influencing variability in rice or wheat crop production but growing season temperatures are. Average minimum and maximum temperature during the thermo-sensitive periods of crop development have a greater negative impact on wheat crop yield than exceedance of critical temperatures. The negative impact of warming on wheat crop production increased with later start-of-season dates. Through an integrated use of remote sensing datasets the spatial patterns in the magnitude and varying nature of the vulnerability of crop production to climate were captured. This enabled identification of location-specific stresses, such as later sowing dates, and targeting locally optimum adaptations.
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2

Alam, Md Khairul. "Assessment of soil carbon sequestration and climate change mitigation potential under conservation agriculture (CA) practices in the Eastern Gangetic Plains." Thesis, Alam, Md. Khairul (2018) Assessment of soil carbon sequestration and climate change mitigation potential under conservation agriculture (CA) practices in the Eastern Gangetic Plains. PhD thesis, Murdoch University, 2018. https://researchrepository.murdoch.edu.au/id/eprint/43726/.

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Conservation agriculture (CA) cropping is based on the principles of minimum soil disturbance, permanent soil cover with crop residue retention and crop rotations with diverse crops. The CA cropping performs well in improving soil health, increasing yield and increasing crop profit in the intensive rice-based, triple–cropping systems on the Eastern Gangetic Plain (EGP), but its effects on the greenhouse gas (GHG) emissions and the dynamics of carbon (C) and nitrogen (N) in the soil has not been studied properly. Two experiments lasting 5 years have examined soil C, N and life cycle GHG emissions in the EGP plains’ intensive rice (Oryza sativa L.)–based cropping soils of Bangladesh. The present study employed a streamlined life cycle assessment (LCA) approach to assess implications of GHGs from CA cropping in comparison with conventional cropping. Minimum disturbance of soil and increased residue retention were assessed at both long-term studies involving rice-based triple cropping systems at Durgapur and Godagari in the EGP since 2010. Component crops of the rice-based systems (lentil (Lens culinaris Medik), mustard (Brassica campestris L.), chickpea (Cicer arietinum L.), jute (Corchorus olitorius L.), early wet season rice & mustard) were established by strip planting (SP) and bed planting (BP), or following 3-4 tillage operations by 2-wheel tractor followed by hand-broadcast seeding and fertilizing (CT). All practices were compared with the conventional low residue retention or increased retention. In case of irrigated and rainfed rice, non-puddled (NP) transplanting were adopted in SP and BP; while soil puddling was used for CT. The life cycle GHG t-1 crop or rice equivalent yield (REY) were assessed under four practices of cropping a) traditional crop establishment practices (CT) with farmers’ practice of residue return (LR), b) CT with return of increased residues (HR); c) strip planting (SP for upland crop)/ transplanting on non-puddled soils (NP for rice) with LR or; d) SP/NP with HR. The cropping systems studied in the long-term trials were mustard-irrigated rice-monsoon rice at Alipur and wheat-jute-monsoon rice at Digram sites. The SP/NP of soils with HR sequestered carbon in soils after five years of cropping at both the locations, relative to current practices of cropping by farmers (CTLR). The increased soil C was associated with reduced CO2eq emissions (13 to 59 % lower than those under CT and BP with LR and HR, respectively, relative to SOC), reduced water soluble carbon (WSC, by 15-23 mg kg-1, relative to CT with LR and HR) contents in soils and increased potentially mineralizable C (PMC) and lower decay rate constant (e.g. 50 % in rice soils). Similarly, at each location (0–10 cm soil depth), SP, including NP, together with HR increased total N by 9 and 32 % relative to BPHR and CTHR and by 62 % relative to the current practice (CTLR), respectively. The increased total N in soil resulted from the increased potentially mineralisable N (PMN) with its low decay rate in soil under all crops with SPHR, relative to other tillage and residue retention practices. The total mineralisation of N in soils under SPHR was statistically equal to (in wheat and jute cropping) or was lower (in mustard and rice cropping) than those under CT with HR. However, soils under SP with residue retention practices had synchronized release of N with crop demand, while CT with LR or HR had increased mineralization during 0–45 days of crop establishment. Conservation agriculture involving SP, and NP of rice, together with HR, has altered the C and N cycling. The alterations were occurred by slowing the early mineralisation of N, reducing the level of mineral N available to plants in the early growing season (low N requirement) but increasing soil total N and plant N uptake by enhancing the synchrony between crop demand and available N supply. In case of C cycling, SP/BP with HR at both the locations modified the C cycle by slowing the in-season turnover of C and by increasing the levels of total organic C in the soil. For all crops in the mustard-irrigated rice-monsoon rice cropping system, SP/NP with LR and HR were the best actual life cycle GHG mitigation option. With the considerable accumulation of SOC (3.8 - 4.2 t CO2eq ha-1) in SP/NP at 0 10 cm soil depth after 5 years in comparison with CT, the life cycle GHG savings with the best mitigation practice (SP/NP with LR) for 1 t of rice-equivalent yield were 46 % relative to CT with LR. Production of 1 t of REY in the rice–based system caused 0.73, 0.74, 0.98 and 1.12 t of CO2eq LCA GHG emission (actual). Production of 1 t of irrigated rice in the EGP after accounting for C sequestered in soils accounted for 0.91, 0.95, 1.25 and 1.41 t CO2eq for NPLR, NPHR, CTLR and CTHR, respectively, whereas the LCA GHGs for the production of 1 t of monsoon rice were 1.10, 1.21, 1.4 and 1.65 t, respectively. For each unit RE mustard production, NPLR, NPHR, CTLR and CTHR were responsible for 0.09, 0.18, 0.31 and 0.29 t CO2eq, respectively. Overall, methane (CH4) released during the on-farm stage of the LCA represented the dominant contributor to LCA GHG in the cropping system. The GHG emitted by machinery usage at on-farm stage (irrigated rice), CO2 emission from soil respiration (monsoon rice), and GHG related to inputs manufacture (REY of mustard) were secondary sources in that order of magnitude. The NPLR and NPHR were the most effective GHG mitigation options when sequestered C was taken into account in footprints of component crops of rice-based rice-upland cropping system. The NPLR and NPHR practices avoided 51 % and 35 % of the actual LCA footprints compared with CTHR and current farmers’ practice, respectively. By not including soil C sequestration in the carbon footprint equation, the life cycle GHG estimates were over-estimated by 9 to 26 %. When soil C sequestration estimated by subtracting C losses from net primary production (NPP) was accounted for in the LCA GHG, the largest decrease in LCA GHG by 20 % was recorded in NPHR but LCA GHG increased by 12 % in CTLR. Overall, the NPLR and NPHR were the most effective GHG mitigation options in production of crops of mustard-irrigated rice-monsoon rice system but NPHR offered yield benefit and its higher CH4 emission was offset by the extra soil organic carbon (SOC) sequestration. The emerging CA approaches being developed for the EGP involving strip planting or NP have the potential to mitigate GWP of intensive rice-based triple cropping systems but further study is needed for a more diverse range of rice-dominant and rice-based triple cropping systems.
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3

Onial, Malvika. "Responses of biodiversity to agricultural intensification : a study in the upper Gangetic Plain, India." Thesis, University of Cambridge, 2011. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.609391.

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4

Chandra, Shobhit. "Fluvial landforms and sediments in the north-central Gangetic Plain, India." Thesis, University of Cambridge, 1993. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.309855.

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5

Gautam, Ritesh. "Aerosol-radiation-climate interactions over the Gangetic-Himalayan region." Fairfax, VA : George Mason University, 2008. http://hdl.handle.net/1920/3353.

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Анотація:
Thesis (Ph.D.)--George Mason University, 2008.
Vita: p. 167. Thesis director: Menas Kafatos. Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Earth Systems an GeoInformation Sciences. Title from PDF t.p. (viewed Jan. 11, 2009). Includes bibliographical references (p. 156-166). Also issued in print.
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Книги з теми "Gangetic Plains"

1

Musavi, Azra, and Orus Ilyas. Biodiversity Strategy and Action Plan: Gangetic Plains. Edited by Wildlife Society of India. New Delhi, India: Authors Press, 2016.

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2

Centre for Science and Environment (New Delhi, India), ed. Indo Gangetic links: A directory of environmental experts in the Indo Gangetic plains. New Delhi: Centre for Science and Environment, 2000.

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3

Ghosh, Prabhat P. A study on rural poverty in Gangetic plains: Profile and determinants. Patna: Asian Development Research Institute, 2003.

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4

1923-2003, Varma Shakuntala, ed. Kahe ko byahi bidesh: Songs of marriage from the Gangetic Plains. New Delhi: Lotus Collection, Roli Books, 2005.

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5

Nesemann, Hasko. Pictorial guide to acquatic macrophytes of the Gangetic plains of Bihar, India. Kolkata: Nature Books India, 2012.

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6

Sanyal, M. N. A handbook of excursion flora of the gangetic plains and adjoining hills. New Delhi: Mittal Publications, 1991.

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7

Material culture of Gangetic plains during first millennium B.C.: (an archaeological study). Varanasi: Kala Prakashan, 2000.

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8

Beginnings of urbanization in early historic India: A study of the gangetic plains. Patna: Novelty & Co., 1998.

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9

Veettil, Prakashan Chellattan. Productivity and efficiency impacts of zero tillage wheat in Northwest Indo-gangetic plains. Delhi: Institute of Economic Growth, University of Delhi, 2012.

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10

Erenstein, Olaf. Livelihoods, poverty and targeting in the Indo-Gangetic plains: A spatial mapping approach. New Delhi: CIMMYT, 2007.

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Частини книг з теми "Gangetic Plains"

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Joshi, C. S., A. N. Singh, and Manohar Lal. "Vertical Movement of Indo-Gangetic Plains." In Slow Deformation and Transmission of Stress in the Earth, 97–106. Washington, D. C.: American Geophysical Union, 2013. http://dx.doi.org/10.1029/gm049p0097.

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2

Valdiya, K. S. "Indo-Gangetic Plains: Evolution and Later Developments." In Society of Earth Scientists Series, 723–45. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-25029-8_22.

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3

Jha, S. K., S. Kumar, A. Shamna, M. L. Roy, and T. Samajdar. "Retrospect and Prospects of Resource Conservation Technologies in Indo- Gangetic Plains." In Conservation Agriculture and Climate Change Impacts and Adaptations, 457–67. London: CRC Press, 2022. http://dx.doi.org/10.1201/9781003364665-35.

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4

Sharma, Priyanka, M. L. Sharma, and V. A. Sawant. "Ground Response Analysis with Deep Bedrock Depth in Indo-Gangetic Plains." In Lecture Notes in Civil Engineering, 1–12. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-15-9984-2_1.

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Chakrabarti, B., U. Mina, D. Chakraborty, H. Pathak, D. K. Sharma, N. Jain, R. S. Jatav, P. Dixit, R. Katiyar, and R. C. Harit. "Water, Carbon and Nitrogen Footprints of Major Crops in Indo-Gangetic Plains." In Geospatial Infrastructure, Applications and Technologies: India Case Studies, 401–11. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-2330-0_29.

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6

Khurana, M. P. S., U. S. Sadana, and Bijay-Singh. "Sulfur Nutrition of Crops in the Indo-Gangetic Plains of South Asia." In Agronomy Monographs, 11–24. Madison, WI, USA: American Society of Agronomy, Crop Science Society of America, Soil Science Society of America, 2015. http://dx.doi.org/10.2134/agronmonogr50.c2.

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Chatterjee, Sudipto, Manab Das, Himanshu Rai, Dharmesh Singh, K. Preeti, and Vasundhara Pandey. "Gangetic Plains of India: High on the Water and Air Pollution Map." In Forest Dynamics and Conservation, 83–106. Singapore: Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-0071-6_4.

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Singh, Ramesh P. "Dust Storms and Their Influence on Atmospheric Parameters over the Indo-Gangetic Plains." In Geospatial Technologies and Climate Change, 21–35. Cham: Springer International Publishing, 2013. http://dx.doi.org/10.1007/978-3-319-01689-4_2.

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Bordoloi, Shreemoyee, Sweety Gogoi, and Robin K. Dutta. "A Low-Cost Arsenic Removal Method for Application in the Brahmaputra-Ganga Plains: Arsiron Nilogon." In Safe and Sustainable Use of Arsenic-Contaminated Aquifers in the Gangetic Plain, 289–98. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-16124-2_18.

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Shukla, Prabhakar, and Raj Mohan Singh. "Groundwater System Modelling and Sensitivity of Groundwater Level Prediction in Indo-Gangetic Alluvial Plains." In Groundwater, 55–66. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-10-5789-2_5.

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Тези доповідей конференцій з теми "Gangetic Plains"

1

Pandey, Satyendra K., and V. Vinoj. "The radiative effects of anthropogenic aerosols on clouds over the Indo-Gangetic Plains." In 2019 URSI Asia-Pacific Radio Science Conference (AP-RASC). IEEE, 2019. http://dx.doi.org/10.23919/ursiap-rasc.2019.8738767.

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2

Patil, Dinesh, Reema Chourey, Sarwar Rizvi, Manoj Singh, and Ritesh Gautam. "An automated fog monitoring system for the Indo-Gangetic Plains based on satellite measurements." In SPIE Asia-Pacific Remote Sensing, edited by Tiruvalam N. Krishnamurti and Madhavan N. Rajeevan. SPIE, 2016. http://dx.doi.org/10.1117/12.2228006.

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3

Ghosh, Aniruddha, and P. K. Joshi. "Identification of bamboo patches in the lower Gangetic plains using very high resolution WorldView 2 imagery." In SPIE Remote Sensing, edited by Ulrich Michel, Daniel L. Civco, Karsten Schulz, Manfred Ehlers, and Konstantinos G. Nikolakopoulos. SPIE, 2013. http://dx.doi.org/10.1117/12.2029192.

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4

Chauhan, Akshansha, and Ramesh P. Singh. "Poor air quality and dense haze/smog during 2016 in the indo-gangetic plains associated with the crop residue burning and diwali festival." In 2017 IEEE International Geoscience and Remote Sensing Symposium (IGARSS). IEEE, 2017. http://dx.doi.org/10.1109/igarss.2017.8128389.

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5

Singh, Prayagraj, Aditya Vaishya, and Shantanu Rastogi. "Radiative characterization of aerosols in the central Indo-Gangetic plain." In SPIE Asia-Pacific Remote Sensing, edited by Eastwood Im, Raj Kumar, and Song Yang. SPIE, 2016. http://dx.doi.org/10.1117/12.2223661.

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6

Vaishya, Aditya, Prayagraj Singh, Shantanu Rastogi, and S. Suresh Babu. "Source apportionment of absorbing aerosols in the central Indo-Gangetic Plain." In SPIE Asia-Pacific Remote Sensing, edited by Eastwood Im, Raj Kumar, and Song Yang. SPIE, 2016. http://dx.doi.org/10.1117/12.2223580.

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7

Vinoj, V., and Satyendra K. Pandey. "Towards understanding the variability of aerosol characteristics over the Indo-Gangetic Plain." In SPIE Asia-Pacific Remote Sensing, edited by Tiruvalam N. Krishnamurti and Madhavan N. Rajeevan. SPIE, 2016. http://dx.doi.org/10.1117/12.2223315.

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8

Vaishya, Aditya, S. Suresh Babu, V. Jayachandran, Mukunda M. Gogoi, N. B. Lakshmi, K. Krishna Moorthy, and K. Satheesh. "Spatial and Altitudinal Contrast in Aerosol Radiative Properties across the Indo-Gangetic Plain." In 2019 URSI Asia-Pacific Radio Science Conference (AP-RASC). IEEE, 2019. http://dx.doi.org/10.23919/ursiap-rasc.2019.8738411.

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9

Jose, Sandhya, Amit Kumar Mishra, and Sachchidanand Singh. "AEROSOL SIZE RESOLVED STUDY ON CLOUD RADIATIVE FORCING OVER THE INDO GANGETIC PLAIN." In 18th Annual Meeting of the Asia Oceania Geosciences Society (AOGS 2021). WORLD SCIENTIFIC, 2022. http://dx.doi.org/10.1142/9789811260100_0015.

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10

Prajapati, Satyam, Akhilesh Kumar, Prashant K. Chauhan, and Abhay K. Singh. "Variation of Aerosol Optical Depth and Radiative Forcing Over Indo-Gangetic Plain using AERONET." In 2022 URSI Regional Conference on Radio Science (USRI-RCRS). IEEE, 2022. http://dx.doi.org/10.23919/ursi-rcrs56822.2022.10118473.

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Звіти організацій з теми "Gangetic Plains"

1

Water Management Institute (IWMI), International. Women’s vulnerability to climatic and non-climatic change in the Eastern Gangetic Plains. International Water Management Institute (IWMI)., 2014. http://dx.doi.org/10.5337/2014.215.

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2

Water Management Institute (IWMI), International. Women’s vulnerability to climatic and non-climatic change in the Eastern Gangetic Plains. In Nepali. International Water Management Institute (IWMI)., 2014. http://dx.doi.org/10.5337/2014.218.

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3

Choudhary, Vishruta, and Avinash Kishore. Diets in eastern Gangetic Plains of South Asia: Brief assessment of sources and a comparison with the EAT-Lancet recommendations. Washington, DC: International Food Policy Research Institute, 2019. http://dx.doi.org/10.2499/p15738coll2.133590.

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