- N. Bahar
- K. S. Kapoor
- B. S. Pathak
- Ajaib Singh
- V. C. Thakur
- Sandeep Singh
- Ashok Kumar
- Nand Lal
- R. B. Sorkhabi
- Bijai Prasad
- Biswajayee A. Patra
- A. R. Vijan
- Stefan Claesson
- David G. Gee
- P. G. Andreasson
- R. M. Manickavasagam
- M. Shreshtha
- Priyom Roy
- A. K. Choudhary
- K. Chandra
- M. Gopinath Reddy
- M. S. Rama Mohan Rao
- K. C. Sharma
- R. B. Panwar
- J. Dogra
- S. Banerjee
- S. N. Misra
- Ashish Dixit
- Amit Upadhyay
- Naveen Sharma
- Ravish Shau
- Kumar Jain Vimal
- A. K. Singhai
- Nityanand Sharma
- P. K. Gupta
- Samidha D. Sharma
- Rajeev Kumar
- Sushmita
- P. K. Mukherjee
- A. K. Patel
- H. Yalla
- M. B. Verma
- L. K. Nanda
- Puneet Seth
- Mrinal Shreshtha
- Keser Singh
- S. C. Srivastava
- S. N. Singh
- L. Srivastava
- Indian Forester
- Journal of Geological Society of India (Online archive from Vol 1 to Vol 78)
- Current Science
- Journal of Rural Development
- The Indian Journal of Nutrition and Dietetics
- Research Journal of Pharmaceutical Dosage Form and Technology
- Asian Journal of Pharmaceutical Research and Health Care
- Power Research
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
Jain, A. K.
- Litter Production Pattern of Eucalyptus tereticornis Plantation in Protected and Unprotected Areas of Upper Gangetic Plain
Authors
Source
Indian Forester, Vol 127, No 7 (2001), Pagination: 814-820Abstract
Litter production patter in Eucalyptus tereticornis plantation of age 15 years has studied in protected and unprotected plots in upper Gangetic plain for a period of one year. A total of 7287.40 kg ha-1 oflitter was produced of which leaflitter contributed 5268.50 kg ha-1, twig litter 1396.10 kg ha-1 and bark litter 622.80 kg ha-1 in protected plot. However, in unprotected plots a total of 5478.20 kg ha-1 of litter was produced of which leaf litter contributed 4326.00 kg ha-1 , twig litter 740.20 kg ha-1 and bark litter 412.00 kg ha-1. It is also observed that total litter production was maximum during the month of July and minimum in the month of December in both protected and unprotected plots. The present study reveals that Eucalyptus tereticornis produces 33% more litter in protected plots as compared to unprotected one.- Joint Forest Management in Cuddapah Forest Division - a Successful Example
Authors
Source
Indian Forester, Vol 124, No 7 (1998), Pagination: 524-530Abstract
It has been realised that the forests can not be protected and developed without the involvement of local people. The 1988 National Forest Policy has also envisaged the involvement of local people in the protection and development of the Forests. In Cuddapah Forest Division, a tribal village by name Saibaba Nagar situated near the Palakonda Reserve Forest was identified in which the Joint Forest Management has been started with the active involvement of all the villagers by forming the Vana Samrakshana Samithi (Forest Protection Committee). A Non-Governmental Organisation has also involved actively in implementation of the Joint Forest Management in this village. The results are very encouraging and the villagers are taking very good interest in protection and development of the degraded forest.- Improvement of Natural Regeneration in Pterocarpus santalinus
Authors
Source
Indian Forester, Vol 122, No 9 (1996), Pagination: 783-786Abstract
By eliminating the Cymbopogon coloratus grass which is highly prone to forest fires as well as by removing the miscellaneous interfering growths like Ziziphus horrida, Bauhinia racemosa and Acacia sandra and also by taking up the soil and moisture conservation measures, the improvement in the natural regeneration in Red Sanders can be made to a large extent which will also help in the faster growth of seedlings of this very important Red Sanders tree species.- Characteristics of Leucaena leucocephala and Sesbania grandiflora Woods
Authors
Source
Indian Forester, Vol 113, No 3 (1987), Pagination: 228-232Abstract
Wood sample taken from the trunk of 3 year old Leucaena leucoceaphala tree was found to have a medium density and EMC and a higher heating value. Its cellulose and carbon contents were high and the ash content was low. Similar sample taken from Sesbania grandiflora plant had a low density and FMC. Compared to Leucaena leucocephala wood, it had lower heating value, less cellulose, more lignin, a lower carbon content Ind higher ash and silica contents. On the basis of the physical and chemical charaeleristics, Leucaena leucocephala wood is considered to be a superior fuel wood and a better raw material for gasification and pyrolysis.- Overthrusting and Emplacement of Basic Rocks in Lesser Himalaya, Garhwal, U. P.
Authors
1 Wadia Institute of Himalayan Geology, University of Delhi, Delhi, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 13, No 3 (1972), Pagination: 226-237Abstract
The metamorphosed basic rocks, probably emplaced along dislocation zones during overthrusting and facilitating such movements, are persistent at the base of Uttarkashi thrust sheet in the Precambrian-Lower Palaeozoic rocks of innermost Lesser Himalayan region of Uttarkashi, Garhwal. Marked absence of such basic rocks in Tertiary rocks, and along thrusts of Sub-Himalaya and outermost Lesser Himalaya in Garhwal, may be taken as indicating a probable Upper Cretaceous age for these intrusives related to the initial phase of Himalayan orogeny.- Strain History of the Pangin Synform of Siang District of NEFA Himalaya, As Deduced from Deformed Pebbles
Authors
1 Wadia Institute of Himalayan Geology, Delhi University Campus, Delhi, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 16, No 4 (1975), Pagination: 470-474Abstract
The deformed shapes of pebbles indicate that both the limbs of the Pangin Synform have suffered flattening-type deformation - the normal limb has undergone greater magnitude of flattening than the inverted limb. The longest axes of the pebbles, representing maximum elongation direction Of the tectonic strain ellipsoid, lie parallel and subparallel to the axial direction of the fold.- Abor Volcanics of the Arunachal Himalaya
Authors
1 Department of Geology and Geophysics, University of Roorkee, Roorkee 247672, U.P, IN
2 Wadia Institute of Himalayan Geology, Dehra Dun, U.P., IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 19, No 8 (1978), Pagination: 335-349Abstract
The Abor Volcanics of the Arunachal Himalaya are typically exposed along the Dihang Valley as penecontemporaneous lava flows, sills, dykes, volcanic breccia and metatuffs.
Although the Abor Volcanics are so far considered contemporaneous to the Panjal Volcanics of the North-West Himalaya, they are typically associated with probable Precambrian-Middle Palaeozoic Siang and Mid Groups and are distinctly older to the Gondwana. Thus, Late Precambrian-Lower Palaeozoic volcanic activity is widely manifested in the Himalaya from Kashmir to Arunachal Pradesh and is represented by the Baifliaz Volcanics in Kashmir, Mandt-Darla Volcanics (in parts) in Himachal Pradesh, penecontemporaneous lavas in Garhwal Group in Kumaon and Garhwal, Karnaprayag Volcanics, Bhowali Volcanics and Abor Volcanics. This volcanism is older to an equally widespread Late Palaeozoic volcanism of the Kashmir Himalaya and Eastern Himalaya.
- Kinematics of the Transverse Lineaments, Regional Tectonics and Holocene Stress Field in the Garhwal Himalaya
Authors
1 Department of Earth Sciences, University of Roorkee, Roorkee 247667 (U.P.), IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 30, No 3 (1987), Pagination: 169-186Abstract
Lineament and fracture trace analyses of the Indo-Gangetic Plain and different tectonic units of the Garhwal Himalaya reveal four important sets with strike-slip sense of movements. Horizontally-displaced lithologic and tectonic boundaries clearly depict the sense of displacement along certain lineaments, e.g. the Ganga and Yamuna. Also, small-scale straight fracture traces generally are associated with major fracture traces of lineaments in the sense of Riedel (R), Conjugate Riedel (R'). Displacement (D) and Thrust shears (P). L1 lineaments trend N5°-N10° and show dextral sense of displacement, while its conjugate sinistral set (L3) trends N50°. The other strike-slip fracture traces and lineaments trend N25° (L1) and N90° (L3) with a dextral and sinistral sense of displacement respectively. Kinematically. it seems that the orientation of maximum principal horizontal stressU 1. deduced from lineament and fracture trace analysis, has changed anticlockwise from N60° to N24° in space and time by an amount of 35°. Interplay of some important faults along some lineaments with the Krol Thrust in frontal parts of the Krol Thrust Sheet has produced the Dehradun Re-entrant as a lateral ramp unlike the other re-entrants in the Himalaya. Furthermore, present-day seismicity in the Garhwal Himalaya is controlled by certain transverse lineaments besides being associated with major thrusts.- Ductile Shearing of the Proterozoic Chor Granitoid in the Lesser Himalaya and its Tectonic Significance
Authors
1 Department of Earth Sciences, University of Roorkee, Roorkee - 247 667, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 47, No 1 (1996), Pagination: 133-138Abstract
A newly identified Chor Thrust demarcates the southern margin of the Proterozoic Chor granitoid massif within the Jutogh Group metamorphics of the Lesser Himalaya in Himachal Pradesh. Numerous shear criteria reveal a topto- SW overthrust-type Intense ductile strain along this margin and are consistent with the southward propagating nappes.- Late Cenozoic - Quaternary Thermo-Tectonic History of Wigher Himalayan Crystalline (HHC) in Kishtwar- Padar-Zanskar region, NW Himalaya: Evidence from Fission Track Ages
Authors
1 Department of Physics, Kurushetra University, Kurukshetra - 132 119, IN
2 Department of Geophysics, Kurukshetrauniversity, Kurukshetra - 132 119, IN
3 Department of Earth Sciences, University of Roorkee, Roorkee - 247 667, IN
4 Department of Geology, ArizonaState University, Tempe, Arizona 85287-1404, US
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 45, No 4 (1995), Pagination: 375-391Abstract
Fission Track (m) ages of apatite and zircon from the Higher Himalayan Crystalline (HHC), SE - Jammu and Kashmiralong Chenab-Suru-Dodarivers and their tributaries provide constraints on the cooling (<250°C) and exhumation history of these rocks. FT ages of apatite/zircon versus the topographic elevations of the host samples from different traverses provide linear relationships, indicating differential and secular nature of exhumation in the Himalaya. The HHC belt is exhumedat a rate of about 0.27 mm/a during Middle to Late Miocene. However, regional exhumation rate near the base along the Main Central Thrust and in central parts of the HHC from FT apatite ages is faster upto 0.35 mm/a since Late Miocene. Exhumation has considerably slowed down to 0.11 mm/a along its northern boundary and 0.02 mm/a along the Zanskar Shear Zone. No apparent faster exhurnationis discernible either along thee MCT or the Zanskar ShearZone (ZSZ). On the other hand, three large fold structures namely the Suru Dome, the Chisoti Dome and the Kishtwaranti formal window have indicated very young and fast exhumation of 0.33 mm/a, 1.1 mm/a and 3.6 mm/a respectively during the last 1 to 5 Ma.Keywords
Fission Track Ages, Geochronology, Crystallines, NW Himalaya.- Rajendra Kumak Goel (1932-1992)
Authors
1 Department of Earth Sciences, University of Roorkee, Roorkee 247 667, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 41, No 2 (1993), Pagination: 175-176Abstract
No Abstract.- Triassic Palynoflora from the Krishna-Godavari Basin (India) and its Stratigraphic Significance
Authors
1 KDM Institute of Petroleum Exploration, Oil & Natural Gas Commission, Dehradun-248 195, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 43, No 3 (1994), Pagination: 239-254Abstract
Triassic palynomorph assemblages are recorded from the subsurface sediments of the Krishna-Godavari Basin. Four palynological assemblage zones, ranging in age from Smithian to Norian are identified in different well sections. These assemblages closely resemble Early to Late Triassic palynoflora of northwestern Australia and represent the Onslow type palynoflora.
It is suggested that the subsurface sedimentary sections in this basin, which have yielded typical Smithian to Norian palynoflora, and are termed as "Chintalapudi Sandstones", be referred to as Maleri sequence or its equivalents.
Keywords
Krishna-Godavari Basin, Stratigraphy, Palaeobotany.- Biotite Rb-Sr Ages: Constraints on Exhumation of the Karakoram Metamorphic Complex, Eastern Ladakh
Authors
1 Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee - 247 667, IN
2 Geochronology Division, KDMIPE, ONGC, Kaulagarh Road, Dehradun - 248 001, IN
3 Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee - 247 667
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 67, No 1 (2006), Pagination: 27-31Abstract
Biotite and K-feldspar Rb-Sr ages from three granitoid intrusives within the Karakoram Metamorphic Belt (KMB), eastern Ladakh yield indistinguishable ages between 12-10 Ma. Since the closure temperature of biotite for Sr diffusion is 300±50°C, we interpret these ages due to exhumation at 10 to 7 km depth within the crust. This implies that the Pangong Metamorphic Belt of the KMB, located at the southern termination of the Eurasian Plate, was undergoing a fast exhumation in a transpressional regime during Middle Miocene. These data also indicates that the southern edge of the Eurasian Plate has exhumed rapidly in comparison to the Higher Himalayan Crystallines within the Indian Plate segment.Keywords
Rb-Sr Ages, Granitoids, Karakoram Complex, Eastern Ladakh.- 2.0 Ga Granite of the Lower Package of the Higher Himalayan Crystallines, Maglad Khad, Sutlej Valley, Himachal Pradesh
Authors
1 Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee - 247 667, IN
2 Laboratory for Isotope Geology, Swedish Museum of Natural History, Box 50007, SE- 104 05 Stockholm, SE
3 Department of Earth Sciences, Uppsala University, Villavagen 16, SE-752 36, Uppsala, SE
4 Department of Lithosphere and Biosphere Science, Solvegatan 12, SE-223 62, Lund, SE
5 Institute Instrumentation Centre, Indian Institute of Technology Roorkee, Roorkee 247 667, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 67, No 3 (2006), Pagination: 295-300Abstract
Along the Sutlej valley, the lower package of the Higher Himalayan Crystallines (HHC) exposes a small concordant to discordant intrusive grey granite -The Maglad Khad Granite, within garnet mica schist/Banded gneiss of the Jeori Formation. This body is fine grained and foliated along the margins, whereas the central part is relatively undeformed. This body along with aplites and pegmatites intrudes the country rock during early to syn-D1 deformation. This is later affected by the most pervasive D2-deformation producing gneissosity within the granite. U-Pb dating of zircons by conventional isotopic dilution technique yield an upper intercept age of 2068±5 Ma (2σ) from 6 zircon-Fractions with MSWD=0.93, constraining the age of crystallization in the basal parts of the HHC during Early Proterozoic as well as the constraining pre-Himalayan fabric development.Keywords
Higher Himalayan Crystallines, Maglad Khad Granite, Geochronology, U-Pb Zircon Dating, Sutlej Valley, Himachal Pradesh.- Shear Sense Analysis of the Higher Himalayan Crystalline Belt and Tectonics of the South Tibetan Detachment System, Alaknanda-Dhauli Ganga Valleys, Uttarakhand Himalaya
Authors
1 Department of Earth Sciences, Indian Institute of Technology, Roorkee 247 667, IN
2 CSIR-Central Building Research Institute, Roorkee 247 667, IN
Source
Current Science, Vol 108, No 6 (2015), Pagination: 1107-1118Abstract
In the central parts of Uttarakhand Himalaya, more than 20 km thick homoclinally NE-dipping Higher Himalayan Crystalline (HHC) Belt is thrust over the Lesser Himalaya Sedimentary Belt along the Main Central Thrust (MCT), and is almost continuously exposed between Helang and Malari along the Alaknanda and Dhauli Ganga valleys. The upper contact of this belt with the Martoli Formation of the Tethyan Himalayan Sequence is demarcated by the South Tibetan Detachment System (STDS). The belt is ubiquitously marked by small-scale asymmetrical structures like S-C and S-C' foliation, porphyroclasts and porphyroblasts, mineral fishes, intrafolial folds, duplex structures, ductile-brittle shear zones, and asymmetric shear boudins. Sense of ductile to brittle- ductile shearing has been determined from these structures across the whole belt, the MCT and the STDS, and reveals two phases of shear deformation: (a) an older top-to-SW upwards phase throughout the HHC, having an overall thrust geometry (DS1), and (b) a younger superposed top-to-NE downwards phase with normal fault sense from the middle to upper parts (DS2). These shear senses provide invaluable constraints on various tectonic models currently in use for the evolution of the Himalayan metamorphics.Keywords
Higher Himalayan Crystalline Belt, Shear Structures, Tectonic Models.- When did India-Asia Collide and Make the Himalaya?
Authors
1 Central Building Research Institute, Roorkee 247 667, IN
Source
Current Science, Vol 106, No 2 (2014), Pagination: 254-266Abstract
Critical evaluation and comparison of the available geological and geochronological data from the northern parts of the Himalaya and Trans-Himalaya mountains highlight that these mountains did not initially evolve by the collision of continents of the Indian and Asian plates. Instead, subducted Tethyan oceanic lithosphere in front of the Indian continent melted to produce the calc-alkaline suite of the Shyok-Dras volcanic arc and the Ladakh batholith. Hence, the Indian plate initially subducted beneath and started building up the then existing intra-oceanic island arc. Timing of the first impingement of the Indian and Asia plates has been better constrained at around 57.5 Ma by comparing (i) the bulk ages from the Ladakh batholith (product of partial melting of the Tethyan oceanic lithosphere) with (ii) the subducted continental lithospheric and UHP metamorphosed Indian crust in the Tso Morari, and (iii) biostratigraphy of the youngest marine sedimentation in Zanskar. Thus, the Himalaya witnessed its first rise and emergence from deeply exhumed terrain in the Tso Morari after around 53 Ma, followed by sequential imbrication of the Indian continental lithosphere and associated exhumation during rise of the Himalayan mountains from north to the south since 45 Ma.Keywords
Batholith, Collision of Plates, Intra-Oceanic Islands Arc, Lithosphere.- Microstructures of Mylonites Along the Karakoram Shear Zone, Tangste Valley, Pangong Mountains, Karakoram
Authors
1 Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee - 247 667, IN
2 Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee – 247 667, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 75, No 5 (2010), Pagination: 679-694Abstract
The Karakoram Shear Zone is a northwest-southeast trending dextral ductile shear zone, which has affected the granitic and granodioritic bodies of the southern Asian Plate margin in three distinct episodes. The ductile shearing of the granitic bodies at Tangste and Darbuk has resulted in the development of mylonites with mylonitic foliation and stretching lineation. More intense deformation is noted in the Tangste granite grading up to orthomylonite, as compared to the Darbuk granite. Kinematic indicators include S-C foliation, synthetic C' and C" antithetic shear bands, Type A s-mantled porphyroclasts, oblique quartz foliation, micro-shears with bookshelf gliding, mineral fishes including Group 2 mica fishes, and Type 1 and 2a pull-apart microstructures, and exhibit strong dextral sense of ductile shearing towards southeast. The textural features of the minerals, especially that of quartz and feldspar, indicate temperature of mylonitisation ranging between 300 and 500°C in the upper greenschist facies, and appear to have been evolved during exhumation as a consequence of oblique strike-slip movements along the Karakoram shear zone.Keywords
Karakoram Shear Zone, Mylonites, Texture, Kinematic Indicators, Karakoram, Uttarakhand.- Crustal Accretion and Metamorphism of Mesoarchean Granulites in Palghat-Cauvery Shear Zone, Southern India
Authors
1 Institute Instrumentation Centre, Indian Institute of Technology Roorkee, Roorkee - 247 667, IN
2 Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee - 247 667, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 77, No 3 (2011), Pagination: 227-238Abstract
This work provides unequivocal evidence of the existence of Mesoarchean granulite facies metamorphic event in the Palghat-Cauvery Shear Zone (PCSZ) of South India. Charnockite samples from two prominent hills at Kollaimalai (KM) and Pachchaimalai (PM) as well as from two quarries within the Bhavani Shear Zone (BSZ) have been analyzed for their Sm-Nd and Rb-Sr ages to investigate the existence or otherwise of the Archean granulite facies events within the PCSZ. The Rb-Sr whole-rock isochron ages for massive charnockites from both the hills appear to be contemporaneous at 2.9 Ga with the initial Sr isotopic ratios of 0.7012 and 0.7014, respectively. However, the Rb-Sr data for whole-rock samples of basic granulites from one of the quarries within the BSZ indicate open system behavior, while the charnockites from the other quarry have insufficient spread in 87Rb/86Sr ratios and do not yield any isochron. The Sm-Nd data, on the other hand, do not distinguish between the massive charnockite and the lowland charnockite and yield Depleted Mantle model ages in the range 2.98±0.3 Ga for all of them. The εT CHUR for all of these rocks are highly positive. Both the Sr isotopic ratios and positive εT CHUR values for these rocks strongly suggest a mantle source for all of them. An upper age limit of ∼3.28 Ga may be assigned to the crustal accretion of the protolith of all these rocks on the basis of their Nd model ages. The Rb-Sr isochron ages of 2.9 Ga for the two massifs could be the age of granulite facies metamorphism. Thus, the metamorphism in the KM and PM Hills took place within ∼100 Ma of crustal accretion of these rocks and probably was part of the same geological event of crust formation and metamorphism. The open system behavior with respect to Rb-Sr isotopes in the basic granulite from Bhavani is possibly due to the migration of Sr isotopes, triggered during the later shearing of these rocks.Keywords
Rb-Sr and Sm-Nd Geochronology, Granulite Facies Metamorphism, Southern Granulite Terrain.- Organisational Structure Involving Community for Effective Watershed Development
Authors
1 Irrigation & Command Area Development Department, Government of Andhra Pradesh, Hyderabad, IN
2 Centre for Economic and Social Studies (CESS), N.O. Campus, Begumpet, Hyderabad, IN
3 Monitoring Evaluation Learning and Documentation, IWMP, CES (Pvt) Ltd, Bangalore, IN
Source
Journal of Rural Development, Vol 30, No 4 (2011), Pagination: 421 - 432Abstract
Evaluation of watershed development projects time and again revealed that the development to be sustainable, calls for involvement of beneficiaries at all stages of development process so as to transform them as Self-Managers. The existing approaches in developing three watersheds under similar agro-climatic and socioeconomic conditions, developed by research, development and NGO agencies were assessed to identify an appropriate organisational structure for developing watersheds on a sustainable basis keeping productivity, conservation, livelihoods and equity concerns in harmony. The longitudinal approach (before and after situation) was adopted to measure the impact.
People's involvement was better in NGO managed watershed due to formation of affinity groups such as SHGs and UGs which remained active even after completion of the programme. The study has established the need for strengthening local level institution, by creating suitable institution at the district level, with capacities and capabilities in managing resources on long term basis for improving productivity and ensuring livelihoods to the rural communities. Strengthening local level institution with support from UGs formed at the village level to conserve and manage the resources related to crop production, livestock, water use and managing common properties would lead to sustainable development by transforming every individual as a partner of the programme. It is concluded that for sustainable development of watersheds, involvement of local level institutions supported by affinity groups and guided by technical persons at different levels on continuous basis was needed. Then alone the primary stakeholders can transform into self-managers.
- Epidemic Dropsy in Rajasthan-A Clinical Study
Authors
1 Department of Medicine-S. P. Medical College, Bikaner 334 001, Rajasthan, IN
Source
The Indian Journal of Nutrition and Dietetics, Vol 23, No 2 (1986), Pagination: 41-44Abstract
Epidemic dropsy is a disease caused by ingestion of the seeds or oil of the 'Mexican Poppy" (Argemone mexicana) and is characterised by edema in the feet, gastro intestinal disturbances, vascular changes and cardiac insufficiency.- Optimization of Formulation and Process Parameters and Product Evaluation of Galactomannan-Borate Complex Based Cream
Authors
1 Dept. of Pharma.Chemistry, R.N.S Institute of Pharmaceutical Science and Technology SItholi, Gwalior (m.p.), IN
2 Dept. of Pharmacology, G.R.Medical College, Gwalior (M.P.), IN
3 R.N.S Institute of Pharmaceutical Science and Technology Sitholi, Gwalior, (M.P.), IN
4 Lakshmi Narain College of Pharmacy, Bhopal (M.P.), IN
Source
Research Journal of Pharmaceutical Dosage Form and Technology, Vol 1, No 3 (2009), Pagination: 229-232Abstract
Optimization of formulation and process parameters and product evaluation of galactomannan and galactomannan-borate complex based liquid paraffin cream were performed in the present study. The concentrations of galactomannan and borax were optimized. Process parameters of galactomannan and galactomannan-borate complex based liquid paraffin cream were optimized. The product evaluation of galactomannan and galactomannan-borate complex based liquid paraffin cream was performed. The galactomannan and galactomannan-borate based complex was compared with vanishing cream.Keywords
Galactomannan, Emulsifying Agent, Borax.- Review of Adoption of Disruptive Innovative Practices in Medical Tourism in India
Authors
1 IMS-DAVV, Indore – 452001, Madhya Pradesh, IN
2 Prestige Law College, Indore - 452 010, Madhya Pradesh, IN
3 Saudi Electronic University, Abha, SA
Source
Asian Journal of Pharmaceutical Research and Health Care, Vol 9, No 3 (2017), Pagination: 112-123Abstract
The Indian Medical Tourism Industry is significantly adding nearly 3% to the total size of healthcare sector of India. Surgical techniques and healthcare technologies have undergone revolutionary changes in past four decades giving way to early adoption of disruptive innovative practices by the quality conscious and low cost medical tourism industry in India. This secondary data based research paper aims at examining the adoption and use of Disruptive Innovative Practices in Medical Tourism Industry in India. It was concluded that Medical Tourism Industry in India is not only suitable but most probable to adopt and use the Disruptive Innovative Practices. The implication of the paper would be the encouragement of further research on disruptive innovative Practices in Medical care in India.Keywords
Disruptive Innovative Practices, Medical Tourism Industry.References
- Govindarajan V, Kopalle PK. The usefulness of measuring disruptiveness of innovations ex-post in making ex-ante predictions. Journal of Product Innovation Management. 2006; 23(1):12–6. https://doi.org/10.1111/j.1540-5885.2005.00176.x
- Schmidt GM, Druehl CT. When Is a disruptive innovation disruptive? Journal of Product Innovation Management. 2008; 25(4):347–22. https://doi.org/10.1111/j.1540-5885.2008.00306.x
- Bower JL, Christensen CM. Disruptive technologies: catching the wave. Harvard Business Review. 1995 Jan–Feb; 73(1):43–10.
- Prime India Biz Services-Health Tourism Indian. Available from: www.health-tourism-india.com.
- Smith MD. Disruptive innovation: Can health care learn from other industries? A conversation with Clayton M. Christensen; 2007.Available from: http://content. healthaffairs.org/content/26/3/w288.full
- Carrera PM, Bridges JFP. Globalisation and Healthcare: Understanding health and medical tourism. Expert review of pharmacoeconomics and Outcomes Research.2006; 6(4):447–7. PMid:20528514. https://doi.org/10.1586/14737167.6.4.447
- Connell J. Medical tourism: Sea, sun, sand and ... surgery. Tourism Management.2006; 27(6):1093–7. https://doi.org/10.1016/j.tourman.2005.11.005
- Forgione DA, Smith PC. Medical tourism and its impact on the US health care system. Journal of Health Care Finance. 2007; 34(1):27–8. PMid:18972983.
- Grennan T. A wolf in sheep's clothing? A closer look at medical tourism. Medical Ethics. 2003; 1(1):50–4.
- Gahlinger P. The medical tourism travel guide. USA: Sunrise River Press, North Branch; 2008.
- Kwoh YS, Hou J, Jonckheere EA, Hayati S. A robot with improved absolute positioning accuracy for CT guided stereotactic brain surgery. IEEE Trans Biomed Eng. 1988 Feb; 35(2):153–8. DOI: 10.1109/10.1354. 2013. https://doi.org/10.1109/10.1354
- Barbash GI, Glied SA. New technology and health care costs- The case of Robot-Assisted surgery. The New England Journal of Medicine. 2010 Aug; 363:701–3. DOI: 10.1056/NEJMp1006602. https://doi.org/10.1056/NEJMp1006602
- Apollo Hospitals Enterprise Limited [IN]. Available from: https://www.apollohospitals. com/lets-talk health/international/2016/02/01/technology-revolution-the-state-of-indian-healthcare-2016/
- Bradley WG Jr. MR‐guided focused ultrasound: a potentially disruptive technology. Journal of the American College of Radiology. 2009 Jul; 6(7):510–3. PMid:19560068. https://doi.org/10.1016/j.jacr.2009.01.004
- Coye M J, Haselkorn A, DeMello S. Remote patient management: technology‐enabled innovation and evolving business models for chronic disease care. Health Affairs (Millwood). 2009 Jan; 28(1):126–35. PMid:19124862. https://doi.org/10.1377/hlthaff.28.1.126
- Benner M. Catching up in pharmaceuticals: Government policies and the rise of genomics. Australian Health Review. 2004 Nov 8; 28(2):161–70. PMid:15527396. https://doi.org/10.1071/AH040161
- Carlson RJ. The disruptive nature of personalized medicine technologies: Implications for the health care system. Public Health Genomics. 2009; 12(3):180–4. PMid:19204421. https://doi.org/10.1159/000189631
- Conti R, Veenstra DL, Armstrong K, Lesko LJ, Grosse SD. Personalized medicine and genomics: Challenges and opportunities in assessing effectiveness, cost‐effectiveness, and future research priorities. Medical Decision Making. 2010 May; 30(3):328‐–40. PMid:20086232 PMCid:PMC4598076. https://doi.org/10.1177/0272989X09347014
- Drews J. Strategic trends in the drug industry. Drug Discovery Today. 2003 May 1; 8(9):411–20. https://doi.org/10.1016/S1359-6446(03)02690-4
- Greenhalgh T, Procter R, Wherton J, Sugarhood P, Hinder S, Rouncefield M. What is quality in assistive living technology? The ARCHIE framework for effective telehealth and telecare services. BMC Medicine. 2015. DOI: 10.1186/s12916-015-0279-6. https://doi.org/10.1186/s12916-015-0279-6
- Szold A, Bergamaschi R, Broeders I, Dankelman J, Forgione A, Lango T, et al. European Association of Endoscopic Surgeons (EAES) consensus statement on the use of robotics in general surgery. Surg Endosc. 2015; 29:253–35. PMid:25380708. https://doi.org/10.1007/s00464-014-3916-9
- Gawede R, Prasad H, Garg P. Life saving disruptions. TechTalk@KPIT. 2014; 7(10).
- Sultana S, Haque A, Momen A, Yasmın F. Factors affecting the attractiveness of medical tourism destination: an empirical study on India. Iran J Public Health. 2014; 43(7):867–9. Available from: http://www.tandfonline.com/doi/full/10.1080/13683500.2014.937324 PMid:25909055 PMCid:PMC4401052
- Ormond M, Sulianti D. More than medical tourism: Lessons from Indonesia and Malaysia on South–South intra-regional medical travel. Current Issues Tourism 2014. DOI: 10.1080/13683500.2014.937324. https://doi.org/10.1080/13683500.2014.937324
- Mochi P, Shetty N, Vahoniya D. Medical tourism-destination India. Commerce and Management.2013; 2(3): 29–10.
- Mishra R, Shailesh K. Making Indian healthcare market a global medical tourism destination. IOSR Journal of Business and Management. 2012; 2(4):23–5. https://doi.org/10.9790/487X-0242328
- Underwood HR, Makadon HJ. Medical tourism: Game‐changing innovation or passing fad? Healthcare Financial Management Articles. 2010 Sep; 64(9):112–4, 116, 118.
- Kane GC, Fichman RG, Gallaugher J, Glaser J. Community relations 2.0. Harvard Business Rev. 2009 Nov; 87(11):45–5. PMid:19891388
- Burns LR, David G, Helmchen LA. Strategic response by providers to specialty hospitals, ambulatory surgery centers, and retail clinics. Population Health Management. 2011 Apr; 14(2):69–8. DOI0: 10.1089/pop.2010.0021. Epub 2010 Nov 23. https://doi.org/10.1089/pop.2010.0021
- Fox N, Ward K, O'Rourke A. The birth of the e‐clinic. Continuity or transformation in the UK governance of pharmaceutical consumption? Social Science and Medicine. 2005 Oct; 61(7):1474–84. PMid:16005782. https://doi.org/10.1016/j.socscimed.2005.03.011
- Levy F. Computers and the supply of radiology services: anatomy of a disruptive technology. Journal of the American College of Radiology. 2008 Oct; 5(10):1067–72. PMid:18812150. https://doi.org/10.1016/j.jacr.2008.05.022
- Shih G, Lakhani P, Nagy P. Is android or iPhone the platform for innovation in imaging informatics? J Digit Imaging. 2010 Feb; 23(1):2–7. Available from: http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2809941/pdf/10278_ 2009_Article_9242.pdf.
- Potchen EJ, Clarke B. Transformative technology: A conversation with E. James Potchen and Bill Clarke. Interview by John K. Inglehart. Health Affairs. 2007 Mar-Apr; 26(2):227–35. PMid:17298955. https://doi.org/10.1377/hlthaff.26.2.w227
- Hillman BJ. The diffusion of new imaging technologies: a molecular imaging prospective. Journal of the American College of Radiology. 2006 Jan; 3(1):33–7. PMid:17412004. https://doi.org/10.1016/j.jacr.2005.08.010
- Christensen CM. The innovator's dilemma: When new technologies cause great firms to fail. Boston: Harvard Business School Press; 1997.
- Walsh ST. Roadmapping a disruptive technology: A case study-the emerging microsystems and top-down nanosystems industry. Technological Forecasting and Social Change. 2004; 71(1-2):161–24. Available from: https://doi.org/10.1016/j.techfore.2003. 10.003
- Maniyka J, Chui M, Bughin J, Dobbs R, Bisson P, Marrs A. Disruptive technologies: Advances that will transform life, business, and the global economy. McKinsey Global Institute; 2013 May.
- Halamandaris VJ. Telemedicine revolution makes the home the center of health care. Caring. 2004 Jul; 23(7):52–5. PMid:15341303
- Windle J, Van‐Milligan G, Duffy S, McClay J, Campbell J. Web‐based physician order entry: an open source solution with broad physician involvement. AMIA Annual Symposium Proceedings; 2003. p. 724–7. Available from: http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1480193/pdf/amia2003_0724.pdf
- Westbrook JI, Braithwaite J. Will information and communication technology disrupt the health system and deliver on its promise? The Medical Journal of Australia. 2010 Oct 4; 193(7):399–1. PMid:20919970.
- Topol EJ. Transforming medicine via digital innovation. Science Translational Medicine. 2010 Jan 27; 2(16):16cm4. PMCid:PMC3756088. https://doi.org/10.1126/scitranslmed.3000484
- Auerswald P. Healthcare in the home: How distributed health service delivery can reduce costs and improve outcomes. GMU school of public policy research paper No. 15-5; 2015. Available from: http://ssrn.com/abstract=2550739
- Venkatramanan P, Rathina I. Healthcare leveraging internet of things to revolutionize healthcare and wellness. IT Services Business Solutions Consulting. Tata Consultancy Services Limited; 2014. PMCid:PMC4018955
- Shah SG, Fitton R, Hannan A, Fisher B, Young T, Barnett J. Accessing personal medical records online: A means to what ends? International Journal of Medical Informatics. 2015; 84(2):111–7. PMid:25453275. https://doi.org/10.1016/j.ijmedinf.2014.10.005
- Christensen CM, Grossman JH, Hwang J. The innovator's prescription: A disruptive solution for health care. New York, USA: McGraw-Hill; 2008.
- Downing GJ. Policy perspectives on the emerging pathways of personalized medicine. Dialogues in Clinical Neurosciences. 2009; 11(4):377–87. PMid:20135895 PMCid:PMC3181936
- Christensen CM, Raynor ME. The Innovator's Solution: Creating and sustaining successful growth. Boston: MA: Harvard Business School Press; 2003.
- Markides C. Disruptive innovation: In need of better theory. Journal of Product Innovation Management. 2006; 23(1):19–6. https://doi.org/10.1111/j.1540-5885.2005.00177.x
- Harvard Medical School. Personally controlled Health Record Infrastructure. Boston, Mass: Harvard Medical School; 2006. Available from: www.pchri2006.org
- Press Information Bureau, Government of India. 2016 May 22. Available from: http://pib.nic.in/newsite/PrintRelease.aspx?relid=145527
- Early–Middle Eocene Exhumation of the Trans-Himalayan Ladakh Batholith, and the India–Asia Convergence
Authors
1 Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee 247 667, IN
2 CSIR-Central Building Research Institute, Roorkee 247 667, IN
3 Sri Sri University, Cuttack 754 006, IN
Source
Current Science, Vol 113, No 06 (2017), Pagination: 1090-1098Abstract
Very fast Early–Middle Eocene exhumation of theTrans-Himalayan Ladakh Batholith (LB) is revealedby new Rb–Sr biotite and zircon fission-track agesalong with the already published ages on these minerals.Exhumation peaked at 3.5 ± 0.9 mm/a between50–45 Ma (40Ar/39Ar hornblende ages) and 48–45 Ma(Rb–Sr biotite ages) as a consequence of the India–Asia convergence. It was followed by deceleration at arate of 1.2 ± 0.2 mm/a until 43–42 Ma (zircon FT ages),like the Deosai batholith in the west. Exhumationrates finally decreased during Oligocene to a minimumof ~0.1 mm/a before a mild late Miocene–Holocene acceleration. Lower-Middle Eocene exhumationof the LB was tectonically controlled by slabbreak-off of the Neo-Tethys oceanic lithosphere and underthrusting of the Himalayan Metamorphic Belt.Keywords
Early–Middle Eocene Exhumation, Fission Track, Ladakh Batholith, Tectonics.References
- Platt, J. P., Exhumation of high-pressure metamorphic rocks: a review of concepts and processes. Terra Nova, 1993, 5, 119–133.
- Hodges, K. V., Parrish, R. R., Housh, T. B., Lux, D. R., Burchfiel, B. C., Royden, L. H. and Chen, Z., Simultaneous Miocene extension and shortening in the Himalayan orogen. Science, 1992, 258, 1446–1470.
- Ring, U., Horizontal contraction or horizontal extension: heterogeneous Late Eocene and Early Oligocene general shearing during blueschist and greenschist-facies metamorphism at the PennineAustroalpine boundary zone in the Western Alps. Geol. Rundsch., 1995, 84, 843–859.
- Ring, U., Brandon, M. T., Lister, G. S. and Willet, S., Exhumation processes. In Exhumation Processes: Normal Faulting, Ductile Flow and Erosion (eds Ring, U. et al.), Geol. Soc. London, Spec. Publ., 1999, vol. 154, 1–28.
- Wobus, C. W., Hodges, K. V. and Whipple, K. X., Has focused denudation sustained active thrusting at the Himalayan topographic front? Geology, 2003, 31, 861–864.
- Searle, M. P. et al., The closing of the Tethys and the tectonics of the Himalaya. Geol. Soc. Am. Bull., 1987, 98, 678–701.
- Jain, A. K., Kumar, D., Singh, S., Kumar, A. and Lal, N., Timing, quantification and tectonic modeling of Pliocene Quaternary movements in the NW Himalaya: evidences from fission track dating. Earth Planet. Sci. Lett., 2000, 179, 437–451.
- Montomoli, C., Carosi, R. and Salvatore, I., Tectonometamorphic discontinuities in the Greater Himalayan sequence: a local or a regional feature. In Tectonics of the Himalaya (eds Mukherjee, S. et al.), Geol. Soc. London Spec. Publ., 2014, 412, 25–41.
- Thiede, R. C. and Ehlers, T. A., Large spatial and temporal variations in Himalayan denudation. Earth Planet. Sci. Lett., 2013, 371–372, 278–293.
- Patel, R. C., Singh, S., Asokan, A., Manickavasagam, R. M. and Jain, A. K., Extensional tectonics in the collisional Zanskar Himalayan belt. In Himalayan Tectonics (eds Treloar, P. J., Searle, M. P.), Geol. Soc. London, Spec. Publ., 1993, 74, 445–459.
- Hodges, K. V., Bowring, S. A., Davidek, K. L., Hawkins, D. and Krol, M., Evidence for rapid displacement on Himalayan normal faults and the importance of tectonic denudation in the evolution of mountain ranges. Geology, 1998, 26, 483–486.
- Thiede, R. C., Arrowsmith, J. R., Bookhagen, B., McWilliams, M. O., Sobel, E. R. and Strecker, M. R., From tectonically to erosionally controlled development of the Himalayan orogen. Geology, 2005, 33, 689–692.
- Honegger, K., Dietrich, V., Frank, W., Gansser, A., Thoni, M. and Trommsdorff, V., Magmatism and metamorphism in the Ladakh Himalaya (the Indus-Tsangpo suture zone). Earth Planet. Sci. Lett., 1982, 60, 253–292.
- Hodges, K. V., Tectonics of the Himalaya and southern Tibet from two decades perspective. Geol. Soc. Am. Bull., 2000, 112, 324–350.
- Weinberg, R. F. and Dunlap, J., Growth and deformation of the Ladakh Batholith, Northwest Himalayas: Implications for timing of continental collision and origin of calcalkaline batholith. J. Geol., 2000, 108, 303–320.
- Rolland, Y., Pecher, A. and Picard, C., Middle Cretaceous back-arc formation and arc evolution along the Asian margin: the Shyok Suture Zone in Northern Ladakh (NW Himalaya). Tectonophysics, 2000, 325, 145–173.
- White, L. T., Ahmad, T., Ireland, T. R., Lister, G. and Forster, M. A., Deconvolving episodic age spectra from zircons of the Ladakh Batholith, northwest Indian Himalaya. Chem. Geol., 2011, 289, 179–196.
- Dunlap, W. J., Weinberg, R. F. and Searle, M. P., Karakoram fault zone rocks cool in two phases. J. Geol. Soc. London, 1998, 155, 903–912.
- Clift, P. D., Carter, A., Krol, M. and Kirby, E., Constraints on India-Eurasia collision in the Arabian sea region taken from the Indus Group, Ladakh Himalaya, India. In The Tectonic and Climatic Evolution of the Arabian Sea Region (eds Clift, P. D.), Geol. Soc. London, Spec. Publ., 2002, 195, 97–116.
- van der Beek, P., Van Melle, J., Guillot, S., Pêcher, A., Reiners, P. W., Nicolescu, S. and Latif, M., Eocene Tibetan plateau remnants preserved in the northwest Himalaya. Nature Geosci., 2009, 2, 364–368.
- Kirstein, L. A., Foeken, J. P. T., van der Beek, P., Stuart, F. M. and Phillips, R. J., Cenozoic unroofing history of the Ladakh Batholith, western Himalaya, constrained by thermochronology and numerical modelling. J. Geol. Soc., London, 2009, 166, 1–12; doi:10.1144/0016-76492008-107.
- Kirstein, L. A., Sinclair, H., Stuart, F. M. and Dobson, K., Rapid early Miocene exhumation of the Ladakh batholith, western Himalaya. Geology, 2006, 34, 1049–1052.
- Reiners, P. W., Todd A. E. and Zeitler, P. K., Past, Present, and future of thermochronology. Rev. Mineral. Geochem., 2005, 58, 1–18.
- Raz, U. and Honneger, K., Magmatic and tectonic evolution of the Ladakh block from field studies. Tectonophysics, 1989, 161, 107–118.
- Thakur, V. C., Geology of the Western Himalaya, Pergamon Press, Oxford, 1993, p. 355.
- Scharer, U., Hamet, J. and Allegre, C. J., The Transhimalaya (Gangdese) plutonism in the Ladakh region: a U–Pb and Rb–Sr study. Earth Planet. Sci. Lett., 1984, 67, 327–339.
- Debon, F., Le Fort, P., Sheppard, S. M. F. and Sonet, J., The four plutonic belts of the Transhimalaya-Himalaya: a chemical, mineralogical, isotopic and chronological synthesis along a Tibet-Nepal section. J. Petrol., 1986, 27, 219–250.
- Kumar, S., Bora, S., Sharma, U. K., Yi, K. and Kim, N., Early Cretaceous subvolcanic calc-alkaline granitoid magmatism in the Nubra-Shyok valley of the Shyok Suture Zone, Ladakh Himalaya, India: evidence from geochemistry and U–Pb SHRIMP zircon geochronology. Lithos, http://dx.doi.org/10.1016/j.lithos.2016.11.019.
- Gansser, A., The significance of the Himalayan suture zone. Tectonophysics, 1980, 62, 37–52.
- Le Fort, P., Himalayas: the collided range, present knowledge of the continental arc. Am. J. Sci., 1975, 275, 1–44.
- Rolland, Y., Picard, C., Pêcher, A., Lapierre, H., Bosch, D. and Keller, F., The cretaceous Ladakh arc of NW Himalaya – slab melting and melt – mantle interaction during fast northward drift of Indian Plate. Chem. Geol., 2002, 182, 139–178.
- Yin, A., Cenozoic tectonic evolution of the Himalayan orogen as constrained by along-strike variation of structural geometry, exhumation history, and foreland sedimentation. Earth Sci. Rev., 2006, 76, 1–131.
- Jain, A. K., Singh, S. and Gupta, K. R., A Late Cretaceous Karakoram Shear Zone and its reactivation during the Late Cenozoic. Int. Assoc. Gondwana Res. Mem., 2007, 10, 77–88.
- Jain, A. K. and Singh, S., Geology and Tectonics of the Southeastern Ladakh and Karakoram. Geological Society of India, Bangalore, 2009, pp. 179.
- Jain, A. K., Continental subduction in the NW-Himalaya and Trans-Himalaya. Ital. J. Geosci., 2016, 135(2), doi: 10.3301/IJG.2015.43.
- Singh, S., Kumar R., Barley, M. and Jain, A. K., U–Pb SHRIMP ages and depth of emplacement of Ladakh Batholith, NW Himalaya. J. Asian Earth Sci., 2007, 30, 490–503.
- St-Onge, M. R., Rayner, N. and Searle, M. P., Zircon age determinations for the Ladakh batholith at Chumathang Northwest India: implications for the age of the India–Asia collision in the Ladakh Himalaya. Tectonophysics, 2010, 495, 171–183.
- Jain, A. K., When did India–Asia collide and make the Himalaya? Curr. Sci., 2014, 106(2), 254–266.
- Jain, A. K., Singh, S., Manickavasagam, R. M., Joshi, M. and Verma, P. K., HIMPROBE Programme: Integrated studies on geology, petrology, geochronology and geophysics of the TransHimalaya and Karakoram. Mem. Geol. Soc. India, 2003, 53, 1–56.
- Jain, A. K. and Singh, S., Tectonics of the southern Asian Plate margin along the Karakoram Shear Zone: Constraints from field observations and U–Pb SHRIMP ages. Tectonophysics, 2008, 451(1–4), 186–205.
- Maheo, G., Bertrand, H., Guillot, S., Villa, I. M., Keller, F. and Capiez, P., The south Ladakh ophiolites (NW Himalaya, India): an intra-oceanic tholeiitic origin with implication for the closure of the Neo-Tethys. Chem. Geol., 2004, 203, 273–303.
- Ahmad, T., Tanaka, T., Sachan, H. K., Asahara, Y., Islam, R. and Khanna, P. P., Geochemical and isotopic constraints on the age and origin of the Nidar Ophiolitic Complex, Ladakh, India: Implications for the Neo-Tethyan subduction along the Indus suture zone. Tectonophysics, 2008, 451, 206–224.
- Leech, M. L., Singh, S. and Jain, A. K., Continuous metamorphic zircon growth and interpretation of U–Pb SHRIMP Dating: an example from the Western Himalaya. Int. Geol. Rev., 2007, 49, 313–328.
- Guillot, S., Replumaz, A., Hattori, K. and Strzerzynski, P., Initial geometry of western Himalaya and ultrahigh pressure metamorphic evolution. J. Asian Earth Sci., 2007, 30, 557–564.
- Kumar, R., Lal Nand, Singh Sandeep and Jain, A. K., Exhumation history of Trans-Himalayan Ladakh Batholith as constrained by fission track apatite and zircon ages. Curr. Sci., 2007, 92(4), 490–496.
- Sorkhabi, R. B., Jain, A. K., Nishimura, S., Itaya, T., Lal, N., Manickavasagam, R. M. and Tagami, T., New age constraints on the cooling and unroofing history of the Trans Himalayan Ladakh batholith (Kargil area), N. W. India. Proc. Indian Acad. Sci. (Earth Planet. Sci.), 1994, 103, 83–97.
- Bouilhol, P., Jagoutz, O., Hanchar, J. M. and Dudas, F. O., Dating the India–Eurasia collision through arc magmatic records. Earth Planet. Sci. Lett., 2013, 366, 163–175.
- Schlup, M., Carter, A., Cosca, M. and Steck, A., Exhumation history of eastern Ladakh revealed by 40Ar/39Ar and fission track ages: the Indus river-Tso Morari transect, NW Himalaya. J. Geol. Soc. London, 2003, 160, 385–399.
- Bhutani, R., Pande, K. and Venkatesan, T. R., Tectono-thermal evolution of the India–Asia collision zone based on 40Ar–39Ar thermochronology in Ladakh. India. Proc. Indian Acad. Sci., 2004, 113, 737–754.
- Clift, P. D., Shimizu, N., Laynge, G., Gaedicke, C., Schulter, H. U., Clark, M. and Amjad, S., Development of the Indus Fan and its significance for the erosional history of the western Himalaya and Karakoram. Geol. Soc. Am. Bull., 2001, 113, 1039–1051.
- Sinclair, H. D. and Jaffey, N., Sedimentology of the Indus Group, Ladakh, Northern India: implications for the timing of initiation of paleo-Indus River. J. Geol. Soc. London, 2001, 158(1), 151–162.
- Kohn, M. J. and Parkinson, C. D., Petrological case for Eocene slab breakoff during the Indo-Asian collision. Geology, 2002, 30(7), 591–594.
- de Sigoyer, J. et al., Dating the Indian continental subduction and collisional thickening in the northwest Himalaya: multichronology of the Tso Morarieclogites. Geology, 2000, 28, 487–490.
- Leech, M. L., Singh, S., Jain, A. K., Klemperer, S. L. and Manickavasagam R. M., Early, steep subduction of India beneath Asia required by early UHP metamorphism. Earth Planet. Sci. Lett., 2005, 234, 83–97.
- Guillot, S., Maheo, G., de Sigoyer, J., Hattori, K. H. and Pêcher, A., Tethyan and Indian subduction viewed from the Himalayan high-to ultrahigh-pressure metamorphic rocks. Tectonophysics, 2008, 451, 225–241.
- Migmatization, Granite Generation and Melt Accumulation in the Himalayan Orogenic Channel, Central and Eastern Bhutan
Authors
1 CSIR-Central Building Research Institute, Roorkee 247 667, IN
2 Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee 247 667, IN
3 Department of Geosciences, Texas Tech University, Lubbock, TX 79409, US
Source
Current Science, Vol 114, No 09 (2018), Pagination: 1903-1912Abstract
In Central and Eastern Bhutan Himalaya, the Great Himalayan Sequence (GHS) reveals mesoscopic structures within the migmatite–leucogranite association due to crustal anataxis above the Main Central Thrust (MCT). The first phase of dominant melting generates stromatitic migmatite along the main foliation during high grade of metamorphism, possibly by dehydration melting. Subsequent ductile strike–slip shearing caused in situ melting in dilatational sites to produce structureless, non-foliated patchy leucogranite leucosome as well as in boudin necks and post-tectonic patches. In addition, melt-enhanced deformation caused doming of accumulated melt and subsidiary ductile shear zones on either margins of these domes. Surrounded by biotite-rich melanosome, leucosomes destroy the pre-existing foliation during new anatectic phase, which post-dates earlier stromatitic migmatite. These migmatites are the snapshot of mutual relations between newly-developed migmatite and leucogranite melt, and signify the transportation of Himalayan Orogenic Channel to the extreme south in Central and Eastern Bhutan over the Lesser Himalayan sedimentary belt along the MCT.Keywords
Bhutan, Channel, Himalayan Orogenic Migmatite, Leucogranite.References
- Brown, M., The definition of metatexis, diatexis and migmatite. Proc. Geol. Assoc., 1973, 84(4), 371–382.
- Harris, N. B. W., Ayres, M. and Massey, J., Geochemistry of granitic melts produced during the incongruent melting of muscovite: Implications for the extraction of Himalayan leucogranite magmas. J. Geophys. Res., 1995, 100, 15767–15777; doi:10.1029/94JB02623.
- Sawyer, E. W., Atlas of migmatites. Can. Miner. Spec. Publ., 2008, 9, 386.
- Mehnert, K. R., Migmatites and the Origin of Granitic Rocks, Elsevier Publ. Co, Amsterdam, 1968, p. 405.
- Wimmenauew, W. and Bryhni, I., Migmatite and related rocks: a proposal on behalf of the IUGS Subcommission on the Systematics of Metamorphic Rocks, 2007, www.bgs.uk/scmr/home.html (web version 1 February 2007).
- Searle, M. P., Crustal melting, ductile flow, and deformation in mountain belts: Cause and effect relationships. Lithosphere, 2013, 5(6), 547–554; doi:10.1130/RF.L006.1.
- St-Onge, M. R., Searle, M. P. and Wodicka, N., Trans-Hudson orogen of North America and Himalaya-Karakoram-Tibet orogen of Asia: Structural and thermal characteristics of the lower and upper plates. Tectonics, 2006, 25, TC4006; doi:10.1029/2005TC 001907.
- Harris, N. and Massey, J., Decompression and anataxis of Himalayan metapelites. Tectonics, 1994, 13(6), 1537–1546; doi:10.1029/94TC01611.
- Neogi, S., Dasgupta, S. and Fukuoka, M., High P–T polymetamorphism, dehydration melting, and generation of migmatites and granites in the Higher Himalayan Crystalline Complex, Sikkim, India. J. Petrol., 1998, 39, 61–99.
- Singh, S., Status of magmatic ages in the Himalaya: a review of geochronological studies. J. Indian Geophys. Union, 2001, 5(1), 57–72.
- Searle, M. P., Cottle, J. M., Streule, M. J. and Waters, D. J., Crustal melt granites and migmatites along the Himalaya: melt source, segregation, transport and granite emplacement mechanisms. Earth Environ. Sci. Trans. R. Soc. Edinb., 2010, 100, 219–233.
- Guo, Z. and Wilson, M., The Himalayan leucogranites: constraints on the nature of their crustal source region and geodynamic setting. Gondwana Res., 2012, 22(2), 360–376.
- Imayama, T., Takeshita, T., Yi, K., Cho, D. L., Kitajima, K., Tsutsumi, Y. and Sano, Y., Two-stage partial melting and contrasting cooling history within the Higher Himalayan Crystalline Sequence in the far-eastern Nepal Himalaya. Lithos, 2012, 134, 1–22.
- Visona, D., Carosi, R., Montomoli, C., Peruzzo, L. and Tiepolo, M., Miocene andalusite leucogranite in central-east Himalaya (Everest–Masang Kang area): low-pressure melting during heating. Lithos, 2012, 144, 194–208.
- Jain, A. K., Seth, P., Shreshtha, M., Mukherjee, P. K. and Singh, K., Structurally-controlled melt accumulation: Himalayan migmatites and related deformation, Dhauli Ganga Valley, Garhwal Himalaya. J. Geol. Soc. India, 2013, 82, 313–318.
- Weinberg, R. F., Himalayan leucogranites and migmatites: nature, timing and duration of anataxis. J. Metamorph. Geol., 2016, doi:10.1111/jmg.12204.
- Bhargava, O. N., The Bhutan Himalaya: a geological account. Spec. Publ. Ser. Geol. Surv. India, Director General, Geological Survey of India, Kolkata, 1995, vol. 39, p. 245.
- Long, S. and McQuarrie, N. and Tobgay, T., Tectonostratigraphy of the Lesser Himalaya of Bhutan: implications for the along strike stratigraphic continuity of the northern Indian margin. Geol. Soc. Am. Bull., 2011, 123, 1406–1426; doi:10.1130/B30202.1.
- McQuarrie, N., Long, S. P. and Tobgay, T., Documenting basin scale, geometry, and provenance through detrital geochemical data: lesson from the Neoproterozoic to Ordovician Lesser, Greater, and Tethyan Himalayan strata of Bhutan. Gondwana Res., 2013, 23, 1491–1510; doi:10.1016/j.gr.2012.09.002.
- Dasgupta, S, Jaishidanda Formation. In Bhutan Himalaya: A Geological Account (ed. Bhargava, O. N.), Geol. Surv. India Spec. Publ., Director General, Geological Survey of India, Kolkata, 1995, vol. 39, pp. 79–88.
- Davidson, C., Grujic, D. E., Hollister, L. S. and Schmid, S. M., Metamorphic reactions related to decompression and synkinematic intrusion of leucogranite, High Himalayan Crystalllines, Bhutan. J. Metamorph. Geol., 1997, 15(5), 593–612.
- Daniel, C. G., Hollister, L. S., Parrish, R. R. and Grujic, D., Exhumation of the Main Central Thrust from lower crustal depths, eastern Bhutan Himalaya. J. Metamorph. Geol., 2003, 21, 317–334; doi:10.1046/j.1525-1314.2003.00445.x.
- Grujic, D., Hollister, L. S. and Parrish, R. R., Himalayan metamorphic sequence as an orogenic channel: insight from Bhutan. Earth Planet. Sci. Lett., 2002, 198, 177–191.
- Zeiger, K., Gordon, S. M., Long, S. P., Kylander-Clark, A. R. C., Agustsson, K. and Penfold, M., Timing and conditions of metamorphism and melt crystallization in Greater Himalayan rocks, eastern and central Bhutan: insight from U–Pb zircon and monazite geochronology and trace-element analyses. Contrib Mineral. Petrol., 2015, 169, 47; doi:10.1007/s00410-015-1143-6.
- Grujic, D., Channel flow and continental collision tectonics. In Channel Flow, Ductile Extrusion and Exhumation in Continental Collision Zones (eds Law, R. D., Searle, M. P. and Godin, L.), Geol. Soc. Spec. Publ., vol. 268, 2006, pp. 25–37.
- Yin, A., Cenozoic tectonic evolution of the Himalayan orogen as constrained by along-strike variation of structural geometry, exhumation history, and foreland sedimentation. Earth-Sci. Rev., 2006, 76, 1–131; doi:10.1016/j.earscirev.2005.05.004.
- Brown, M., The generation, segregation, ascent and emplacement of granite magma: the migmatite-tocrustally-derived granite connection in thickened orogens. Earth-Sci. Rev., 1994, 36, 83–130.
- Brown, M., Averkin, Y. A., McLellan, E. L. and Sawyer, E. W., Melt segregation in migmatites. J. Geophys. Res., 1995, 100(B8), 15655–15679.
- Platt, J. P. and Vissers, R. L. M., Extensional structures in anisotropic rocks. J. Struct. Geol., 1980, 2, 397–410.
- Jain, A. K., Sushmita and Singh, Sandeep, Photograph of the month. J. Struct. Geol., 2014, 59, 50.
- Arslan, A., Passchier, C. W. and Koehn, D., Foliation boudinage. J. Struct. Geol., 30, 291–309.
- Davidson, C., Hollister, L. S. and Schmid, S. M., Role of melt during deformation in the deep crust. Terra Nova, 1994, 6, 133–142.
- Brown, M. and Solar, G. S., Shear-zone systems and melts: feedback relations and self- organization in orogenic belts. J. Struct. Geol., 1997, 20(2/3), 211–227.
- Berger, A. and Kalt, A., Structures and melt fractions as indicators of rheology in cordierite- bearing migmatites of the Bayersche Wald (Variscan Belt, Germany). J. Petrol., 1999, 40, 1699–1719.
- Brown, M., Orogeny, migmatites and leucogranites: a review. Earth Planet. Sci. Lett., 2001, 110(4), 313–336.
- Sawyer, E. W., Melt segregation in the continental crust. Geology, 1994, 22, 1019–1022.
- Jung, S., Hoernes, S., Masberg, P. and Hoffer, E., The petrogenesis of some migmatites and granites (Central Damara Orogen, Namibia): evidence for disequilibrium melting, wall-rock contamination and crystal fractionation. J. Petrol., 1999, 40(8), 1241–1269.
- Brown, M. and Rushmer, T., The role of deformation in the movement of granitic melt: views from the laboratory and the field. In Deformation-Enhanced Fluid Transport in the Earth′s Crust and Mantle (ed. Holness, M. B.), Chapman & Hall, London, 1997, pp. 111–144.
- Snoke, A. W., Kalakay, T. J., Quick, J. E. and Sinigoi, S., Deep-crustal shear zone as a result of mafic igneous intrusion in the lower crust, Ivrea-Verbano Zone, Southern Alps, Italy. Earth Planet. Sci. Lett., 1999, 166, 31–45.
- Hutton, D. H. W., Depster, T. J., Brown, P. E. and Becker, S. D., A new mechanism of granite emplacement: intrusion in active extensional shear zones. Nature, 1990, 343, 452–455.
- Vernon, R. H. and Paterson, S. R., Axial-surface leucosomes in anatectic migmatites. Tectonophysics, 2001, 335, 183–192.
- Ord, A., Mechanical controls on dilatant shear zones. In Deformation Mechanisms, Rheology and Tectonics (eds Knipe, R. J. and Rutter, E. H.), Geol. Soc. London Spec. Publ., 1990, 54, 183–192.
- D’Eramo, F., Tubía, J. M., Pinotti, L., Vegas, N., Coniglio, J., Demartis, M., Aranguren, A. and Basei, M., Granite emplacement by crustal boudinage: example of the Calmayo and El Hongo plutons (Córdoba, Argentina). Terra Nova, 2015, 25, 423–430.
- Hollister, L. S. and Crawford, M. L., Melt enhanced deformation: a major tectonic process. Geology, 1986, 14, 558–561.
- Webb, A. A. G., Yin, A., Harrison, T. M., Célérier, J. and Burgess, W. P., The leading edge of the Greater Himalayan Crystallines revealed in the NW Indian Himalaya: Implications for the evolution of the Himalayan Orogen. Geology, 2007, 35, 955–958; doi:10.1130/G23931A.1.
- Jain, A. K. and Manickavasagam, R. M., Inverted metamorphism in the intracontinental ductile shear zone during Himalayan collision tectonics. Geology, 1993, 21, 407–410.
- Beaumont, C., Jamieson, R. A., Nguyen, M. H. and Lee, B., Himalayan tectonics explained by extrusion of a low-viscosity crustal channel coupled to focused surface denudation. Nature, 2001, 414, 738–742.
- Jain, A. K. and Manickavasagam, R. M., Singh, Sandeep and Mukherjee, S., Himalayan collision zone: new perspectives-its tectonic evolution in a combined ductile shear zone and channel flow model. Himal. Geol., 2005, 26(1), 1–18.
- Godin, L., Grujic, D., Law, R. D. and Searle, M. P., Channel flow, ductile extrusion and exhumation in continental collision zones; an introduction. In Channel Flow, Ductile Extrusion and Exhumation in Continental Collision Zones (eds Law, R. D., Searle, M. P. and Godin, L.), Geol. Soc. London Spec. Publ., 2006, vol. 268, pp. 1–23.
- Hollister, L. S. and Grujic, D., Pulsed channel flow in Bhutan. Geol. Soc. Spec. Publ., 2006, 268, 415–423; doi:10.1144/GSL.SP.2006.268.01.19.
- Gansser, A., Geology of the Bhutan Himalaya, Birkäuser, Basel, 1983, p. 181.
- Uranium Mineralization in Metasediments of North Delhi Fold Belt of Buchara Area, Jaipur District, Rajasthan, India
Authors
1 Atomic Minerals Directorate for Exploration and Research, Hyderabad 500 016, IN
2 Atomic Minerals Directorate for Exploration and Research, Western Region, Jaipur 302 033, IN
Source
Current Science, Vol 114, No 12 (2018), Pagination: 2437-2439Abstract
The Proterozoic Delhi Supergroup rocks of North Delhi Fold Belt (NDFB) is one of the prime targets for base metals, uranium and other economic mineral prospects.References
- Khandelwal, M. K., Jain, R. C., Dash, S. K., Padhi, A. K. and Nanda, L. K., Mem. Geol. Soc. India, 2010, 76, 75–85.
- Yadav, O. P., Hamilton, S., Vimal, R., Saxena, V. P., Pande, A. K. and Gupta, K. R., Explor. Res. At. Miner., 2002, 14, 109–130.
- Padhi, A. K. et al., Explor. Res. At. Miner., 2016, 26, 53–70.
- Sinha-Roy, S., Malhotra, G. and Mohanti, M., Geological Society of India, Geology of Rajasthan, 1998, 1st edn, p. 278.
- Coordinated Bidding Strategy of a Supplier in Day-Ahead and Balancing Energy Market
Authors
1 Department of Electrical Engineering, Indian Institute of Technology, Kanpur–208016, IN
2 Department of Electrical Engineering, Madhav Institute of Technology and Science, Gwalior–474005, IN