|
India | |
|
| Magna, T., Viladkar, S., Rapprich, V., Pour, O., Hopp, J., & ÄejkovĆ”, B. (2020). NbāV-enriched sƶvites of the northeastern and eastern part of the Amba Dongar carbonatite ring dike, IndiaāA reflection of post-emplacement hydrothermal overprint?. Geochemistry, 80(1), 125534.
Chandra, J., Paul, D., Viladkar, S. G., & Sensarma, S. (2018). Origin of the Amba Dongar carbonatite complex, India and its possible linkage with the Deccan Large Igneous Province. Geological Society, London, Special Publications, 463(1), 137-169.
Viladkar, S. G. (2015). Mineralogy and geochemistry of fenitized nephelinites of the Amba Dongar complex, Gujarat. Journal of the Geological Society of India, 85(1), 87-97.
Srivastava, R. K. (1994). Petrology, petrochemistry and genesis of the alkaline rocks associated with the Ambadungar Carbonatite Complex, Baroda district, Gujarat, India. JOURNAL-GEOLOGICAL SOCIETY OF INDIA, 43, 23-23.
Rock, N. M. S., Gwalani, L. G., & Griffin, B. J. (1994). Alkaline rocks and carbonatites of Amba Dongar and adjacent areas, Deccan Alkaline Province, Gujarat, India. 2. Complexly zoned clinopyroxene phenocrysts. Mineralogy and Petrology, 51(2-4), 113-135.
Viladkar, S. G., & Wimmenauer, W. (1992). Geochemical and petrological studies on the Amba Dongar carbonatites (Gujarat, India). Chem. Erde, 52, 277-291.
Notholt, A. J. G., Highley, D. E., & Deans, T. (1990). Economic minerals in carbonatites and associated alkaline igneous rocks. Institution of Mining and Metallurgy Transactions. Section B. Applied Earth Science, 99.
Viladkar, S. G. (1984). Alkaline rocks associated with the carbonatites of Amba Dongar, Chhota Udaipur, Gujarat, India. Indian Mineral, 130-135.
Viladkar, S. G. (1981). The carbonatites of Amba Dongar, Gujarat, India. Bull. Geol. Soc. Finland, 53, 17-28.
Deans, T., Sukheswala, R. N., Sethna, S. F., & Viladkar, S. G. (1973). Discussion and contributions: Metasomatic feldspar rocks (potash fenites) associated with the fluorite deposits and carbonatites of Amba Dongar, Gujarat, India. Inst. Mining Metall. Trans, 82, 33-40. |
|
| Samal, Amiya K., Rajesh K. Srivastava, and Dewashish Upadhyay. (2021) "Major, Trace, and Rare-Earth Element Geochemistry of Nb-V Rich Andradite-Schorlomite-Morimotoite Garnet from Ambadungar-Saidivasan Alkaline Carbonatite Complex, India: Implication for the Role of Hydrothermal Fluid-Induced Metasomatism" Minerals 11, no. 7: 756. https://doi.org/10.3390/min11070756 |
|
| Viladkar, S. G., & Gittins, J. (2016). Trace elements and REE geochemistry of Siriwasan carbonatite, Chhota Udaipur, Gujarat. Journal of the Geological Society of India, 87(6), 709-715. |
|
| Karkare, S.G., Kumar, S. & Srivastava, R.K. 1991. Evolution of the island chain of Kutch and role of rift magmatism and autonomous activization. Journal of Scientific Research, Banares Hindu University, 41B, 163-175. |
|
| Kshirsagar, P. V., Sheth, H. C., & Shaikh, B. (2011). Mafic alkalic magmatism in central Kachchh, India: a monogenetic volcanic field in the northwestern Deccan Traps. Bulletin of Volcanology, 73(5), 595-612.
Guha, D., Das, S., Srikarni, C., & Chakraborty, S. K. (2005). Alkali basalt of Kachchh: its implication in the tectonic framework of Mesozoic of western India. JOURNAL-GEOLOGICAL SOCIETY OF INDIA, 66(5), 599.
Karmalkar, N. R., Rege, S., Griffin, W. L., & O'Reilly, S. Y. (2005). Alkaline magmatism from Kutch, NW India: implications for plumeālithosphere interaction. Lithos, 81(1-4), 101-119.
Le Maitre, R. W. - Ed. (2002) Igneous Rocks - A Classification and Glossary of Terms (2nd ed.) Cambridge University Press. doi:10.1017/cbo9780511535581
Krishnamurthy, P., Pande, K., Gopalan, K., & Macdougall, J. D. (1999). Mineralogical and chemical studies on alkaline basaltic rocks of Kutch, Gujarat, India. Memoirs-Geological Society of India, (2), 757-784.
Krishnamurthy, P., Pande, K., Gopalan, K., & Macdougall, J. D. (1988). Upper mantle xenoliths in alkali basalts related to Deccan Trap volcanism. Deccan Flood Basalts, 10, 53-67. |
|
| Dessai, A. G., & Viegas, A. (2010). Petrogenesis of alkaline rocks from Murud-Janjira, in the Deccan Traps, western India. Mineralogy and Petrology, 98(1-4), 297-311.
Dessai, A. G., & Viegas, A. (2010). Petrogenesis of alkaline rocks from Murud-Janjira, in the Deccan Traps, western India. Mineralogy and Petrology, 98(1-4), 297-311.
Melluso, L., Sethna, S. F., dāAntonio, M., Javeri, P., & Bennio, L. (2002). Geochemistry and petrogenesis of sodic and potassic mafic alkaline rocks in the Deccan Volcanic Province, Mumbai area (India). Mineralogy and Petrology, 74(2-4), 323-342.
Melluso, L., Sethna, S. F., dāAntonio, M., Javeri, P., & Bennio, L. (2002). Geochemistry and petrogenesis of sodic and potassic mafic alkaline rocks in the Deccan Volcanic Province, Mumbai area (India). Mineralogy and Petrology, 74(2-4), 323-342.
Sethna, S. F., & DāSa, C. P. (1991). Occurrence of ijolite with veinlets of carbonatite in the Deccan Trap at Murud-Janjira, Maharashtra, India. Journal of the Geological Society of India, 37, 257-263.
Sethna, S. F., & DāSa, C. P. (1991). Occurrence of ijolite with veinlets of carbonatite in the Deccan Trap at Murud-Janjira, Maharashtra, India. Journal of the Geological Society of India, 37, 257-263.
Dessai, A. G., Rock, N., Griffin, B. J., & Gupta, D. (1990). Mineralogy and petrology of some xenolith-bearing alkaline dykes associated with Deccan magmatism, south of Bombay, India. European Journal of Mineralogy, 667-686.
Dessai, A. G., Rock, N., Griffin, B. J., & Gupta, D. (1990). Mineralogy and petrology of some xenolith-bearing alkaline dykes associated with Deccan magmatism, south of Bombay, India. European Journal of Mineralogy, 667-686. |
|
| Patel, Ashim Kumar, Upadhyay, Dewashish, Mishra, Biswajit, Pruseth, Kamal Lochan (2023) Reconstruction of hydrothermal fluid composition of the Kamthai carbonatite complex, India using lattice strain model: Implications for LREE/HREE fractionation. Lithos, 444. 107097 doi:10.1016/j.lithos.2023.107097 |
