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INTER-UNIVERSITY ACCELERATOR CENTRE, NEW DELHI (IUACD) RADIOCARBON DATE LIST II
Published online by Cambridge University Press: 19 November 2021
Abstract
Accelerator mass spectrometry (AMS) activities at the Inter-University Accelerator Centre (IUAC) in New Delhi, India, started with its 15UD Pelletron accelerator and cosmogenic radionuclide (CRN) measurements of 10Be and 26Al. Realizing the demand of a radiocarbon (14C) AMS facility in India, a 500kV Pelletron accelerator based AMS system was installed in 2015. This facility was designated with the lab code IUACD for 14C measurements. 14C dates measured in 2015 and 2016 were published in the first radiocarbon date list (see text for details). The present list is the second 14C date list and consists of dates measured from January to December 2017.
Keywords
- Type
- Date List
- Information
- Copyright
- © The Author(s), 2021. Published by Cambridge University Press for the Arizona Board of Regents on behalf of the University of Arizona
References
REFERENCES
Amir, M, Paul, D, Malik, JN. 2021. Geochemistry of Holocene sediments from Chilika Lagoon, India: inferences on the sources of organic matter and variability of the Indian summer Monsoon. Quaternary International 599–600:148–157. doi: 10.1016/j.quaint.2020.08.050.CrossRefGoogle Scholar
Bharath, S, Arya Krishnan, K, D’Souza, RS, Rashmi Nayak, S, Ravi, PM, Sharma, R, Kumar, P, Chopra, S, Karunakara, N. 2021. Optimization of CO2 absorption and liquid scintillation counting method for carbon-14 specific activity measurement in atmospheric air. Applied Radiation and Isotopes 172:109685.CrossRefGoogle Scholar
Chaudhri, AR, Chopra, S, Kumar, P, Ranga, R, Singh, Y, Rajput, S, Sharma, V, Verma, VK, Sharma, R. 2021. Saraswati River in northern India (Haryana) and its role in populating the Harappan civilization sites—a study based on remote sensing, sedimentology, and strata chronology. Archaeological Prospection: 1–18. doi: 10.1002/arp.1829.CrossRefGoogle Scholar
Das, C, Dhal, S P, Kumar, P, Pati, P, Chopra, S. 2021. Climate-induced denudational changes during the Little Ice Age inferred from 10Be (meteoric)/9Be ratio: a case study from the core monsoon zone of India. Quaternary International 599–600:107–116. doi: 10.1016/j.quaint.2020.10.041.CrossRefGoogle Scholar
Das, S, Kumar, P, Rajni, MB, Chopra, S. 2019. Radiocarbon dating of historical bricks: exploring the unprotected archaeological mounds in the environs of excavated site of Nalanda. PINSA 85(3):619–628.Google Scholar
Kavil, SP, Ramya Bala, P, Kumar, P, Ghosh, D, Sukumar, R. 2021 in press. Climate change and the migration of a pastoralist people c.3500 cal. years BP inferred from palaeofire and lipid biomarker records in the montane Western Ghats, India. Environmental Archaeology. doi: 10.1080/14614103.2021.1959188.CrossRefGoogle Scholar
Kumar Das, S, Gangopadhyay, K, Ghosh, A, Biswas, O, Bera, S, Ghosh, P, Paruya, DK, Naskar, N, Mani, D, MS, K, Yoshida, K. 2021. Organic geochemical and palaeobotanical reconstruction of a late-Holocene archaeological settlement in coastal eastern India. The Holocene 31(10):1511–1524. doi: 10.1177/09596836211025970
CrossRefGoogle Scholar
Kumar, P, Chopra, S, Pattanaik, JK, Ojha, S, Gargari, S, Joshi, R, Kanjilal, D. 2015. A new AMS facility at Inter University Accelerator Centre, New Delhi. Nuclear Instruments and Methods in Physics Research B 361:115–119.CrossRefGoogle Scholar
Kumar, O, Ramanathan, AL, Bakke, J, Kotlia, BS, Shrivastava, JP. 2020. Disentangling source of moisture driving glacier dynamics and identification of 8.2 ka event: evidence from pore water isotopes, Western Himalaya. Sci. Rep. 10(15):324.CrossRefGoogle ScholarPubMed
Kumar, O, Ramanathan, AL, Bakke, J, Kotlia, BS, Shrivastava, JP, Kumar, P, Sharma, R, Kumar, P. 2021. Role of Indian Summer Monsoon and Westerlies on glacier variability in the Himalaya and East Africa during Late Quaternary: review and new data. Earth Science Reviews 212:103431.CrossRefGoogle Scholar
Kumar, P, Pattanaik, J K, Ojha, S, Gargari, S, Joshi, R, Roonwal, GS, Balakrishnan, S, Chopra, S, Kanjilal, D. 2011.
10Be measurements at IUAC-AMS facility. J. Radioanal. Nucl. Chem. 290:179–182.CrossRefGoogle Scholar
Lone, AM, Achyuthan, H, Shah, RA, Sangode, SJ, Kumar, P, Chopra, S, Sharma, R. 2020. Paleoenvironmental shifts spanning the last ∼6000 years and recent anthropogenic controls inferred from a high-altitude temperate lake: Anchar Lake, NW Himalaya. The Holocene 30(1):23–36.CrossRefGoogle Scholar
Meenakshi, Kumar P, Shrivastava, JP, Chandra, R, Chopra, S, Roonwal, GS, Sharma, R. 2018. High resolution 14C AMS ages (∼50 ka) of organic matter associated with the loess-palaeosol Holocene-Late Pleistocene (8–130 ka) sediments of Dilpur Formation, Karewa Group, Kashmir, India. Quaternary Geochronology 47:170–179.CrossRefGoogle Scholar
Naskar, N, Chaudhuri, P, Gangopadhyay, K, Ghosh, A, Lahiri, S, Sharma, R, Kumar, P, Ojha, S, Chopra, S. 2018. New dates from the site of Erenda, East Medinipur District, West Bengal: implications for Indian protohistory. Proceedings of the Fourth International Conference on Application of Radiotracers and Energetic Beams in Sciences 50:115–116.Google Scholar
Nemec, M, Wacker, L, Hajdas, I, Gäggeler, H. 2010. Alternative methods for cellulose preparation for AMS measurement. Radiocarbon 52:1358–1370.CrossRefGoogle Scholar
Neelavannan, K, Hussain, SM, Nishath, NM, Achyuthan, H, Veerasingam, S, Prakasam, M, Kumar, P, Singh, P, Kurian, PJ. 2021. Paleoproductivity shifts since the last 130 ka off Lakshadweep, southeastern Arabian Sea. Regional Studies in Marine Science 44:101776.CrossRefGoogle Scholar
Saini, R, Sharma, MC, Deswal, S, Barr, ID, Kumar, P, Kumar, P, Chopra, S. 2019. Glacio-archeological evidence of permanent settlements within a glacier end moraine complex during 980–1840 CE: the Miyar Basin, Lahaul Himalaya, India. Anthropocene 26:100197.CrossRefGoogle Scholar
Shah, RA, Achyuthan, H, Lone, AM, Kumar, S, Kumar, P, Sharma, R, Amir, M, Singh, AK, Dash, C. 2020. Holocene palaeoenvironmental records from the high-altitude Wular Lake, Western Himalayas. The Holocene 30(5):733–743.CrossRefGoogle Scholar
Shah, RA, Achyuthan, H, Lone, A, Kumar, P, Ali, A, Rahman, A. 2021. Palaeoenvironment shifts during last ∼500 years and eutrophic evolution of the Wular Lake, Kashmir Valley, India. Limnology 22:111–120.CrossRefGoogle Scholar
Shamurailatpam, MS, Kumar, O, Ramanathan, AL. 2021. Testing the reliableproxies to understand the mid-Holocene climate variability records from Chandratal lake, Western Himalayas. Quaternary International 599–600:55–61. doi: 10.1016/j.quaint.2020.11.003.CrossRefGoogle Scholar
Sharma, R, Kumar, P, Ojha, S, Gargari, S, Chopra, S. 2020. Inter-University Accelerator Centre, New Delhi (IUACD) Radiocarbon Date List I. Radiocarbon 62(5):E1–E13. doi: 10.1017/RDC.2020.44.CrossRefGoogle Scholar
Sharma, R, Umapathy, GR, Kumar, P, Ojha, S, Gargari, S, Joshi, R, Chopra, S, Kanjilal, D. 2019. AMS and upcoming geochronology facility at Inter University Accelerator Centre (IUAC), New Delhi, India. Nuclear Instruments and Methods in Physics Research B 438:124–130.CrossRefGoogle Scholar
Singh, DS, Dubey, CA, Kumar, D, Kumar, P, Ravindra, R. 2018. Climate events between 47.5 and 1 ka BP in glaciated terrain of the Ny-Alesund region, Arctic, using geomorphology and sedimentology of diversified morphological zones. Polar Science 18:123–134.CrossRefGoogle Scholar
Singh, DS, Dubey, CA, Kumar, D, Vishawakarma, B, Singh, AK, Tripathi, A, Gautam, PK, Bali, R, Agarwal, KK, Sharma, R. 2019. Monsoon variability and major climatic events between 25 and 0.05 ka BP using sedimentary parameters in the Gangotri Glacier region, Garhwal Himalaya, India. Quaternary International 507:148–155.CrossRefGoogle Scholar
Stuiver, M, Polach, HA. 1977. Discussion: reporting of 14C data. Radiocarbon 19(2):355–363.CrossRefGoogle Scholar