INO

(India-based Neutrino Observatory)

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References

1 - Reviews

[1-1]
Physics Potential of the ICAL detector at the India-based Neutrino Observatory (INO), Shakeel Ahmed et al. (ICAL), Pramana 88 (2017) 79, arXiv:1505.07380.
[ICAL:2015stm]

2 - Detector

[2-1]
Expected Performance of Cosmic Muon Veto Detector, Raj Shah, Gobinda Majumder, arXiv:2403.06114, 2024.
[Shah:2024qxo]
[2-2]
Magnetic field simulations and measurements on the mini-ICAL detector, Honey Khindri, B. Satyanarayana, D. Indumathi, V. M. Datar, R. Shinde, N. Dalal, S. Prabhakar, S. Ajith, JINST 19 (2024) P01027, arXiv:2311.17364.
[Khindri:2023fvf]
[2-3]
Mass testing of SiPMs for the CMVD at IICHEP, Mamta Jangra et al. (Robert Craig Group), SciPost Phys.Proc. 13 (2023) 025, arXiv:2208.11446.
[Jangra:2022uxu]
[2-4]
Magnetic field measurements on the mini-ICAL detector using Hall probes, Honey et al., JINST 17 (2022) T10006, arXiv:2206.15082.
[Khindri:2022elz]
[2-5]
Improving Time and Position Resolution of RPC detectors using Time Over Threshold Information, Jim M John, S. Pethuraj, G. Majumder, K. C. Ravindran, V. M. Datar, B. Satyanarayana, JINST 17 (2022) P04020, arXiv:2201.09279.
[John:2022fuy]
[2-6]
Study of Streamer Development in Resistive Plate Chamber, Jaydeep Datta, Sridhar Tripathy, Nayana Majumdar, Supratik Mukhopadhyay, JINST 15 (2020) C12006, arXiv:2005.13911.
[Datta:2020whg]
[2-7]
Effect of variations in the gas mixture compositions on the timing and charge of glass RPC, A. K. Sikdar, J. Sadiq, P. K. Behera, JINST 15 (2020) C01003, arXiv:1912.04954.
[Sikdar:2019tab]
[2-8]
Numerical studies on timing response and efficiency of RPC, Abhik Jash, Sridhar Tripathy, Nayana Majumdar, Supratik Mukhopadhyay, Subhasis Chattopadhyay, JINST 14 (2019) P06024, arXiv:1812.07031.
[Jash:2018cxf]
[2-9]
Simulation of muon-induced neutral particle background for a shallow depth Iron Calorimeter detector, Neha Panchal, G. Majumder, V.M. Datar, JINST 14 (2019) P02032, arXiv:1809.08834.
[Panchal:2018phs]
[2-10]
Artificial Neural Networks-based Track Fitting of Cosmic Muons through Stacked Resistive Plate Chambers, Deepak Samuel, Karthik Suresh, JINST 13 (2018) P10035, arXiv:1807.04625.
[Samuel:2018xci]
[2-11]
Timing and Charge measurement of single gap Resistive Plate Chamber Detectors for INO-ICAL Experiment, Ankit Gaur, Ashok Kumar, Md. Naimuddin, Nucl.Instrum.Meth. A877 (2018) 246-251, arXiv:1709.08946.
[Gaur:2017osj]
[2-12]
A compact cosmic muon veto detector and possible use with the Iron Calorimeter detector for neutrinos, Neha Panchal et al., JINST 12 (2017) T11002, arXiv:1708.08597.
[Panchal:2017aub]
[2-13]
Angular resolution of stacked resistive plate chambers, Deepak Samuel, Pratibha B Onikeri, Lakshmi P Murgod, JCAP 1701 (2017) 058, arXiv:1609.03071.
[Samuel:2016ocs]
[2-14]
Effect of electrical properties of glass electrodes on the performance of RPC detectors for the INO-ICAL experiment, K. Raveendrababu, P. K. Behera, B. Satyanarayana, JINST 11 (2016) P08024, arXiv:1608.04230.
[Raveendrababu:2016ihx]
[2-15]
Optimisation and Characterisation of Glass RPC for India-based Neutrino Observatory Detectors, R. Kanishka, Vipin Bhatnagar, D. Indumathi, arXiv:1605.09361, 2016.
[Kanishka:2016bdx]
[2-16]
Effect of glass thickness variation on the performance of RPC detectors, Jafar Sadiq, K. Raveendrababu, Prafulla Kumar Behera, JINST 11 (2016) C10003, arXiv:1605.02189.
[Sadiq:2016ofe]
[2-17]
Study of glass properties as electrode for RPC, K. Raveendrababu, P. K. Behera, B. Satyanarayana, Jafar Sadiq, JINST 11 (2016) C07007, arXiv:1605.01044.
[Raveendrababu:2016zuw]
[2-18]
Measurement of Characteristic Impedance of Silicon Fiber Sheet based readout strips panel for RPC detector in INO, M. K. Singh, A. Kumar, N. Marimuthu, V. Singh, V. S. Subrahmanyam, JINST 12 (2017) T01006, arXiv:1603.06334.
[Singh:2016tzf]
[2-19]
Development and characterization of single gap glass RPC, Manisha, V. Bhatnagar, J.S. Shahi, J.B. Singh, Nucl.Instrum.Meth. A840 (2016) 128-132, arXiv:1603.01719.
[Manisha:2016ggf]
[2-20]
Error Propagation of the Track Model and Track Fitting Strategy for the Iron CALorimeter Detector in India-based Neutrino Observatory, Kolahal Bhattacharya, Arnab K. Pal, Gobinda Majumder, Naba K. Mondal, Comput. Phys. Commun. 185 (2014) 3259-3268, arXiv:1510.02792.
[Bhattacharya:2014tha]
[2-21]
Estimation of low energy neutron flux ($E_n\leq15$ MeV) in India-based Neutrino Observatory cavern using Monte Carlo techniques, N. Dokania et al., JINST 10 (2015) T12005, arXiv:1509.06879.
[Dokania:2015lya]
[2-22]
Energy and Direction Estimation of Neutrinos in muonless events at ICAL, Ali Ajmi, S. Uma Sankar, arXiv:1505.07295, 2015.
[AliAjmi:2015qho]
[2-23]
Simulations Study of Muon Response in the Peripheral Regions of the Iron Calorimeter Detector at the India-based Neutrino Observatory, R. Kanishka, Meghna K. K., Vipin Bhatnagar, D. Indumathi, Nita Sinha, JINST 10 (2015) P03011, arXiv:1503.03369.
[Kanishka:2015qsa]
[2-24]
Characterization of 3 mm Glass Electrodes and Development of RPC Detectors for $INO-ICAL$ Experiment, Daljeet Kaur et al., Nucl.Instrum.Meth. A774 (2015) 74-81, arXiv:1412.4998.
[Kaur:2014rfa]
[2-25]
A Study on the time resolution of Glass RPC, N. Dash, V. M. Datar, G. Majumder, arXiv:1410.5532, 2014.
[Dash:2014ifa]
[2-26]
Characterisation of Glass Electrodes and RPC Detectors for $INO-ICAL$ Experiment, Md. Naimuddin et al., JINST 9 (2014) C10039, arXiv:1409.7184.
[Naimuddin:2014qca]
[2-27]
Study of RPC bakelite electrodes and detector performance for INO-ICAL, Ashok Kumar et al., JINST 9 (2014) C10042, arXiv:1409.5522.
[Kumar:2014ffa]
[2-28]
Simulation Studies for Electromagnetic Design of INO ICAL Magnet and its Response to Muons, S. P. Behera, M. S. Bhatia, V. M. Datar, A.K. Mohanty, IEEE Trans.Magnetics 51 (2015) 4624, arXiv:1406.3965.
[Behera:2014zca]
[2-29]
A Simulations Study of the Muon Response of the Iron Calorimeter Detector at the India-based Neutrino Observatory, Animesh Chatterjee et al., JINST 9 (2014) P07001, arXiv:1405.7243.
[Chatterjee:2014vta]
[2-30]
Hadron energy resolution as a function of iron plate thickness at ICAL, Lakshmi S. Mohan et al., JINST 9 (2014) T09003, arXiv:1401.2779.
[Mohan:2014qua]
[2-31]
Hadron energy response of the ICAL detector at INO, Moon Moon Devi et al., JINST 8 (2013) P11003, arXiv:1304.5115.
[Devi:2013wxa]
[2-32]
Development of Glass Resistive Plate Chambers for INO, Satyanarayana Bheesette et al. (INO), arXiv:0810.4693, 2008. ICHEP08.
[Bheesette:2008rb]

3 - Detector - Talks

[3-1]
Characteristic Study and Development of Surface Resistivity Measuring Device for Resistive Plate Chamber Detector, A. Kumar et al., J.Nucl.Mater. 516 (2019) 54-62, arXiv:1806.10194. RPC 2018.
[Kumar:2018upy]
[3-2]
Development and Commissioning of HARDROC based Readout for INO-ICAL Experiment, Ashok Kumar, Ankit Gaur, Aman Phogat, Md. Rafik, Md. Naimuddin, JINST 11 (2016) C10004, arXiv:1605.06235. XIII workshop on Resistive Plate Chambers and related detectors (RPC2016) - Ghent (Belgium).
[Kumar:2016rpg]
[3-3]
Study of Glass and Bakelite Properties as Electrodes in RPC, Manisha, V. Bhatnagar, J.S. Shahi, Sci.Technol. 4 (2016) 21-24, arXiv:1604.04130. 3rd National Conference on Photonics and Materials Science, 2015.
[Manisha:2016aat]

4 - Phenomenology

[4-1]
Probing the interior of Earth using oscillating neutrinos at INO-ICAL, Anil Kumar, Anuj Kumar Upadhyay, Sanjib Kumar Agarwalla, Amol Dighe, PoS EPS-HEP2023 (2024) 198, arXiv:2401.17416. EPS-HEP2023.
[Kumar:2024nyv]
[4-2]
A simulation study of tau neutrino events at the ICAL detector in INO, R. Thiru Senthil, D. Indumathi, Prashant Shukla, Phys.Rev.D 106 (2022) 093004, arXiv:2203.09863.
[Senthil:2022tmj]
[4-3]
Neutrino Oscillation parameter determination at INO-ICAL using track and hit information from GEANT, Jadeep Datta, Bana Singh, S. Uma Sankar, JINST 17 (2022) T08006, arXiv:2111.14184.
[Datta:2021myx]
[4-4]
Validating the Earth's Core using Atmospheric Neutrinos with ICAL at INO, Anil Kumar, Sanjib Kumar Agarwalla, JHEP 08 (2021) 139, arXiv:2104.11740.
[Kumar:2021faw]
[4-5]
First simulation study of trackless events in the INO-ICAL detector to probe the sensitivity to atmospheric neutrinos oscillation parameters, Aleena Chacko, D. Indumathi, James F. Libby, P.K. Behera, Phys.Rev. D102 (2020) 032005, arXiv:1912.07898.
[Chacko:2019wwm]
[4-6]
Study of neutrino oscillation parameters at the INO-ICAL detector using event-by-event reconstruction, Karaparambil Rajan Rebin, Jim Libby, D. Indumathi, Lakshmi S. Mohan, Eur.Phys.J. C79 (2019) 295, arXiv:1804.02138.
[Rebin:2018fdl]
[4-7]
Prospects of Indirect Searches for Dark Matter at INO, Sandhya Choubey, Anushree Ghosh, Deepak Tiwari, JCAP 1805 (2018) 006, arXiv:1711.02546.
[Choubey:2017vpr]
[4-8]
Sensitivity to neutrino decay with atmospheric neutrinos at INO, Sandhya Choubey, Srubabati Goswami, Chandan Gupta, S. M. Lakshmi, Tarak Thakore, Phys.Rev.D 97 (2018) 033005, arXiv:1709.10376.
[Choubey:2017eyg]
[4-9]
Search for the differences in Atmospheric Neutrinos and Antineutrinos oscillation parameters at the INO-ICAL Experiment, Daljeet Kaur, Zubair Ahmad Dar, Sanjeev Kumar, Md. Naimuddin, Phys.Rev. D95 (2017) 093005, arXiv:1703.06710.
[Kaur:2017dpd]
[4-10]
Search for the sterile neutrino mixing with the ICAL detector at INO, S. P. Behera et al., Eur.Phys.J. C77 (2017) 307, arXiv:1605.08607.
[Behera:2016kwr]
[4-11]
Simulations study of neutrino oscillation parameters with the Iron Calorimeter Detector (ICAL): an improved analysis, Lakshmi S. Mohan, D. Indumathi, Eur.Phys.J. C77 (2017) 54, arXiv:1605.04185.
[Mohan:2016gxm]
[4-12]
Improving the hierarchy sensitivity of ICAL using neural network, Ali Ajmi, Abhish Dev, Mohammad Nizam, Nitish Nayak, S. Uma Sankar, J.Phys.Conf.Ser. 888 (2017) 012151, arXiv:1510.02350.
[AliAjmi:2015rns]
[4-13]
Search for Magnetic Monopole using ICAL at INO, N. Dash, V. M. Datar, G. Majumder, Astropart. Phys. 70 (2015) 33-38, arXiv:1406.3938.
[Dash:2014fba]
[4-14]
Enhancing sensitivity to neutrino parameters at INO combining muon and hadron information, Moon Moon Devi, Tarak Thakore, Sanjib Kumar Agarwalla, Amol Dighe, JHEP 1410 (2014) 189, arXiv:1406.3689.
[Devi:2014yaa]
[4-15]
Comments on the reach of INO experiment: JHEP 1304, 009 (2013) and arXiv:1303.2534 [hep-ph], Abhijit Samanta, arXiv:1305.2819, 2013.
[Samanta:2013ada]
[4-16]
Determining the Neutrino Mass Hierarchy with INO, T2K, NOvA and Reactor Experiments, Anushree Ghosh, Tarak Thakore, Sandhya Choubey, JHEP 1304 (2013) 009, arXiv:1212.1305.
[Ghosh:2012px]
[4-17]
Atmospheric neutrino flux at INO, South Pole and Pyhasalmi, M. Sajjad Athar, M. Honda, T. Kajita, K. Kasahara, S. Midorikawa, Phys. Lett. B718 (2013) 1375-1380, arXiv:1210.5154.
[SajjadAthar:2012dji]
[4-18]
Identifying the Neutrino mass Ordering with INO and NOvA, Mattias Blennow, Thomas Schwetz, JHEP 08 (2012) 058, arXiv:1203.3388.
[Blennow:2012gj]
[4-19]
Unraveling neutrino parameters with a magical beta-beam experiment at INO, Sanjib Kumar Agarwalla, Sandhya Choubey, Amitava Raychaudhuri, Nucl. Phys. B798 (2008) 124-145, arXiv:0711.1459.
[Agarwalla:2007ai]
[4-20]
A GEANT-based study of atmospheric neutrino oscillation parameters at INO, Abhijit Samanta et al., Int. J. Mod. Phys. A23 (2008) 233-245, arXiv:hep-ph/0702180.
[Samanta:2007ue]
[4-21]
The mass hierarchy with atmospheric neutrinos at INO, Abhijit Samanta, Phys. Lett. B673 (2009) 37-46, arXiv:hep-ph/0610196.
[Samanta:2006sj]

5 - Phenomenology - Talks

[5-1]
Analysis of Ultra High Energy Muons at the INO-ICAL Using Pair-Meter Technique, Jaydip Singh, Srishti Nagu, Jyotsna Singh, Springer Proc.Phys. 201 (2018) 137-145, arXiv:1709.07445. Advanced Detectors for Nuclear, High Energy and Astroparticle Physics - Bose Institute Kolkata, India.
[Singh:2017gwg]
[5-2]
CERN-INO magical Beta-beam experiment: A high precision probe for neutrino parameters, Sanjib Kumar Agarwalla, Sandhya Choubey, Amitava Raychaudhuri, PoS NUFACT08 (2008) 034, arXiv:0811.1822. 10th International Workshop on Neutrino Factories, Super beams and Beta beams (NUFACT08), June 30 - July 5 2008, Valencia, Spain.
[Agarwalla:2008yk]
[5-3]
Probing deviation of tribimaximal mixing and reach of $\theta_{13}$ using neutrino factory at CERN and ICAL detector at INO, Debasish Majumdar, Ambar Ghosal, Sudeb Bhattacharya, Kamales Kar, AIP Conf. Proc. 981 (2008) 184-186, arXiv:0710.3281. NUFACT07.
[Majumdar:2007qg]
[5-4]
Measuring the deviation from maximal mixing of atmospheric muon neutrinos at INO, Probir Roy, AIP Conf. Proc. 842 (2006) 883-885, arXiv:hep-ph/0601011. PANIC 05, Santa Fe, Oct. 24 - 28, 2005.
[Roy:2006dw]

6 - Talks

[6-1]
India-based Neutrino Observatory, G.Rajasekaran, Aip Conf. Proc. 721 (2004) 243, arXiv:hep-ph/0402246. NuFact 03, 5th International Workshop on Neutrino Factories and Superbeams, 5-11, June 2003, Columbia University, New York.
[Rajasekaran:2004wi]

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Last Update: Thu 18 Apr 2024, 14:48:47 CET