R. R. Shinde scite author profile

A Cosmic Muon Veto (CMV) detector using extruded scintillators is being designed around the mini-Iron Calorimeter detector at the transit campus of the India-based Neutrino Observatory, Madurai for measuring its efficiency at shallow depth underground experiments. The scintillation signal is transmitted through a Wavelength Shifting (WLS) fibre and readout by Hamamatsu Silicon-Photomultipliers (SiPMs). A Light Emitting Diode (LED) system is included on the front-end readout for in-situ calibration of the gain of each SiPM. A characterization system was developed for the measurement of gain and choice of the overvoltage (V ov) of SiPMs using the LED as well as a cosmic muon telescope. The V ov is obtained by studying the noise rate, the gain of the SiPM, and the muon detection efficiency. In case of any malfunction of the LED system during the operation, the SiPM can also be calibrated with the noise data as well as using radioactive sources. This paper describes the basic characteristics of the SiPM and the comparison of the calibration results using all three methods, as well as the V ov of the SiPMs and muon selection criteria for the veto detector.

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Development of glass resistive plate chambers for INO experiment

Datar

Jena

Kalmani

et al. 2009

Nuclear Instruments and Methods in Physics Research Section A:

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Development of 2m×2m size glass RPCs for INO

Bhuyan¹,

Datar²,

Kalmani³

et al. 2012

Nuclear Instruments and Methods in Physics Research Section A:

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Magnetic field measurements on the mini-ICAL detector using Hall probes

et al. 2022

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The magnetised 51 kton Iron Calorimeter (ICAL) detector proposed to be built at INO is designed with a focus on detecting 1–20 GeV muons. The magnetic field will enable the measurement of the momentum of the μ - and μ + generated from the charge current interactions of atmospheric νμ and ν̅μ separately within iron in the detector, thus permitting the determination of the neutrino mass ordering/hierarchy, among other important goals of ICAL. Hence it is important to determine the magnetic field as accurately as possible. The mini-ICAL detector is an 85-ton prototype of ICAL, which is operational at Madurai in South India. We describe here the first measurement of the magnetic field in mini-ICAL using Hall sensors. A set-up was developed to calibrate the Hall probe sensors using an electromagnet. The readout system has been designed using an Arduino Nano board for selection of channels of Hall probes mounted on the PCB and the output voltage was measured. The magnetic field has been measured in the small gaps (provided for the purpose) between iron plates in the top layer of mini-ICAL as well as in the air just outside the detector. A precision of better than 3% was obtained, with a sensitivity down to about 3 mT when measuring the small fringe fields outside the detector.

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VME-based data acquisition system for the India-based Neutrino Observatory prototype detector

Bhuyan

Chandratre

Dasgupta

et al. 2012

Nuclear Instruments and Methods in Physics Research Section A:

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R. R. Shinde

Characterization of Silicon-Photomultipliers for a Cosmic Muon Veto detector

Development of glass resistive plate chambers for INO experiment

Development of 2m×2m size glass RPCs for INO

Magnetic field measurements on the mini-ICAL detector using Hall probes

VME-based data acquisition system for the India-based Neutrino Observatory prototype detector

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