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http://dx.doi.org/10.1016/j.net.2022.02.027

Radiation effect on the polymer-based capacitive relative humidity sensors  

Shchemerov, I.V. (National University of Science and Technology "MISiS")
Legotin, S.A. (National University of Science and Technology "MISiS")
Lagov, P.B. (National University of Science and Technology "MISiS")
Pavlov, Y.S. (A.N. Frumkin Institute of Physical Chemistry and Electrochemistry Russian Academy of Sciences)
Tapero, K.I. (National University of Science and Technology "MISiS")
Petrov, A.S. (Research Institute of Scientific Instruments)
Sidelev, A.V. (Research Institute of Scientific Instruments)
Stolbunov, V.S. (Institute of Theoretical and Experimental Physics)
Kulevoy, T.V. (Institute of Theoretical and Experimental Physics)
Letovaltseva, M.E. (Russian Technological University MIREA)
Murashev, V.N. (National University of Science and Technology "MISiS")
Konovalov, M.P. (National University of Science and Technology "MISiS")
Kirilov, V.N. (National University of Science and Technology "MISiS")
Publication Information
Nuclear Engineering and Technology / v.54, no.8, 2022 , pp. 2871-2876 More about this Journal
Abstract
The sensitivity of polymer-based capacitive relative humidity (RH) sensors after irradiation with neutrons, electrons and protons was measured. Degradation consists of the decreasing of the upper RH limit that can be measured. At the same time, low RH-level sensitivity is almost stable. After 30 krad of absorption dose, RH cut off is equal to 85% of max value, after 60 krad-40%. Degradation reduces after annealing which indicates high radiation sensitivity of the internal circuit in comparison to RH-sensing polymer film.
Keywords
Relative humidity; Sensor irradiation; Sensitivity degradation under irradiation;
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1 W. Petchmaneelumka, P. Phankamnerd, A. Rerkratn, V. Riewruja, Capacitive sensor readout circuit based on sample and hold method, Energy Rep. 8 (2022) 1012-1018.   DOI
2 Y.S. Pavlov, P.B. Lagov, Magnetic buncher accelerator for radiation hardness research and pulse detector characterization, in: 15th European Conference on Radiation and its Effects on Components and Systems, RADECS), 2015, pp. 1-3.
3 L.A. Aslanov, et al., Nanosilicon stabilized with ligands: effect of high-energy electron beam on luminescent properties, Surf. Interface Anal. (2016) 1-5.
4 I. Mandi, et al., Measurements with silicon detectors at extreme neutron fluences, J. Instrum. 15 (2020) P11018.   DOI
5 A. Floriduz, J.D. Devine, Radiation Testing of Optical and Semiconductor Components for Radiation-Tolerant LED Luminaires. 2018 18th European Conference on Radiation and its Effects on Components and Systems, RADECS), 2018, pp. 1-8.
6 H.J. Kim, et al., Fiber-optic humidity sensor system for the monitoring and detection of coolant leakage in nuclear power plants, Nucl. Eng. Technol. 52 (8) (2020) 1689-1696.   DOI
7 D. Rodriguez, et al., Combined effects of humidity and frequency on the dielectric strength of air for VLF applications, in: 2008 Annual Report Conference on Electrical Insulation and Dielectric Phenomena, Quebec, QC, Canada, 2008, pp. 611-614.
8 LHCb collaboration, LHCb tracker upgrade technical design report, LHCb TDR 15 (21st February 2014).
9 A. Makovec, et al., Radiation hard polyimide-coated FBG optical sensors for relative humidity monitoring in the CMS experiment at CERN, J. Instrum. 9 (2014) C03040.   DOI
10 A. Kapic, et al., Humidity sensors for high energy Physics applications: a review, IEEE Sensor. J. 20 (2020) 10335-10344.   DOI
11 J. Vohlidal, Polymer degradation: a short review, Chem. Teach. Int. 2 (2020), 20200015.
12 A. Uleckas, et al., Investigation of the switching and carrier recombination characteristics in the proton irradiated and thermally annealed Si PIN diodes, Lith. J. Phys. 50 (2) (2010) 225-232.   DOI
13 F.J. Franco, Y. Zong, J. Casas-Cubillos, et al., Neutron effects on short circuit currents of op amps and consequences, IEEE Trans. Nucl. Sci. 52 (5) (2005) 1530-1537.   DOI
14 J.A. Agapito, N.P. Barradas, F.M. Cardeira, et al., Radiation Tests on Commercial Instrumentation Amplifiers, Analog Switches & DAC's. 7th Workshop on Electronics for LHC Experiments, 2001, pp. 117-121.
15 Datasheet HIH-4000 Series Humidity Sensors, Honeywell, 2010. https://sensing.honeywell.com.
16 A. Kapic, et al., Radiation tolerance of capacitive humidity sensor for highenergy Physics applications, IEEE Sens. Lett. 3 (2019) 1-4, 2000604.
17 P. Wu, Z. Xu, C. Meng, et al., The Experiment Study of Effects on ADC Chip against Radiation and Electromagnetic Environment, 12th International Workshop on the Electromagnetic Compatibility of Integrated Circuits, 2019, pp. 207-209.
18 K. Chen, H. Chen, J. Kierstead, et al., Evaluation of commercial ADC radiation tolerance for accelerator experiments, J. Inst. Met. 10 (2015) P08009.
19 P.B. Lagov, et al., Proton-irradiation technology for high-frequency high-current silicon welding diode manufacturing, J. Phys.: Conf. Ser. 830 (2017) 12152.   DOI
20 P.P. D'yachenko, O.A. Elovskii, et al., Stand B" reactor-laser system, At. Energy 88 (2000) 352.   DOI
21 A.L. Buck, New equations for computing vapor pressure and enhancement factor, Am. Meteorol. Soc. 20 (2016) 1527-1532.
22 A.A. Alves Jr., et al., The LHCb detector at the LHC, J. Instrum. 3 (2008) S08005.   DOI
23 A.A. Alves Jr., et al., LHCb detector performance, Int. J. Mod. Phys. 30 (2015), 1530022.   DOI
24 O. Steinkamp, The upstream tracker for the LHCb upgrade, Nucl. Instrum. Methods Phys. Res. 831 (2016) 367-369.   DOI