Abstract
Technologies used to detect mm-wave/Terahertz (THz) radiation range from those that are based on temperature changes, direct/indirect transitions or those that detect through the applied electric field. However, many commercially available detectors have limitations in terms of speed and responsivity and are quite expensive. For these reasons, commercially available indicator lamps which are called glow discharge detectors (GDDs) can be a good alternative since they are low cost and can detect microwave to mm-wave radiation with high sensitivity. These detectors have shown a good response in the mm wave region of the spectrum below ~100GHz, and here we show that their sensitivity even extends far into the THz region. To allow for such a broad frequency sensitivity we studied the detection mechanism behind the glow discharge, and find that it is as a non-local thermal equilibrium plasma whereby it can be simulated using a kinetic approach. The validity of such an approach is shown by obtaining plasma discharge parameters which agree well with experimental observations. The sensitivity of these lamps to frequencies which range from gigahertz to terahertz region allowed us to investigate the possibility of using these lamps in array configurations for low-cost active imaging purposes.
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References
Burroughs G, Bronwell A (1952) High-Sensitivity Gas Tube Detector. Teleteknik II:62–63
Lampert MA, White AD (1953) Microwave techniques for studying discharges in gases. Electr Commun 30:124–128
Udelson BJ (1957) Effect of microwave signals incident upon different regions of a dc hydrogen glow discharge. J Appl Phys 28:380–381
Lobov GD (1960) Gas discharge detector of microwave oscillations. Radiotech Electron 5:152–165
Severin PJW (1965) The interaction of microwaves with the cathode fall and negative glow in a glow discharge. Phillips Research Laboratories, Eindhoven
Farhat NH, Kopeika NS (1972) A low-cost millimeter wave glow-discharge detector. Proceedings of the IEEE 60:759–760
Kopeika NS (1978) Glow discharge detection of long wavelength electromagnetic radiation: cascade ionization process internal signal gain and temporal and spectral response properties. IEEE Trans Plasma Sci 6:139–157
Kopeika NS, Farhat NH (1975) Video detection of millimeter waves with glow discharge tubes: part I - physical description; part II - experimental results. IEEE Trans Electron Devices 22:534–548
Abramovich A, Kopeika NS, Rozban D, Farber E (2007) Inexpensive detector for terahertz imaging. Appl Opt 46(29):7207–7211
Rozban D, Kopeika NS, Abramovich A, Farber E (2008) Terahertz detection mechanism of inexpensive sensitive glow discharge detector. J Appl Phys 103:093306
Avihai Aharon (Akram), Daniel Rozban, Natan S. Kopeika, Amir Abramovich (2013) Heterodyne detection at 300 GHz using neon indicator lamp glow discharge detector. Appl Opt 52:4077–4082
Hou L, Park H, Zhang X-C (Feb, 2011) Terahertz wave imaging system based on glow discharge detector. IEEE J Sel Top Quantum Electronics 17:177–182
Hou L, Shi W (2012) Fast terahertz continuous-wave detector based on weakly-ionized plasma. IEEE Electron Device Lett 33:1583–1585
Alasgarzade N, Takan T, Uzun-Kaymak IU, Sahin AB, Altan H (2015) Modualtion and frequency response of GDDs in the millimeter wav/THz region. Proc SPIE 9510C
Cinar K, Bozaci HM, Altan v H (2013) Characterization of a glow discharge detector with terahertz time domain spectroscopy. IEEE Sensors J 13(7):2643–2647
Kopeika NS (1975) On the mechanism of glow discharge detection of microwave and millimeter-wave radiation. Proc IEEE 63(6):981–982
Nanbu K (2000) Probability theory of electron-molecule, ion-molecule, molecule-molecule, and coulomb collisions for particle modelling of materials processing plasmas and cases. IEEE Trans Plasma Sci 28:971–990
Longo S (2000) Monte carlo models of electron and ion transport in non-equilibrium plasmas. Plasma Sources Sci. Technol. 9:468–476
Kusoglu Sarikaya C, Rafatov, Kudryavtsev AA (2016) Particle in Cell/Monte Carlo Collision analysis of the problem of identification of impurities in the gas by the plasma electron spectroscopy method. Phys Plasmas 23:063524
Kusoglu Sarikaya C, Akbar D, Ribeiro MA, Altan H (2018) Understanding the detection mechanism of mm wave radiation in glow discharge detectors. Proc SPIE 10800:108000E
Farhat NH (1974) Optimization of millimeter-wave glow-discharge detectors. Proc IEEE 62(2):279–281
Hou L, Park H, Zhang X (2009) Broadband detector measures IR, millimeter & THz waves. In: 2009 34th international conference on infrared, millimeter, and terahertz waves, Busan, pp 1–2
Acknowledgments
The work was supported by the Scientific and Technical Research Council of Turkey (TUBITAK) 115F226 and by Fundação para a Ciencia e a Tecnologia (TUBITAK/0002/2014). This research is also sponsored in part by the NATO Science for Peace and Security Program under grant MD.SFPP 984775. The simulations are performed using High Performance and Grid Computing Center (TRUBA Resources) at TUBITAK ULAKBIM.
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Akbar, D., Altan, H., Pavia, J.P., Ribeiro, M.A., Sahin, A.B., Sarikaya, C.K. (2021). Development of Stand-Off Imaging Systems Using Low Cost Plasma Detectors That Work in the GHz to THz Range. In: Pereira, M.F., Apostolakis, A. (eds) Terahertz (THz), Mid Infrared (MIR) and Near Infrared (NIR) Technologies for Protection of Critical Infrastructures Against Explosives and CBRN. NATO Science for Peace and Security Series B: Physics and Biophysics. Springer, Dordrecht. https://doi.org/10.1007/978-94-024-2082-1_19
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DOI: https://doi.org/10.1007/978-94-024-2082-1_19
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