Research Article
HARİCİ UYGULANAN MANYETİK ALANIN MİLİMETRE DALGA/TERAHERTZ DEDEKTÖRÜ OLARAK KULLANILAN PARILTILI DEŞARJ LAMBALARINDAKİ PLAZMA IŞIMA OPTİK SPEKTRUMUNA OLAN ETKİSİNİN DENEYSEL GÖSTERİMİ
Abstract
Bu çalışmada, Parıltılı deşarj lambaları (GDD) içindeki plazma bölgesinde meydana gelen optik
ışımada meydana gelen, milimetre dalga radyasyon ve harici elektromanyetik alana bağlı değişimler
gözlemlenmiş ve ölçülmüştür. Milimetre dalganın (MD) tek başına uygulandığı zaman optik ışımada
görülen etkinin göreceli olarak %3 civarı olduğu görülmektedir. Elektromanyetik alanın (EM) etkisi ile
ışınımda %5’lik bir artış oluşmaktadır. 600 Gauss şiddetinde bir manyetik alanın uygulanması, plazma
bölgesi optik ışımasının milimetre dalga radyasyona karşı hassasiyetini 0.4 dB kadar arttırmıştır. Daha
yüksek manyetik alan değerlerinin denenmesi planlanmıştır.
Keywords
References
- Abramovich A., Kopeika N. S., Rozban D., 2009, "THz polarization effects on detection responsivity of glow discharge detectors (GDDs)," IEEE Sensors Journal, Cilt 9, ss. 1181-1184.
- Bellan P. M., 2008, Fundamentals of plasma physics: Cambridge University Press.
- Çınar K., Altan H., Şahin A. B., 2013, "THz transmission and detection through glow discharge detectors," in SPIE Defense, Security, and Sensing, ss. 87160J-87160J-9.
- Haddad J., Bousquet B., Canioni L., Mounaix P., 2013, "Review in terahertz spectral analysis," TrAC Trends in Analytical Chemistry, Cilt 44, ss. 98-105.
- Hafez H., Chai X., Ibrahim A., Mondal S., Férachou D., Ropagnol X., Ozaki T., 2016, "Intense terahertz radiation and their applications," Journal of Optics, Cilt 18, p. 093004.
- Ilin K.S, Lindgren M., Currie M., Semenov A. D., Goltsman G. N., Sobolewski R., 2000, “Picosecond hot-electron energy relaxation in NbN superconducting photodetectors,”Appl. Phys. Lett. 76, p. 2752–2754.
- Lewis R. A., 2014, "A review of terahertz sources," Journal of Physics D: Applied Physics, Cilt. 47, p. 374001.
- Rozban D., Kopeika N. S., Abramovich A., Farber E., 2008, "Terahertz detection mechanism of inexpensive sensitive glow discharge detectors," Journal of Applied Physics, Cilt 103, p. 093306.
- Semerci T., Demirhan Y., Miyakawa N., Wang H. B., Ozyuzer L., 2016, “Thin film like terahertz bolometric detector on Bi2212 single crystal,” Opt. Quantum. Electron. 48, p. 3401–3411.
- Sizov F., 2010, "THz radiation sensors," Opto-electronics review, Cilt 18, pp. 10-36.
- Sizov F., Rogalski A., 2010,"THz detectors," Progress in Quantum Electronics, Cilt 34, ss. 278-347.
- Tonouchi M., 2007, “Cutting-edge terahertz technology,” Nat. Photonics 1,p. 97-105.
- Yuan C.-X., Zhou Z., Yue F., 2012, "Terahertz waves propagation in a bounded plasma slab with high plasma density and high collision frequency," in Intelligent Computation Technology and Automation (ICICTA), 2012 Fifth International Conference on, pp. 608-613.
Experimental Demonstration of the Effect of the Externally Applied Magnetic Field on the Plasma Optical Radiation Spectrum of the Glow Discharge Lamps which are used as milimeter wave/Terahertz dedectors
Abstract
In this study, the optical emission from a Glow Discharge Device (GDD) lamp plasma that
is affected by both magnetic and milimeter wave electric field is observed and recorded. Milimeter wave
radiation has increased the optical emission by %3. Electromagnetic field has also increased the emission
by %5. A magnetic field of 600 Gauss has increased the optical emission sensitivity to milimeter wave by
0.4 dB. In the future, higher magnetic field values will be studied.
Keywords
References
- Abramovich A., Kopeika N. S., Rozban D., 2009, "THz polarization effects on detection responsivity of glow discharge detectors (GDDs)," IEEE Sensors Journal, Cilt 9, ss. 1181-1184.
- Bellan P. M., 2008, Fundamentals of plasma physics: Cambridge University Press.
- Çınar K., Altan H., Şahin A. B., 2013, "THz transmission and detection through glow discharge detectors," in SPIE Defense, Security, and Sensing, ss. 87160J-87160J-9.
- Haddad J., Bousquet B., Canioni L., Mounaix P., 2013, "Review in terahertz spectral analysis," TrAC Trends in Analytical Chemistry, Cilt 44, ss. 98-105.
- Hafez H., Chai X., Ibrahim A., Mondal S., Férachou D., Ropagnol X., Ozaki T., 2016, "Intense terahertz radiation and their applications," Journal of Optics, Cilt 18, p. 093004.
- Ilin K.S, Lindgren M., Currie M., Semenov A. D., Goltsman G. N., Sobolewski R., 2000, “Picosecond hot-electron energy relaxation in NbN superconducting photodetectors,”Appl. Phys. Lett. 76, p. 2752–2754.
- Lewis R. A., 2014, "A review of terahertz sources," Journal of Physics D: Applied Physics, Cilt. 47, p. 374001.
- Rozban D., Kopeika N. S., Abramovich A., Farber E., 2008, "Terahertz detection mechanism of inexpensive sensitive glow discharge detectors," Journal of Applied Physics, Cilt 103, p. 093306.
- Semerci T., Demirhan Y., Miyakawa N., Wang H. B., Ozyuzer L., 2016, “Thin film like terahertz bolometric detector on Bi2212 single crystal,” Opt. Quantum. Electron. 48, p. 3401–3411.
- Sizov F., 2010, "THz radiation sensors," Opto-electronics review, Cilt 18, pp. 10-36.
- Sizov F., Rogalski A., 2010,"THz detectors," Progress in Quantum Electronics, Cilt 34, ss. 278-347.
- Tonouchi M., 2007, “Cutting-edge terahertz technology,” Nat. Photonics 1,p. 97-105.
- Yuan C.-X., Zhou Z., Yue F., 2012, "Terahertz waves propagation in a bounded plasma slab with high plasma density and high collision frequency," in Intelligent Computation Technology and Automation (ICICTA), 2012 Fifth International Conference on, pp. 608-613.
There are 13 citations in total.
Details
| Primary Language | Turkish |
|---|---|
| Subjects | Engineering |
| Journal Section | Research Article |
| Authors | |
| Publication Date | June 3, 2020 |
| Submission Date | May 31, 2019 |
| Acceptance Date | August 20, 2019 |
| Published in Issue | Year 2020 Volume: 8 Issue: 2 |
