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http://hdl.handle.net/11452/34105
Başlık: | Time resolved Fabry-Perot measurements of cavity temperature in pulsed QCLs |
Yazarlar: | Gündoğdu, Sinan Pisheh, Hadi Sedaghat Demir, Abdullah Günöven, Mete Sirtori, Carlo Uludağ Üniversitesi/Mühendislik Fakültesi/Elektrik-Elektronik Mühendisliği Bölümü. 0000-0001-5952-5993 Aydınlı, Atilla ABI-7535-2020 7005432613 |
Anahtar kelimeler: | Optics Quantum-cascade lasers Thermal impedance Spectroscopy Emission spectroscopy Fabry-perot interferometers Quantum cascade lasers Refractive index Semiconductor lasers Spectral density Temperature measurement Thermal conductivity Emission wavelength Kapitza resistance Pulsed-mode operation Refractive index changes Temperature variation Time resolved temperature Time-dependent temperature Time-resolved emission spectra Pulsed lasers |
Yayın Tarihi: | 21-Şub-2018 |
Yayıncı: | Optica Publishing Group |
Atıf: | Gündoğdu, S. vd. (2018). ''Time resolved Fabry-Perot measurements of cavity temperature in pulsed QCLs''. Optics Express, 26(6), 6572-6580. |
Özet: | Temperature rise during operation is a central concern of semiconductor lasers and especially difficult to measure during a pulsed operation. We present a technique for in situ time-resolved temperature measurement of quantum cascade lasers operating in a pulsed mode at similar to 9.25 mu m emission wavelength. Using a step-scan approach with 5 ns resolution, we measure the temporal evolution of the spectral density, observing longitudinal Fabry-Perot modes that correspond to different transverse modes. Considering the multiple thin layers that make up the active layer and the associated Kapitza resistance, thermal properties of QCLs are significantly different than bulk-like laser diodes where this approach was successfully used. Compounded by the lattice expansion and refractive index changes due to time-dependent temperature rise, Fabry-Perot modes were observed and analyzed from the time-resolved emission spectra of quantum cascade lasers to deduce the cavity temperature. Temperature rise of a QCL in a pulsed mode operation between -160 degrees C to -80 degrees C was measured as a function of time. Using the temporal temperature variations, a thermal model was constructed that led to the extraction of cavity thermal conductivity in agreement with previous results. Critical in maximizing pulsed output power, the effect of the duty cycle on the evolution of laser heating was studied in situ, leading to a heat map to guide the operation of pulsed lasers. |
URI: | https://doi.org/10.1364/OE.26.006572 https://opg.optica.org/oe/fulltext.cfm?uri=oe-26-6-6572&id=383124 http://hdl.handle.net/11452/34105 |
ISSN: | 1094-4087 |
Koleksiyonlarda Görünür: | Scopus Web of Science |
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Aydınlı_vd_2018.pdf | 2.54 MB | Adobe PDF | Göster/Aç |
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