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Linewidth measurement of free-running, pulsed, distributed feedback quantum cascade lasers
In gas spectroscopy with distributed feedback quantum cascade lasers (DFB-QCLs), linewidth is an important measurement parameter. However, in standard usage, these lasers are used in pulsed operation, so that the laser linewidth can no longer be assumed to remain constant over the length of the puls...
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| Published in: | Journal of applied physics 2004-05, Vol.95 (9), p.4551-4554 |
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| Main Authors: | , , , |
| Format: | Article |
| Language: | English |
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| cited_by | cdi_FETCH-LOGICAL-c227t-c96003c19b67cd9fe9f6cd7504c218b5ecbeacb850088253202adae648f251703 |
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| cites | cdi_FETCH-LOGICAL-c227t-c96003c19b67cd9fe9f6cd7504c218b5ecbeacb850088253202adae648f251703 |
| container_end_page | 4554 |
| container_issue | 9 |
| container_start_page | 4551 |
| container_title | Journal of applied physics |
| container_volume | 95 |
| creator | Beyer, Thomas Braun, Marcus Hartwig, Susanne Lambrecht, Armin |
| description | In gas spectroscopy with distributed feedback quantum cascade lasers (DFB-QCLs), linewidth is an important measurement parameter. However, in standard usage, these lasers are used in pulsed operation, so that the laser linewidth can no longer be assumed to remain constant over the length of the pulse. For the instantaneous measurement of such dynamic linewidths, a suitable measurement technique was still lacking. Frequently, pulse lengths of 5 to 10 ns are used to obtain laser linewidths that will be suitable for gas measurements. In these experiments, standard photoconductive or photovoltaic mid-infrared detectors with bandwidths in the 1 MHz range are employed, so that the linewidth is averaged over the tuning range of the QCL. The linewidth averaging could be reduced by shorter pulses, but for pulses shorter than 5 ns, the Fourier limitation increases the linewidth again. We present a technique to measure the dynamic laser linewidth continuously within a laser pulse of 30 ns to several μs. Due to the use of high-bandwidth detectors working from 2 to 12 μm, laser linewidths can be determined much more accurately than with short pulses. Instantaneous linewidths of DFB-QCLs down to 60 MHz are obtained. This shows that QCLs are well suited for gas measurement in the mid-infrared. |
| doi_str_mv | 10.1063/1.1689750 |
| format | article |
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However, in standard usage, these lasers are used in pulsed operation, so that the laser linewidth can no longer be assumed to remain constant over the length of the pulse. For the instantaneous measurement of such dynamic linewidths, a suitable measurement technique was still lacking. Frequently, pulse lengths of 5 to 10 ns are used to obtain laser linewidths that will be suitable for gas measurements. In these experiments, standard photoconductive or photovoltaic mid-infrared detectors with bandwidths in the 1 MHz range are employed, so that the linewidth is averaged over the tuning range of the QCL. The linewidth averaging could be reduced by shorter pulses, but for pulses shorter than 5 ns, the Fourier limitation increases the linewidth again. We present a technique to measure the dynamic laser linewidth continuously within a laser pulse of 30 ns to several μs. Due to the use of high-bandwidth detectors working from 2 to 12 μm, laser linewidths can be determined much more accurately than with short pulses. Instantaneous linewidths of DFB-QCLs down to 60 MHz are obtained. 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However, in standard usage, these lasers are used in pulsed operation, so that the laser linewidth can no longer be assumed to remain constant over the length of the pulse. For the instantaneous measurement of such dynamic linewidths, a suitable measurement technique was still lacking. Frequently, pulse lengths of 5 to 10 ns are used to obtain laser linewidths that will be suitable for gas measurements. In these experiments, standard photoconductive or photovoltaic mid-infrared detectors with bandwidths in the 1 MHz range are employed, so that the linewidth is averaged over the tuning range of the QCL. The linewidth averaging could be reduced by shorter pulses, but for pulses shorter than 5 ns, the Fourier limitation increases the linewidth again. We present a technique to measure the dynamic laser linewidth continuously within a laser pulse of 30 ns to several μs. Due to the use of high-bandwidth detectors working from 2 to 12 μm, laser linewidths can be determined much more accurately than with short pulses. Instantaneous linewidths of DFB-QCLs down to 60 MHz are obtained. 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However, in standard usage, these lasers are used in pulsed operation, so that the laser linewidth can no longer be assumed to remain constant over the length of the pulse. For the instantaneous measurement of such dynamic linewidths, a suitable measurement technique was still lacking. Frequently, pulse lengths of 5 to 10 ns are used to obtain laser linewidths that will be suitable for gas measurements. In these experiments, standard photoconductive or photovoltaic mid-infrared detectors with bandwidths in the 1 MHz range are employed, so that the linewidth is averaged over the tuning range of the QCL. The linewidth averaging could be reduced by shorter pulses, but for pulses shorter than 5 ns, the Fourier limitation increases the linewidth again. We present a technique to measure the dynamic laser linewidth continuously within a laser pulse of 30 ns to several μs. Due to the use of high-bandwidth detectors working from 2 to 12 μm, laser linewidths can be determined much more accurately than with short pulses. Instantaneous linewidths of DFB-QCLs down to 60 MHz are obtained. This shows that QCLs are well suited for gas measurement in the mid-infrared.</abstract><doi>10.1063/1.1689750</doi><tpages>4</tpages></addata></record> |
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| ispartof | Journal of applied physics, 2004-05, Vol.95 (9), p.4551-4554 |
| issn | 0021-8979 1089-7550 |
| language | eng |
| recordid | cdi_crossref_primary_10_1063_1_1689750 |
| source | American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list) |
| title | Linewidth measurement of free-running, pulsed, distributed feedback quantum cascade lasers |
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