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165 results on '"Carter, Adrian L."'

1. Characterization of the monolithic fiber amplifier engineering prototype for the next generation of gravitational wave detectors

Author

Wellmann, Felix, Steinke, Michael, Thies, Fabian, Bode, Nina, Oppermann, Patrick, Willke, Benno, Overmeyer, Ludger, Neumann, Jörg, Kracht, Dietmar, Dong, Liang, and Carter, Adrian L.

Subjects
Materials science, Gravitational-wave observatory, Extinction ratio, business.industry, Amplifier, Detector, Dewey Decimal Classification::600 | Technik::620 | Ingenieurwissenschaften und Maschinenbau, Modular design, Laser, Single-frequency, LIGO, law.invention, Interferometry, law, Optoelectronics, Gravitational wave detection, ddc:620, business, Monolithic fiber amplifier, Konferenzschrift
Abstract

Single-frequency Yb3+ fiber amplifiers operating at 1064 nm are promising candidates to fulfill the challenging requirements for laser sources of the next generation of interferometric gravitational wave detectors. We present the current development progress of a fiber amplifier engineering prototype and compare the optical and thermal performance to the solid-state-laser source of advanced LIGO. The fiber amplifier system consists of two monolithic fiber amplifier stages which currently deliver more than 110 W (functional prototype demonstrated 215 W [9,11]) of output power. The fiber amplifier output beam has one to two orders of magnitude lower relative beam pointing and relative power noise in the lower frequency range of 1 Hz to 100 Hz compared to the solid-state-laser system. It also has a polarization extinction ratio above 21 dB and a TEM00-mode content of more than 97.8 % ±0.6 % at 110 W output power. Besides the optical properties, repair and maintenance procedures are improved by a modular design of the system. Each of the modules can separately be maintained and repaired or easily be replaced by a preassembled module; it therefore minimizes laser downtimes. Another advantage is the lower heat load of approximately 500 W compared to the SSL, which produces more than 4500 W of heat, both at an optical output power of 200 W. The lower heat load simplifies cooling and reduces the complexity of the modules. © 2019 SPIE.

Published
2019

2. Characterization of the monolithic fiber amplifier engineering prototype for the next generation of gravitational wave detectors

Author

Dong, Liang, Carter, Adrian L., Wellmann, Felix, Steinke, Michael, Thies, Fabian, Bode, Nina, Oppermann, Patrick, Willke, Benno, Overmeyer, Ludger, Neumann, Jörg, Kracht, Dietmar, Dong, Liang, Carter, Adrian L., Wellmann, Felix, Steinke, Michael, Thies, Fabian, Bode, Nina, Oppermann, Patrick, Willke, Benno, Overmeyer, Ludger, Neumann, Jörg, and Kracht, Dietmar

Abstract

Single-frequency Yb3+ fiber amplifiers operating at 1064 nm are promising candidates to fulfill the challenging requirements for laser sources of the next generation of interferometric gravitational wave detectors. We present the current development progress of a fiber amplifier engineering prototype and compare the optical and thermal performance to the solid-state-laser source of advanced LIGO. The fiber amplifier system consists of two monolithic fiber amplifier stages which currently deliver more than 110 W (functional prototype demonstrated 215 W [9,11]) of output power. The fiber amplifier output beam has one to two orders of magnitude lower relative beam pointing and relative power noise in the lower frequency range of 1 Hz to 100 Hz compared to the solid-state-laser system. It also has a polarization extinction ratio above 21 dB and a TEM00-mode content of more than 97.8 % ±0.6 % at 110 W output power. Besides the optical properties, repair and maintenance procedures are improved by a modular design of the system. Each of the modules can separately be maintained and repaired or easily be replaced by a preassembled module; it therefore minimizes laser downtimes. Another advantage is the lower heat load of approximately 500 W compared to the SSL, which produces more than 4500 W of heat, both at an optical output power of 200 W. The lower heat load simplifies cooling and reduces the complexity of the modules. © 2019 SPIE.

Published
2019

3. Recent progress on monolithic fiber amplifiers for next generation of gravitational wave detectors

Author

Wellmann, Felix, Booker, Phillip, Hochheim, Sven, Theeg, Thomas, de Varona, Omar, Fittkau, Willy, Overmeyer, Ludger, Steinke, Michael, Weßels, Peter, Neumann, Jörg, Kracht, Dietmar, Carter, Adrian L., and Hartl, Ingmar

Subjects
Dewey Decimal Classification::600 | Technik::620 | Ingenieurwissenschaften und Maschinenbau, monolithic fiber amplifier, chemistry.chemical_element, 01 natural sciences, law.invention, 010309 optics, Erbium, law, 0103 physical sciences, Fiber, 010306 general physics, Konferenzschrift, Physics, business.industry, Gravitational wave, Amplifier, Detector, single-frequency, Modular design, Laser, Interferometry, chemistry, gravitational waves, Optoelectronics, ddc:620, business
Abstract

Single-frequency fiber amplifiers in MOPA configuration operating at 1064 nm (Yb3p) and around 1550 nm (Er3p or Er3p:Yb3p) are promising candidates to fulfill the challenging requirements of laser sources of the next generation of interferometric gravitational wave detectors (GWDs). Most probably, the next generation of GWDs is going to operate not only at 1064 nm but also at 1550 nm to cover a broader range of frequencies in which gravitational waves are detectable. We developed an engineering fiber amplifier prototype at 1064 nm emitting 215 W of linearly-polarized light in the TEM00 mode. The system consists of three modules: the seed source, the pre-amplifier, and the main amplifier. The modular design ensures reliable long-term operation, decreases system complexity and simplifies repairing and maintenance procedures. It also allows for the future integration of upgraded fiber amplifier systems without excessive downtimes. We also developed and characterized a fiber amplifier prototype at around 1550 nm that emits 100 W of linearly-polarized light in the TEM00 mode. This prototype uses an Er3p:Yb3p codoped fiber that is pumped off-resonant at 940 nm. The off-resonant pumping scheme improves the Yb3p-to-Er3p energy transfer and prevents excessive generation of Yb3p-ASE.

Published
2018

4. Recent progress on monolithic fiber amplifiers for next generation of gravitational wave detectors

Author

Carter, Adrian L., Hartl, Ingmar, Wellmann, Felix, Booker, Phillip, Hochheim, Sven, Theeg, Thomas, de Varona, Omar, Fittkau, Willy, Overmeyer, Ludger, Steinke, Michael, Weßels, Peter, Neumann, Jörg, Kracht, Dietmar, Carter, Adrian L., Hartl, Ingmar, Wellmann, Felix, Booker, Phillip, Hochheim, Sven, Theeg, Thomas, de Varona, Omar, Fittkau, Willy, Overmeyer, Ludger, Steinke, Michael, Weßels, Peter, Neumann, Jörg, and Kracht, Dietmar

Abstract

Single-frequency fiber amplifiers in MOPA configuration operating at 1064 nm (Yb3+) and around 1550 nm (Er3+ or Er3+:Yb3+) are promising candidates to fulfill the challenging requirements of laser sources of the next generation of interferometric gravitational wave detectors (GWDs). Most probably, the next generation of GWDs is going to operate not only at 1064 nm but also at 1550 nm to cover a broader range of frequencies in which gravitational waves are detectable. We developed an engineering fiber amplifier prototype at 1064 nm emitting 215 W of linearly-polarized light in the TEM00 mode. The system consists of three modules: the seed source, the pre-amplifier, and the main amplifier. The modular design ensures reliable long-term operation, decreases system complexity and simplifies repairing and maintenance procedures. It also allows for the future integration of upgraded fiber amplifier systems without excessive downtimes. We also developed and characterized a fiber amplifier prototype at around 1550 nm that emits 100 W of linearly-polarized light in the TEM00 mode. This prototype uses an Er3+:Yb3+ codoped fiber that is pumped off-resonant at 940 nm. The off-resonant pumping scheme improves the Yb3+-to-Er3+ energy transfer and prevents excessive generation of Yb3+-ASE.

Published
2018

6. Polarization effects in a high-birefringence elliptical fiber laser with a Bragg grating in a low-birefringence fiber

Author

Hernandez-Cordero, Juan, Kozlov, Valery A., Carter, Adrian L. G., and Morse, T. F.

Subjects
Polarization (Electricity) -- Measurement, Lasers -- Research, Optics -- Research, Astronomy, Physics
Abstract

The polarization characteristics of a fiber laser cavity that combines a high-birefringence [Er.sup.3+]-doped elliptical core fiber with a Bragg grating fabricated in a low-birefringence (Low-Bi) fiber are studied. It is shown that, by use of an adequate length of Low-Bi fiber and an intracavity polarization controller, the dependence of the fiber laser's state of polarization on the pump's state of polarization can be altered. This fiber laser cavity design allows for the realization of a double-frequency, orthogonally polarized single-mode fiber laser source insensitive to the polarization parameters of the pump source. [C] 2000 Optical Society of America OCIS codes: 140.3510, 060.2320, 260.1440, 060.2380, 060.2420, 260.5430, 230.1480, 140.0140.

Published
2000

46. VAD technology for laser fibers

Author

Carter, Adrian L., Dong, Liang, Kim, Jaesun, Cho, Hyungsu, Park, Gaye, Han, Jaewan, Lee, Junho, Kim, Daeyoung, Hwang, Chanho, Moon, Dae Seung, Jung, Changhyun, and Ouh, Chihwan

Published
2019
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