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AdvLIGO Laser Status Lutz Winkelmann, Maik Frede, Oliver Puncken, Bastian Schulz Ralf Wilhelm, and Dietmar Kracht Laser Zentrum Hannover Frank Seifert,

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Presentation on theme: "AdvLIGO Laser Status Lutz Winkelmann, Maik Frede, Oliver Puncken, Bastian Schulz Ralf Wilhelm, and Dietmar Kracht Laser Zentrum Hannover Frank Seifert,"— Presentation transcript:

1 AdvLIGO Laser Status Lutz Winkelmann, Maik Frede, Oliver Puncken, Bastian Schulz Ralf Wilhelm, and Dietmar Kracht Laser Zentrum Hannover Frank Seifert, Patrick Kwee and Benno Willke AEI LSC March 06 G060112-00Z

2 Outline Optimization History of the advLIGO laser –New laser design approach –Component related complications –Quality inspection measures for new components –Final results of new approach

3 History New resonator design to improve beam profile / mode control – Asymmetric resonator design

4 New Resonator Design

5

6

7

8 Better mode control pump power mode radius

9 History New resonator design to improve beam profile / mode control –Asymmetric resonator design => output power  115 W Difficulties with low damage threshold of 45° mirror coatings –Mirrors changed to high power IPG coated ones

10 History New resonator design to improve beam profile / mode control –Asymmetric resonator design => output power  115 W Difficulties with low damage threshold of 45° mirror coatings –Mirrors changed to high power IPG coated ones Power-loss due to impurities in laser crystal material –minimal Er/Yb contamination in crystal material –decrease in output power by unknown absorption effects –higher thermal-lensing

11 Comparison of laser crystals old and new

12 Quality inspection measures for new components: laser crystals

13 Variation of up to +/-10% in doping concentration for rods from different vendors

14 History New resonator design to improve beam profile / mode control –Asymmetric resonator design => output power  115 W Difficulties with low damage threshold of 45° mirror coatings –Mirrors changed to high power IPG coated ones Power-loss due to impurities in laser crystal material –after component (mirrors / Nd:YAG rod) change output power  125 W

15 History New resonator design to improve beam profile / mode control –Asymmetric resonator design => output power  115 W Difficulties with low damage threshold of 45° mirror coatings –Mirrors changed to high power IPG coated ones Power-loss due to impurities in laser crystal material –after component (mirrors / Nd:YAG rod) change output power  125 W Limitation of output power due to depolarization effects –45° HR1064nm / HT808nm => phase shift difference for p- and s- polarization up to 30° –mirrors act as /x-waveplates –additional depolarization losses

16 Mirrors Old mirror with low damage threshold: phase difference 3° for s- and p-polarization

17 Mirrors New high power mirror with IPG coating: phase difference 30° for s- and p-polarization

18 Mirrors Mirrors actually used: phase difference 20° for s- and p-polarization

19 Quality inspection measures for new components: mirror’s automated polarimeterpolarization analysis software

20 History New resonator design to improve beam profile / mode control –Asymmetric resonator design => output power  115 W Difficulties with low damage threshold of 45° mirror coatings –Mirrors changed to high power IPG coated ones Power-loss due to impurities in laser crystal material –after component (mirrors / Nd:YAG rod) change output power  125 W Limitation of output power due to depolarization effects –Increased output power by use of mirrors with 20° phase shift to  150 W

21 History New resonator design to improve beam profile / mode control –Asymmetric resonator design => output power  115 W Difficulties with low damage threshold of 45° mirror coatings –Mirrors changed to high power IPG coated ones Power-loss due to impurities in laser crystal material –after component (mirrors / Nd:YAG rod) change output power  125 W Limitation of output power due to depolarization effects –Increased output power by use of mirrors with 20° phase shift to  150 W Improvement of locking range –Replaced front-end by 35 W Nd:YVO 4 amplifier

22 New Laser Design

23 Injection-Locked Single Frequency Output-Power Power noise < 2.5% / h Single-frequency TEM 00 output power 183 W

24 Beam Quality Optimization of front-end to HPL mode-matching: Further improvements in output power and beam quality possible

25 Summary and Outlook 35 W front-end implemented 183 W linearly polarized output power ( >200 W expected due to new mirrors ) Beam quality M 2 < 1.2 (has to be optimized) Quality inspection measures for incoming components Further investigation on PET mirror resonance More accurate mode-matching of front-end and HPL

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