Presentation is loading. Please wait.

Presentation is loading. Please wait.

G030275-00-Z LIGO R&D1 Input Optics Definition, Function The input optics (IO) conditions light from the pre- stabilized laser (PSL) for injection into.

Published byEllen Randall Modified over 8 years ago

Similar presentations

Presentation on theme: "G030275-00-Z LIGO R&D1 Input Optics Definition, Function The input optics (IO) conditions light from the pre- stabilized laser (PSL) for injection into."— Presentation transcript:

1 G030275-00-Z LIGO R&D1 Input Optics Definition, Function The input optics (IO) conditions light from the pre- stabilized laser (PSL) for injection into the main interferometer Specific functions »modulation for RF sideband generation »Mode cleaning of dynamic laser pointing fluctuations; intermediate frequency and intensity stabilization »Power control into interferometer »Mode matching into interferometer cavities »Optical isolation of the PSL and distribution of light for length and alignment sensing and control

2 G030275-00-Z LIGO R&D2 Input Optics Conceptual Design

3 G030275-00-Z LIGO R&D3 Input optics heritage Advanced LIGO IO evolves from current LIGO IO »No major changes in AdL IO conceptual design Contiguity of IO team from current LIGO IO »Univ. of Florida assumes primary responsibility (as in current LIGO) »IO technical leaders same as in LIGO In terms of R&D, most progressed of Advanced LIGO subsystems »Relatively low technical risk »Conceptual Design and Design Requirements completed May 2002 Major R&D »Electro-optic modulators: materials, architecture »Faraday Isolators: thermal lensing, depolarization, dynamics »Adaptive mode matching »Mode cleaner thermal and noise modeling

4 G030275-00-Z LIGO R&D4 Isolators »Demonstration of fully compensated TGG-based isolator »45 dB isolation »Negligible thermal lensing Modulators »RTP: excellent thermal properties and nonlinear properties »RTP-based transverse modulator prototype tested –temperature-stabilized –no thermal lensing observed at 50 W powers Current Progress I No thermal compensation Thermal compensation

5 G030275-00-Z LIGO R&D5 Current Progress II Adaptive Mode Matching »in situ adjustment of mode matched based on laser/radiative heating »Ratio of ‘writing’ beam to ‘reading’ beam waist large »Preserves modal content Model Performance 1064 nm 532 nm Schott OG515 Preliminary Experiment

6 G030275-00-Z LIGO R&D6 Technical Challenges/Opportunities Challenges: »High power poses problems to IO optical components –Thermal lensing, thermally-induced depolarization, long term degradation –Primarily affects electro-optic modulators –Sideband amplitude stability –challenging for DC readout; beyond state-of-the-art for RF oscillators »Excess laser jitter may require active suppression –MC technical radiation pressure at requirement limit for required frequency noise Opportunities »Novel adaptive optics

7 G030275-00-Z LIGO R&D7 R&D Plans for 2004 Upgrade to 100 W laser testing »LIGO Livingston High Power Test Lab (underway) EOM prototype testing »RF amplitude modulation, amplitude modulation from parasitic nonlinear processes »Frequency stability (at limit of RF oscillator) »Long term laser exposure and damage testing (100 W powers) »Contingency modulation architectures if required Mode cleaner R&D »MELODY model of thermal effects (carrier, sidebands), potential astigmatism (mostly done) »Better understanding of beam jitter in PSL; if necessary, examination of possibility of second mode cleaner

8 G030275-00-Z LIGO R&D8 R&D Plans for 2004 (cont’d) Faraday isolation »Investigate dynamic effects due to loss of lock and rapid thermal loading »Trade study of optimal commercial components (wave plates, polarizers, TGG) Interferometer mode-matching »Prototype thermal adaptive telescope in vacuum »Preliminary Advanced LIGO telescope design; MELODY modeling of performance under various powers System interface issues »In-vacuum layout (underway)

9 G030275-00-Z LIGO R&D9 Schedule Design phase »Design Requirements and Conceptual Design: May 2002 (completed) »Preliminary Design Phase: April 2005 »Final Design: November 2007 »Milestones –Design LASTI mode cleaner and ancillary input optics: November 2002 (completed) –Deliver prototype modulators and isolators to Gingin High Power Test Facility: June 2004 –Deliver LASTI mode cleaner and ancillary optics: January 2005 –Deliver prototype modulators and isolators to LASTI: January 2006 Fabrication and assembly phase »Major optics procurement (all interferometers): August 2006 – August 2009 »Input optics installation –Interferometer 1: thru August 2008 –Interferometer 2: thru February 2009 –Interferometer 3: thru September 2009

10 G030275-00-Z LIGO R&D10 IO Team IO Manager: D. Reitze (Univ. Florida) LIGO Lab Liaison: P. King (CIT) IO Team »Univ. of Florida –R. Amin, K. Franzen, G. Mueller, M. Rakhmanov, D. Tanner, V. Quetschke, L. Zhang » Institute of Applied Physics (Nizhny Novgorod, Russia) –E. Khazanov, A. Malshakov, A. Shakin, A. Sergeev »LIGO Lab –P. King, R. Savage

Download ppt "G030275-00-Z LIGO R&D1 Input Optics Definition, Function The input optics (IO) conditions light from the pre- stabilized laser (PSL) for injection into."

Similar presentations

G030577-00-R LIGO Laboratory1 Advanced LIGO Research and Development David Shoemaker LHO LSC 11 November 2003.

G R LIGO Laboratory1 Advanced LIGO Research and Development David Shoemaker LHO LSC 11 November 2003.
G1200688-v1Squeezed Light Interferometry1 Squeezed Light Techniques for Gravitational Wave Detection July 6, 2012 Daniel Sigg LIGO Hanford Observatory.

G v1Squeezed Light Interferometry1 Squeezed Light Techniques for Gravitational Wave Detection July 6, 2012 Daniel Sigg LIGO Hanford Observatory.
High Power Input Optics for Advanced Virgo Julien Marque, Benjamin Canuel, Richard Day, Eric Génin, Flavio Nocera, Federico Paoletti The European Gravitational.

High Power Input Optics for Advanced Virgo Julien Marque, Benjamin Canuel, Richard Day, Eric Génin, Flavio Nocera, Federico Paoletti The European Gravitational.
Optical simulation – March 04 1 Optical Simulation François BONDU VIRGO Tools Goals Example: tuning of modulation frequency A few questions.

Optical simulation – March 04 1 Optical Simulation François BONDU VIRGO Tools Goals Example: tuning of modulation frequency A few questions.
G010407-00-M Advanced R&D1 Seismic Isolation Retrofit Plan for the LIGO Livingston Observatory Dennis Coyne 29 Nov 2001.

G M Advanced R&D1 Seismic Isolation Retrofit Plan for the LIGO Livingston Observatory Dennis Coyne 29 Nov 2001.
LIGO-G000206-00-W LIGO II Pre-stabilized Laser System Design Requirements and Conceptual Design David Ottaway, Todd Rutherford, Rick Savage, Peter Veitch,

LIGO-G W LIGO II Pre-stabilized Laser System Design Requirements and Conceptual Design David Ottaway, Todd Rutherford, Rick Savage, Peter Veitch,
LIGO-G000207-00-W LIGO II IO/PSL Optical Table Layouts Rick Savage and David Ottaway LIGO Science Collaboration Meeting Hanford, August 15-17, 2000.

LIGO-G W LIGO II IO/PSL Optical Table Layouts Rick Savage and David Ottaway LIGO Science Collaboration Meeting Hanford, August 15-17, 2000.
LIGO-G010242-00-D partial ADVANCED LIGO1 Development Plan R&D including Design through Final Design Review »for all long lead or high risk subsystems »LIGO.

LIGO-G D partial ADVANCED LIGO1 Development Plan R&D including Design through Final Design Review »for all long lead or high risk subsystems »LIGO.
Measurement of the laser beam profile at PSL to Mode Cleaner interface for the 40 Meter Prototype Interferometer A table of contents 1. Introduction 1.1.

Measurement of the laser beam profile at PSL to Mode Cleaner interface for the 40 Meter Prototype Interferometer A table of contents 1. Introduction 1.1.
Laser Interferometer Gravitational-wave Observatory1 Characterization of LIGO Input Optics University of Florida Thomas Delker Guido Mueller Malik Rakhmanov.

Laser Interferometer Gravitational-wave Observatory1 Characterization of LIGO Input Optics University of Florida Thomas Delker Guido Mueller Malik Rakhmanov.
LIGO-G060210-00-M April 5, 2006 Interferometer Sensing and Control (ISC) Cost and Schedule Breakout Presentation NSF Review of Advanced LIGO Project Richard.

LIGO-G M April 5, 2006 Interferometer Sensing and Control (ISC) Cost and Schedule Breakout Presentation NSF Review of Advanced LIGO Project Richard.
G0900746-v1 Squeezer Update Review August 25, 2009 H1 Squeezer Experiment ANU, AEI, MIT, CIT and LHO collaboration.

G v1 Squeezer Update Review August 25, 2009 H1 Squeezer Experiment ANU, AEI, MIT, CIT and LHO collaboration.
G050259-00-D Initial LIGO improvements & Advanced LIGO P Fritschel PAC Meeting LLO, 18 May 2005.

G D Initial LIGO improvements & Advanced LIGO P Fritschel PAC Meeting LLO, 18 May 2005.
G030460-00-R DC Readout for Advanced LIGO P Fritschel LSC meeting Hannover, 21 August 2003.

G R DC Readout for Advanced LIGO P Fritschel LSC meeting Hannover, 21 August 2003.
LSC meeting, HLO, August 18, 2004 IAP/UF/LIGO Research Collaboration: Status and Prospectives Efim Khazanov, Ilya Kozhevatov, Anatoly Malshakov, Oleg Palashov,

LSC meeting, HLO, August 18, 2004 IAP/UF/LIGO Research Collaboration: Status and Prospectives Efim Khazanov, Ilya Kozhevatov, Anatoly Malshakov, Oleg Palashov,
Design of Stable Power-Recycling Cavities University of Florida 10/05/2005 Volker Quetschke, Guido Mueller.

Design of Stable Power-Recycling Cavities University of Florida 10/05/2005 Volker Quetschke, Guido Mueller.
LIGO-G060207-00-M May 31-June 2, 2006 Input Optics (IO) Cost and Schedule Breakout Presentation NSF Review of Advanced LIGO Project David Reitze UF.

LIGO-G M May 31-June 2, 2006 Input Optics (IO) Cost and Schedule Breakout Presentation NSF Review of Advanced LIGO Project David Reitze UF.
Test mass dynamics with optical springs proposed experiments at Gingin Chunnong Zhao (University of Western Australia) Thanks to ACIGA members Stefan Danilishin.

Test mass dynamics with optical springs proposed experiments at Gingin Chunnong Zhao (University of Western Australia) Thanks to ACIGA members Stefan Danilishin.
LIGO- G030033-00-R 40m Progress, LSC meeting, 3/031 40m Laboratory Upgrade Progress Report Osamu Miyakawa, Caltech 40m Technical Advisory Committee LIGO-G030033-00-R.

LIGO- G R 40m Progress, LSC meeting, 3/031 40m Laboratory Upgrade Progress Report Osamu Miyakawa, Caltech 40m Technical Advisory Committee LIGO-G R.
LIGO-G010262-00-M Management of the LIGO Project Gary Sanders California Institute of Technology Presented to the Committee on Programs and Plans of the.

LIGO-G M Management of the LIGO Project Gary Sanders California Institute of Technology Presented to the Committee on Programs and Plans of the.

Similar presentations

Ads by Google