Test Mass Substrate Material Selection for Advanced LIGO-An.ppt

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1、LIGO R&D,1,Test Mass Substrate Material Selection for Advanced LIGO: An Update from the Optics Working GroupDavid ReitzeUFfor the OWG,?,?,Sapphire,Fused Silica,LIGO R&D,2,Test Mass Material Selection,At the LSC meeting, Livingston, LA, March 2004:Date for selection: June 30, 2004,LIGO R&D,3,June 30t

2、h has passed; where are we?,Deadline driven by intimate link between optics and suspensions Physical dimensions of test mass material different for sapphire and fused silica Test mass size difference affects quad suspension design Must fix size to move design forward (and keep UK funding synchronize

3、d) Do we have enough information to make a good decision? We always want more Very active R leads to a more complex decision Agreement between SUS and OWG to push back decision Not a problem given current AdL funding and construction schedule,LIGO R&D,4,Down Selection Participants,LSC Participants H

4、elena Armandula, Gari Billingsley, Eric Black, Jordan Camp*, Dennis Coyne, Marty Fejer*, Sam Finn*, Peter Fritschel*, Gregg Harry, Jim Hough*, Steve Penn, Dave Reitze, Roger Route, Norna Robertson, Shiela Rowan, Peter Saulson*, David Shoemaker*, Phil Willems* * DS committee member, *DS chair Industr

5、ial Partners/Contributors Chandra Khattak (Crystal Systems, sapphire), Jean-Marie Mackowsky (SMA Virgo, coatings), Roger Netterfield (CSIRO, coatings),LIGO R&D,5,Sapphire Test Mass Requirements,P. Fritschel, et al., LIGO T010075-00; G. Billingsley, et al., LIGO-T020103-08,*ITM only *assumes active t

6、hermal compensation above 40 ppm/cm,LIGO R&D,6,Fused Silica Test Mass Requirements,P. Fritschel, et al., LIGO T010075-00; G. Billingsley, et al., LIGO-T020103-05,*ITM only *assumes active thermal compensation,LIGO R&D,7,The Importance of Coatings,G. Harry, et al., LIGO-C030187-00-R,Currently,Mechani

7、cal loss: 2-3 x 10-4 (tantala),Absorption: 0.5-1 ppm,LIGO R&D,8,Decision Criteria: Beyond the physical, optical, and mechanical characteristics,Primacy of the astrophysics mission of Advanced LIGO Which substrate is better suited to optimizing the number, type, and parameter estimation of detectable

8、 events? IFO performance - “Will it work if we choose _?” Hard failure mode interferometer will not operate (or operate with significant reduction in sensitivity) Soft failure mode some reduced sensitivity, reach IFO Schedule “Will there be delays?” Fabrication delays Commissioning delays IFO Implem

9、entation Issues thermal compensation Cost turns out to be about the same for both materials Fallback “If we choose substrate X and discover a nasty hard failure mode, how easily can we fall back to substrate Y?”,LIGO R&D,9,DS Methodology,Exchange and coordination of research through meetings and tel

10、econs Scheduled monthly OWG meetings Frequent (at least monthly, sometimes more) meetings to discuss coating R&D Formal Down-selection telecons Define and refine selection criteria Identify gaps in knowledge Quantify risk Score sheet for sapphire and silica All scores have error bars Some error bars

11、 are larger than others Some things are still unknown Work Product recommendation to the LIGO Lab management (who will make the final decision),LIGO R&D,10,Astrophysics Selection Criteria,Different sources different performance metrics for sapphire and fused silica NS-NS inspiral 10 M BH-BH merger A

12、ccreting low mass X-ray binary source near 700 Hz Stochastic background Evaluate on Bench 2.1 Consider optimistic, pessimistic, and baseline TM parameters Normalized performance dependent on event type Inspirals, mergers, XRB (2*RangesubX/SRange) 3 Stochastic Log(WsubX/ WsubY) Equal weighting for ev

13、ents,G. Harry, D. Shoemaker, MIT,(Bildstein, arXiv:astro-ph/0212004),LIGO R&D,11,Thermal Noise Performance: LMXBs,FS has better low frequency performance But more uncertainty Sapphire TE noise helped by mesa beam Sapphire has better high frequency performance Sapphire sees almost all LMXBs,P. Fritsc

14、hel, G. Harry, MIT Kip Thorne, CIT,LIGO R&D,12,Impact on BHBH binary searches,Kip Thorne, CIT,LIGO R&D,13,Astrophysics Score Sheet,LIGO R&D,14,Performance Selection Criteria,Which substrate has the best opportunity for reaching the AdLIGO SRD sensitivity?Risks for sapphire Growth of 15-18 large blan

15、ks with average absorption 100 ppm/cm and absorption fluctuations 0.25 mean absorption Not as much known about coatings on sapphire Adhesion, absorption Thermal noise from differential thermal expansion between silica bonding ears and sapphire flats Risks for Silica Mechanical loss not yet completel

16、y understood for large substrates Coating absorption inhomogeneities thermal compensation challenge Risks for both Parametric excitation of mirror Stokes modes by laser Noise from patch fields on the optics,LIGO R&D,15,Performance Score Sheet,Fused silica 1.5x more likely to perform Stokes instabili

17、ty how important?,V.B. Braginsky, et al., Phys. Lett. (2001).,LIGO R&D,16,Schedule Perspective,Evaluation of schedule slippage risk Vendor delays Sapphire crystal growth More difficult to polish sapphire to required tolerances; more steps involved (compensating polish) Sapphire may require high temp

18、erature annealing Coating adhesion on sapphire Assembly delays Bonding ears for suspension fibers Commissioning delays electrostatic charging,LIGO R&D,17,Schedule Score Sheet,Fused silica 1.9x more likely to meet schedule Parametric instabilitiy, charging not well investigated,LIGO R&D,18,Implementa

19、tion Perspective,How does the choice of substrate impact implementing AdLIGO IFOs? Can we fit a second interferometer at one of the sites? Suspension issues related to TM size differences? Thermal compensation Fallback,LIGO R&D,19,Implementation Score Sheet,Sapphire 4.5x better than silica Thermal c

20、ompensation implementation critical,LIGO R&D,20,Thermal Compensation,Implemented in LIGO I Stabilization of power recycling cavity for RF sidebands For AdLIGO, require homogeneous and inhomogeneous compensation Homogeneous heating: beam profile imprints DT(r) on mirror due to average absorptionDOPD

21、= DT(r) (dn/dT) L bulk index optical path distortion DL = a DT(r) L surface physical distortion Compensate using a ring heater or laser (CO2 the current choice) Inhomogeneous heating: beam profile imprints DT(x,y,z) on mirror due to fluctuations in absorption Compensate using a laser (CO2 the curren

22、t choice) Both substrate and coating absorption problematic Coating more so!,Phil Willems, CIT, Ryan Lawrence, MIT,LIGO R&D,21,Thermal Compensation (contd),Affects AdLIGO in 3 ways Arm cavity mode and scattered power Homogeneous waist, spots on end mirrors are power dependent Mode changes sapphire =

23、 0.9, silica = 0.8 For laser actuation, worry about injecting noise sapphire = 0.5, silica = 0.9Inhomogeneous coating absorption inhomogeneties Not much known, but can tolerate 30 mW (I) hot spots sapphire = 0.8, silica = 0.2,Phil Willems, CIT,LIGO R&D,22,Coating Absorption Maps - Fused Silica,SMA V

24、irgo,LIGO R&D,23,Thermal Compensation (contd),RF sideband power in the recycling cavities - RF sidebands resonate in PR, SR cavities Thermal distortions clamp sideband power Silica compensable for coating absorption 0.5 ppm Sapphire compensable for coating absorption 0.5 ppm Inhomogeneites cause sig

25、nificant problems for sapphire sapphire = 0.8, silica = 0.6 Efficiency of GW coupling to dark port GWs resonate in SR thermally distorted SR cavity depends on operational mode (tuned vs detuned) depends on frequency range (source) sapphire = 0.6, silica = 0.4,Phil Willems, CIT,LIGO R&D,24,Sapphire O

26、utstanding Issues,Absorption in large substrates: 3 pieces measured by SMA-Virgo #1 (314 mm x 130 mm): 60 ppm/cm average, 30 130 ppm/cm range #2 (314 mm x 130 mm): 31 ppm/cm average, 10 53 ppm/cm range #3 (250 mm x 100 mm): 49-55 ppm/cm average, 29 110 ppm/cm range,Post-growth annealing studies (Sta

27、nford) Annealing time scaling with substrate size? Does annealing smoothout inhomogeneous absorption?,LIGO R&D,25,Absorption in Sapphire,Investigates methods for reducing homogeneous and inhomogeneous absorption using high temperature anneal and cooling Vary T, cool down period, annealing gas In sma

28、ll samples (2” x 2”), see reductions to 10-20 ppm/ range Need to look at larger samples Possible evidence for smoothing of inhomogeneities due to diffusion Need more statistics,R. Route, M. Fejer, Stanford,LIGO R&D,26,CSI-A017 sapphire cylinder results of hydrogen-annealing at 1900C,N.A. due to surf

29、ace topography after anneal,Before,Before,After,R. Route, M. Fejer, Stanford,Long.,Trans.,LIGO R&D,27,Hi-Temp. Vacuum Annealing Results (Promising but need more data on high spatial frequency inhomogeneities and kinetics),LIGO R&D,28,Sapphire Outstanding Issues II,Sapphire mirror coatings Coating pr

30、ocess not as mature as fused silica Adhesion Microroughness Cleaning surface after polishing R&D effort required by vendor Excess noise from silica-sapphire bonding interface Differential thermal expansion Stress creaking Inhomogeneous bonds suffer more Not much known,unbaked,baked,LIGO R&D,29,Fused

31、 Silica Outstanding Issues,Coating absorption Identified as a potentially serious problem for thermal compensation in AdLIGO Homogeneous absorption: 1 ppm breaks interferometer Inhomogeneous absorption: carrier arm cavity loss; sideband PRM, SRM loss Thermal noise in fused silica Understanding of me

32、chanical loss Large substrates Frequency dependence,LIGO R&D,30,Mechanical Loss in Fused Silica,Need fused silica Q 108 for AdLIGO Salient data Syracuse group: low frequency f (V/S)-1 Measurements on large substrates done at high frequencies (above GW band) Empirical model for frequency dependence o

33、f fused silica,Steve Penn, HWS,LIGO R&D,31,Mechanical Loss in Fused Silica,Steve Penn, HWS,AdLIGO,LIGO R&D,32,Advanced LIGO Coating Research,Major efforts focused on: Reducing mechanical loss (thermal, thermo-elastic noise) Reducing optical loss (coating absorption and scattering) without forgetting

34、 about homogeneity, birefringence, uniformity Advanced LIGO R&D groups: Caltech, Glasgow Hobart William Smith College, MIT, Stanford Joint R&D efforts with: CSIRO stoichiometry, optical loss, Youngs modulus of tantala SMA Virgo doping and different coatings to reducing mechanical loss,LIGO R&D,33,“C

35、oating thermal noise engineering”,Doping with Ta2O5 with Ti relaxes stress SMA-Virgo/Glasgow/MIT effort,l/4 SiO2 l/4 Ta2O5 Coatings with TiO2 dopantDopant Conc. Loss AngleNone 2.7 10-4Low 1.8 10-4 Medium 1.6 10-4 High ?,Greg Harry, MIT,LIGO R&D,34,Conclusions,Selection of test mass substrate enterin

36、g final phase Late by official schedule, nonetheless the delay has been worthwhile Sapphire better based on astrophysics considerations Assumes all sources are equally interesting Fused silica better on confidence in performance, schedule On cost and implementation, roughly equal except for thermal compensation Caveat is thermal compensation; favors sapphire, but scary for both Active R&D efforts continuing in sapphire absorption, silica Q, coatings DS meeting tomorrow 8 am Decision likely in the very near future Input solicited,