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Crab Pulsar

Probing the Universe for Gravitational Waves Barry C. Barish Caltech Cornell University 3-April-06. Crab Pulsar. General Relativity the essential idea. G mn = 8 pT mn. Gravity is not a force, but a property of space & time Spacetime = 3 spatial dimensions + time

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Crab Pulsar

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  1. Probing the Universe for Gravitational WavesBarry C. BarishCaltechCornell University 3-April-06 Crab Pulsar

  2. General Relativitythe essential idea Gmn= 8pTmn • Gravity is not a force, but a property of space & time • Spacetime = 3 spatial dimensions + time • Perception of space or time is relative • Objects follow the shortest path through this warped spacetime; path is the same for all objects • Overthrew the 19th-century concepts of absolute space and time • Concentrations of mass or energy distort (warp) spacetime LIGO - Cornell University

  3. After several hundred years, a small crack in Newton’s theory ….. perihelion shifts forward an extra +43”/century compared to Newton’s theory LIGO - Cornell University

  4. A new prediction of Einstein’s theory … Light from distant stars are bent as they graze the Sun. The exact amount is predicted by Einstein's theory. LIGO - Cornell University

  5. Confirming Einstein …. bending of light Observation made during the solar eclipse of 1919 by Sir Arthur Eddington, when the Sun was silhouetted against the Hyades star cluster A massive object shifts apparent position of a star LIGO - Cornell University

  6. A Conceptual Problem is solved ! Newton’s Theory “instantaneous action at a distance” Einstein’s Theory information carried by gravitational radiation at the speed of light LIGO - Cornell University

  7. Einstein’s Theory of Gravitation • Gravitational waves are necessary consequence of Special Relativity with its finite speed for information transfer • Gravitational waves come from the acceleration of masses and propagate away from their sources as a space-time warpage at the speed of light gravitational radiation binary inspiral of compact objects LIGO - Cornell University

  8. Einstein’s Theory of Gravitation gravitational waves • Using Minkowski metric, the information about space-time curvature is contained in the metric as an added term,hmn. In the weak field limit, the equation can be described with linear equations. If the choice of gauge is thetransverse traceless gaugethe formulation becomes a familiar wave equation • The strainhmntakes the form of a plane wave propagating at the speed of light (c). • Since gravity is spin 2, the waves have two components, but rotated by 450 instead of 900 from each other. LIGO - Cornell University

  9. Russel A. Hulse Joseph H.Taylor Jr The Evidence For Gravitational Waves The Discovered and Studied Pulsar System PSR 1913 + 16 with Radio Telescope LIGO - Cornell University Source: www.NSF.gov

  10. The evidence for gravitational waves • Neutron binary system • separation = 106 miles • m1 = 1.4m • m2 = 1.36m • e = 0.617 Hulse & Taylor 17 / sec · · • Prediction • from • general relativity • spiral in by 3 mm/orbit • rate of change orbital • period period ~ 8 hr PSR 1913 + 16 Timing of pulsars LIGO - Cornell University

  11. “Indirect”evidence for gravitational waves LIGO - Cornell University

  12. Direct Detection Gravitational Wave Astrophysical Source Terrestrial detectors LIGO, TAMA, Virgo, AIGO Detectors in space LISA LIGO - Cornell University

  13. Gravitational Waves in Space LISA Three spacecraft, each with a Y-shaped payload, form an equilateral triangle with sides 5 million km in length. LIGO - Cornell University

  14. Network of Interferometers LIGO Virgo GEO TAMA AIGO decompose the polarization of gravitational waves detection confidence locate the sources LIGO - Cornell University

  15. The frequency range of astronomy • EM waves studied over ~16 orders of magnitude • Ultra Low Frequency radio waves to high energy gamma rays LIGO - Cornell University

  16. Frequencies of Gravitational Waves The diagram shows the sensitivity bands for LISA and LIGO LIGO - Cornell University

  17. Gravitational Wave Detection free masses h = strain amplitude of grav. waves h = DL/L ~ 10-21 L = 4 km DL ~ 10-18 m Laser Interferometer laser LIGO - Cornell University

  18. laser Interferometer optical layout vacuum suspended, seismically isolated test masses mode cleaner 4 km various optics 4-5 W 150-200 W 9-12 kW 10 W 6-7 W 200 mW photodetector GW channel LIGO - Cornell University

  19. LIGOLaser Interferometer Gravitational-wave Observatory Hanford Observatory MIT Caltech Livingston Observatory LIGO - Cornell University

  20. 4 km LIGO Livingston, Louisiana LIGO - Cornell University

  21. 4 km 2 km LIGO Hanford Washington LIGO - Cornell University

  22. LIGO Beam Tube • Minimal enclosure • Reinforced concrete • No services • 1.2 m diameter - 3mm stainless 50 km of weld • 65 ft spiral welded sections • Girth welded in portable clean room in the field LIGO - Cornell University

  23. Vacuum Chambersvibration isolation systems • Reduce in-band seismic motion by 4 - 6 orders of magnitude • Compensate for microseism at 0.15 Hz by a factor of ten • Compensate (partially) for Earth tides LIGO - Cornell University

  24. LIGOvacuum equipment LIGO - Cornell University

  25. Seismic Isolationsuspension system Suspension assembly for a core optic • Support structure is welded tubular stainless steel • Suspension wire is 0.31 mm diameter steel music wire • Fundamental violin mode frequency of 340 Hz LIGO - Cornell University

  26. Surface uniformity < 1 nm rms Scatter < 50 ppm Absorption < 2 ppm ROC matched < 3% Internal mode Q’s > 2 x 106 LIGO Opticsfused silica Caltech data CSIRO data LIGO - Cornell University

  27. Core Opticsinstallation and alignment LIGO - Cornell University

  28. Lock Acquisition LIGO - Cornell University

  29. Tidal Compensation Data Tidal evaluation 21-hour locked section of S1 data Predicted tides Feedforward Feedback Residual signal on voice coils Residual signal on laser LIGO - Cornell University

  30. Controlling angular degrees of freedom LIGO - Cornell University

  31. Seismic Noise Quantum Noise Radiation pressure Residual gas scattering "Shot" noise Wavelength & amplitude fluctuations Thermal (Brownian) Noise Interferometer Noise Limits test mass (mirror) LASER Beam splitter photodiode LIGO - Cornell University

  32. What Limits LIGO Sensitivity? • Seismic noise limits low frequencies • Thermal Noise limits middle frequencies • Quantum nature of light (Shot Noise) limits high frequencies • Technical issues - alignment, electronics, acoustics, etc limit us before we reach these design goals LIGO - Cornell University

  33. Evolution of LIGO Sensitivity • S1: 23 Aug – 9 Sep ‘02 • S2: 14 Feb – 14 Apr ‘03 • S3: 31 Oct ‘03 – 9 Jan ‘04 • S4: 22 Feb – 23 Mar ‘05 • S5: 4 Nov ‘05 - LIGO - Cornell University

  34. 2 2 2 2 4 4 4 4 1 1 1 1 3 3 3 3 E3 E7 E5 E9 E10 E8 Runs S1 S2 S3 S4 S5 Science First Science Data Commissioning /Running Time Line 2000 2001 2002 2003 2004 2005 2006 1999 2 4 2 4 4 1 3 1 3 2 4 3 1 3 Inauguration First Lock Full Lock all IFO Now 4K strain noise at 150 Hz [Hz-1/2] 10-21 10-22 4x10-23 10-17 10-18 10-20 E2 E11 Engineering LIGO - Cornell University

  35. Initial LIGO - Design Sensitivity LIGO - Cornell University

  36. Rms strain in 100 Hz BW: 0.4x10-21 Sensitivity Entering S5 … LIGO - Cornell University

  37. S5 Run Plan and Outlook Interferometer duty cycles • Goal is to“collect at least a year’s data of coincident operation at the science goal sensitivity” • Expect S5 to last about 1.5 yrs • S5 is not completely ‘hands-off’ LIGO - Cornell University

  38. Sensitivity Entering S5 … Hydraulic External Pre-Isolator LIGO - Cornell University

  39. Locking Problem is Solved LIGO - Cornell University

  40. What’s after S5? LIGO - Cornell University

  41. “Modest” Improvements Now – 14 Mpc Then – 30 Mpc LIGO - Cornell University

  42. Astrophysical Sources • Compact binary inspiral: “chirps” • NS-NS waveforms are well described • BH-BH need better waveforms • search technique: matched templates • Supernovae / GRBs: “bursts” • burst signals in coincidence with signals in electromagnetic radiation • prompt alarm (~ one hour) with neutrino detectors • Pulsars in our galaxy: “periodic” • search for observed neutron stars (frequency, doppler shift) • all sky search (computing challenge) • r-modes • Cosmological Signal “stochastic background” LIGO - Cornell University

  43. Compact Binary Collisions • Neutron Star – Neutron Star • waveforms are well described • Black Hole – Black Hole • need better waveforms • Search: matched templates “chirps” LIGO - Cornell University

  44. Template Bank 2110 templatesSecond-orderpost-Newtonian • Covers desiredregion of massparam space • Calculatedbased on L1noise curve • Templatesplaced formax mismatchof  = 0.03 LIGO - Cornell University

  45. Then inverse Fourier transform gives you the filter output at all times: Find maxima of over arrival time and phaseCharacterize these by signal-to-noise ratio (SNR) and effective distance Optimal Filtering frequency domain • Transform data to frequency domain : • Generate template in frequency domain : • Correlate, weighting by power spectral density of noise: LIGO - Cornell University

  46. Matched Filtering LIGO - Cornell University

  47. Inspiral Searches Mass BBH Search S3/S4 Physical waveform follow-up S3/S4 10 Inspiral-Burst S4 3 Spin is important Detection templates S3 BNS S3/S4 1 “High mass ratio” Coming soon PBH MACHO S3/S4 0.1 0.1 1 10 3 Mass LIGO - Cornell University

  48. Binary Neutron Star Search Results (S2) Physical Review D, In Press Rate < 47 per year per Milky-Way-like galaxy cumulative number of events signal-to-noise ratio squared LIGO - Cornell University

  49. Binary Black Hole Search LIGO - Cornell University

  50. Binary Inspiral Search: LIGO Ranges binary neutron star range binary black hole range Image: R. Powell LIGO - Cornell University

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