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Gravitational Wave Detection Using Pulsar Timing Current Status and Future Progress Fredrick A. Jenet Center for Gravitational Wave Astronomy University.

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Presentation on theme: "Gravitational Wave Detection Using Pulsar Timing Current Status and Future Progress Fredrick A. Jenet Center for Gravitational Wave Astronomy University."— Presentation transcript:

1 Gravitational Wave Detection Using Pulsar Timing Current Status and Future Progress Fredrick A. Jenet Center for Gravitational Wave Astronomy University of Texas at Brownsville

2 Collaborators Dick Manchester ATNF/CSIRO Australia George Hobbs ATNF/CSIRO Australia KJ Lee Peking U. China Andrea Lommen Franklin & Marshall USA Shane L. Larson Penn State USA Linqing Wen AEI Germany Teviet Creighton Caltech USA John Armstrong JPL USA

3 Main Points Radio pulsar can directly detect gravitational waves –How can you do that? What can we learn? –Astrophysics –Gravity Current State of affairs What can the SKA do.

4 Radio Pulsars

5 Gravitational Waves “Ripples in the fabric of space-time itself” g  =   + h    h  /   t +  2 h  = 4  T  G  (g) = 8  T 

6 Three Categories of G-waves Periodic Signals (Single Source) Burst Signals (Single Source) Stochastic Signals (Multiple Sources)

7 Pulsar Timing Pulsar timing is the act of measuring the arrival times of the individual pulses

8 How does one detect G- waves using Radio pulsars? Pulsar timing involves measuring the time-of arrival (TOA) of each individual pulse and then subtracting off the expected time-of-arrival given a physical model of the system. R = TOA – TOA m

9 Timing residuals from PSR B1855+09 From Jenet, Lommen, Larson, & Wen, ApJ, May, 2004 Data from Kaspi et al. 1994 Period =5.36 ms Orbital Period =12.32 days

10 The effect of G-waves on pulsar timing Earth Pulsar

11 kk  Photon Path G-wave Pulsar Earth

12 t0 t0 + P0 t0 + P0 + P1 t0 + P0 + P1 + P2 TOA(N) =  0 N-1 P i + t 0 P i = P i m +  P i R(N) = TOA(N) – TOA(N) m =  0 N-1  P i P i = 1/ i = 1/( i m +  i ) R(N) = -  0 N-1  i /( i m ) 2 R(t) = -  0 N-1 P i m  i / v i m

13 The effect of G-waves on the Timing residuals

14 h =  RR rms  1  sh >= 1  s  /N 1/2 10 -14 10 -13 10 -12 3  10 -9 h Frequency, Hz 3  10 -8 3  10 -7 10 -15 10 -16 3  10 -10 3  10 -11 Sensitivity of a Pulsar timing “Detector” * 3C 66B 10 10 M sun BBH @ a distance of 20 Mpc 10 9 M sun BBH @ a distance of 20 Mpc SMBH Background * OJ287

15 Detection vs Limits A single pulsar can place limits on the existence of G-waves Plot thanks to George Hobbs

16 The Stochastic Background h c (f) = A f   gw (f) = (2  2 /3 H 0 2 ) f 2 h c (f) 2 Super-massive Black Holes:  = -2/3 A = 10 -15 - 10 -14 yrs -2/3 Characterized by its “Characterictic Strain” Spectrum: Jaffe & Backer (2002) Wyithe & Lobe (2002) Enoki, Inoue, Nagashima, Sugiyama (2004) For Cosmic Strings:  = -7/6 A= 10 -21 - 10 -15 yrs -7/6 Damour & Vilenkin (2005)

17 The Stochastic Background The best limits on the background are due to pulsar timing. For the case where  gw (f) is assumed to be a constant (  =-1): Kaspi et al (1994) report  gw h 2 < 6  10 -8 (95% confidence) McHugh et al. (1996) report  gw h 2 < 9.3  10 -8 Frequentist Analysis using Monte-Carlo simulations Yield  gw h 2 < 1.2  10 -7

18 The Stochastic Background The Parkes Pulsar Timing Array Project Goal: Time 20 pulsars with 100 nano-second residual RMS over 5 years Current Status Timing 20 pulsars for 2 years, 5 currently have an RMS < 300 ns Combining this data with the Kaspi et al data yields:  = -1 : A<4  10 -15 yrs - 1  gw h 2 < 8.8  10 -9  = -2/3 : A<6.5  10 -15 yrs -2/3  gw (1/20 yrs)h 2 < 3.0  10 -9  = -7/6 : A<2.2  10 -15 yrs -7/6  gw (1/20 yrs)h 2 < 6.9  10 -9

19 The Stochastic Background With the SKA: 40 pulsars, 10 ns RMS, 10 years  = -1 : A<3.6  10 -17  gw h 2 < 6.8  10 -13  = -2/3 : A<6.0  10 -17  gw (1/10 yrs)h^2 < 4.0  10 -13  = -7/6 : A<2.0  10 -17  gw (1/10 yrs)h^2 < 2.1  10 -13

20 The Stochastic Background A Dream, or almost reality with SKA: 40 pulsars, 1 ns RMS, 20 years  = -2/3 : A<1.0  10 -18  gw (1/10 yrs)h^2 < 1.0  10 -16 The expected background due to white dwarf binaries lies in the range of A = 10 -18 - 10 -17 ! (Phinney (2001)) Individual 10 8 solar mass black hole binaries out to ~100 Mpc. Individual 10 9 solar mass black hole binaries out to ~1 Gpc

21 The timing residuals for a stochastic background This is the same for all pulsars. This depends on the pulsar. The induced residuals for different pulsars will be correlated.

22 Two-point correlation Two basic techniques Spherical Harmonic Decomposition Hellings & Downs 1983 Jenet, Hobbs, Lee, & Manchester 2005 Jaffe & Backer 2002

23 The Expected Correlation Function Assuming the G-wave background is isotropic:

24 The Expected Correlation Function

25 How to detect the Background For a set of N p pulsars, calculate all the possible correlations:

26 How to detect the Background

27

28 Search for the presence of  (  ) in C(  ):

29 How to detect the Background The expected value of  is given by: In the absence of a correlation,  will be Gaussianly distributed with:

30 How to detect the Background The significance of a measured correlation is given by:

31 Single Pulsar Limit (1  s, 7 years) Expected Regime For a background of SMBH binaries: h c = A f -2/3 20 pulsars.

32 Single Pulsar Limit (1  s, 7 years) 1  s, 1 year Expected Regime For a background of SMBH binaries: h c = A f -2/3 20 pulsars.

33 Single Pulsar Limit (1  s, 7 years) 1  s, 1 year (Current ability) Expected Regime.1  s 5 years For a background of SMBH binaries: h c = A f -2/3 20 pulsars.

34 Single Pulsar Limit (1  s, 7 years) 1  s, 1 year (Current ability) Expected Regime.1  s 5 years.1  s 10 years For a background of SMBH binaries: h c = A f -2/3 20 pulsars.

35 Single Pulsar Limit (1  s, 7 years) 1  s, 1 year (Current ability) Expected Regime.1  s 5 years.1  s 10 years SKA 10 ns 5 years 40 pulsars h c = A f -2/3 Detection SNR for a given level of the SMBH background Using 20 pulsars

36 Graviton Mass Current solar system limits place m g < 4.4 10 -22 eV  2 = k 2 + (2  m g /h) 2 c = 1/ (4 months) Detecting 5 year period G-waves reduces the upper bound on the graviton mass by a factor of 15. By comparing E&M and G-wave measurements, LISA is expected to make a 3-5 times improvement using LMXRB’s and perhaps up to 10 times better using Helium Cataclismic Variables. (Cutler et al. 2002)

37 Radio pulsars can directly detect gravitational waves –R = h/  s, 100 ns (current), 10 ns (SKA) What can we learn? –Is GR correct? SKA will allow a high SNR measurement of the residual correlation function -> Test polarization properties of G-waves Detection implies best limit of Graviton Mass (15-30 x) –The spectrum of the background set by the astrophysics of the source. For SMBHs : Rate, Mass, Distribution (Help LISA?) Current Limits –For SMBH, A<6.5  10 -15 or  gw (1/20 yrs)h 2 < 3.0  10 -9 SKA Limits –For SMBH, A<6.0  10 -17 or  gw (1/10 yrs)h 2 < 4.0  10 -13 –Dreamland: A<1.0  10 -18 or  gw (1/10 yrs)h 2 < 1.0  10 -16 Individual 10 8 solar mass black hole binaries out to ~100 Mpc. Individual 10 9 solar mass black hole binaries out to ~1 Gpc

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