pierre binétruy , apc, paris
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Overview of LISA signals. Pierre Binétruy , APC, Paris. Gravitational waves , New frontier , Seoul, 17 January 2013. LISA has become a programme rather than a mission:. LISA Pathfinder « classic » LISA now turned into « evolved » LISA or eLISA in Europe - PowerPoint PPT PresentationTRANSCRIPT
Pierre Binétruy, APC, Paris
Overview of LISA signals
Gravitational waves, New frontier, Seoul, 17 January 2013
LISA has become a programme rather than a mission:
• LISA Pathfinder
• « classic » LISA now turned into « evolved » LISA or eLISA in Europe
• post-LISA missions considered in Japan (DECIGO), China, …
Meanwhile, some progress has been made regarding the science of LISA
• Very significant progress these last years in data analysis methods thanks tothe Mock LISA Data Challenge
• Scientific breakthrough in numerical relativity with the computation of the signal due to the coalescence of two black holes (« grand challenge » of the 1990s)
• January 2011: ESA abandons a joint mission with NASA• NGO (New Gravitational wave Observatory) proposed for selection as L1 mission(together with the X-ray mission ATHENA and the JUICE mission to the moons of Jupiter)• May 2012: JUICE mission selected as L1• June 2012: ESA changes the selection process of L missions and announces a call in 2013/2014• September 2012: ESA Member States launch the eLISA consortium
The LISA program in Europe has undergone a series of important reorientations since 2010:
LISA redefinition study (2011): the way to eLISA/NGO
Boundary conditions:• ESA-only mission• cost cap for ESA cost at 850 M€• member state contribution at around 200M€
Some guiding principles adopted to redefine the LISA mission NGO:
• Keep the same principle of measurement and the same payload concept• Depart as little as possible from LISAPathfinder• Optimise the orbit and the launcher: minimize the mass• Simplify the payload
• Suppression of one of the arms of the triangle: mother-daughter configuration• Reduction of the arms from 5 Mkm to 1 Mkm• New orbit closer to Earth (drift away)• inertial sensor identical to LISAPathfinder• nominal mission lifetime: 2 yrs (ext. to 5 yrs)
Solutions adopted:
See LISA session on Friday (S. Vitale, H. Halloin,…)
NGO/eLISA vs classic LISA sensitivity
Science of NGO
Very significant work to identify the potential of possible NGO missions
Task force, with strong US participation to undertake simulations for each possible mission.
The science of eLISA-NGO
Ultra-compact binaries
Provides the «verification binaries » i.e. guaranteed sources of gravitational waves
Detached Double White Dwarf binary Interacting White Dwarf-Neutron Star binary
Out of the 50 known ultra-compact binaries, 8 should be detected in a few weeks to months and could be used to check the performance of the instrument.
By the time of the launch, several tens should be known.
Verification binaries
other binaries
eLISA will detect about 3000 WD binaries individually. Most have orbital periods between 5 and 10 minutesand have experienced at least one common-envelope phase, which can thus be tested.
Tidal distortion of a primary white dwarf
Lightcurve of SDSS J0651+28
eLISA will constrain the physics of tides in WD and mass transfer stability
Strain amplitude
Thus the measurement of h, f and f will provide a determination of distance D and chirp mass M.
eLISA will measure the sky position and distance of several hundred binaries, constraining the mass distribution in the Galaxy. For several hundred sources, it will determine the orbital inclination to better than 10°, allowingto test if they are statistically aligned with the Galactic disk.
The millions of ultra-compact binaries that will not beindividually detected will form a detectable foreground from which the global properties of the whole population can be determined.
.
extragalactic binary confusion noise
Massive black holes
There seems to exist a close connection between galaxies and their central black hole
which leads to think that they evolved jointly
« merger tree history »
M= 104to105M
M= 106to107M
courtesy A. Petiteau
Direct collapse Pop III remnants
NGO will allow to study black holes of mass 104 à 105 Mup to redshifts 15 à 20
NGO will allow to observe individually the coalescence of two massive black holes resulting from the collision of their host galaxies, passing through the « inspiral », « merger » and « ringdown » phases.
Test of the strong gravity regime
Plunge Merger Ringdown
GR: postNewtonian approximation
GR: numerical relativity
BH perturbation theory
LGW = 1023 L
several quasinormalmodes observed
A. Sesana @ LISA Symposium
Parameter estimation: Fischer matrix results
EMRI (Extreme Mass Ratio Inspiral)
Gravitational waves produced by massive objects (mass 10 to 100 M) falling into the horizon of a supermassive black hole allow to identify in a unique way thegeometry of space-time, to identify the characteristics of the black hole and toverify the predictions of GR.
Stellar-mass BH capture by a massive BH: dozens per year to z~0.7.
We have measured the mass of the GC BH using a few stars and with at most 1 orbit each, still far from horizon.
Imagine the accuracy when we have 105 orbits very close to horizon! GRACE/GOCE for massive BHs.
– Prove horizon exists.
– Test the no-hair theorem to 1%.
– Measure masses of holes to 0.1%, spin of central BH to 0.001.
– Population studies of central and cluster BHs.
– Find IMBHs: captures of 103 Mo BHs.
Confronting General Relativity
• A Kerr black hole is characterized by its mass and spin: detecting two or more quasinormal modes (2 parameters for each normal mode) in the ringdown phase will allow to check that the object is described only by 2 independent numbers.
No hair hypothesis
• EMRI will allow to do precise geodesy and again to check that the mass, spin and quadrupole moment of the central object are consistent with Kerr geometry:
Define mass moments Ml and mass-current multipole moments Sl (a S/M Kerr spin parameter)≣
Ml + iSl = (ia)l M M⇒ 0 = M, S1 = a M, quadrupole moment M2=-a2 M =-S2/M, …
With SNR of 30, ΔM0 /M and ΔS1 /M2 are of order 10-3 to 10-4, while ΔM2/ M3 10∼ -2 to 10-4
Graviton mass
eLISA will be able to set an upper limit on the graviton that is four orders of magnitude better than theexisting 4.10-22 eV.
Barack Cutler gr-qc/0612029
☺
Cosmological backgrounds
cosmic strings
In the mother-daughter configuration,loss of Sagnac mode which allowed to « dig » into the sensitivity curve
M
d
d
Bender, Hogan astro-ph/0104266
See also Littenberg, Cornish 1008.1577[gr-qc]
Still possible to detect stochastic backgrounds if they havea frequency dependence different from the background.
Hence effort to understand not only the amplitude of cosmological background but also the nature of theirfrequency dependence and how generic it is.
☺
First order phase transition
nucleation of true vacuum bubblesinside the false vacuum
Collision of bubbles and (MHD) turbulence production of gravitational waves
The Terascale region(E TeV to 10∼ 4 TeV)lies precisely in the LISA frequency window
It remains to be seen whether this applies to the electroweak phase transition, given the results on the Higgs.
Large loop scenario (at production, the size L of loops is a fraction of the horizon L = α dH ≈ αt)
Small loop scenario (α = 50 Gμ ε, ε << 1)
Background induced by cosmic or fundamental strings
parameter is string tension μ, or rather GNμ.
Towards a multi-wavelength analysis?
VIRGO
aVIRGO
See P.B., A. Bohe, J.-F. Dufaux and C. Caprini 1201.0983
Using MBH coalescence to do cosmography (e.g. measure the equation of state of dark energy
Key parameter : chirp mass M = (m1 m2)3/5
(m1 + m2)1/5
Amplitude of the gravitational wave in the inspiral phase:
h(t) = F (angles) cos (t) M(z)5/3 f(t)2/3
dL
Luminosity distance poorly known in the case of LISA, worse for eLISA
~ 10 arcmin 1 HzSNR fGW
(z) (1+z)
frequency f(t) = d/2dt
B. Schutz
When both a measure of the direction and of the redshift are allowed
dL/dL
0.5%
Holz and Hughes
But beware of gravitational lensing!delensing methods?
Can one identify the host galaxy (and thus z)?
Use subdominant signal harmonics () to narrow the LISA window
Enforce statistical consistency with cosmological parameter determination for all possible hosts
Broeck, Trias, Sathyaprakash, Sintes 1001.3099
Petiteau, Babak, Sesana 1102.0769
Science NGO LISA
Galactic binaries Expected: about 3000Verification binaries: > 8
Expected: about 10 000Verfication binaries: > 20
Astrophysical BH mergers Expected rate: 10 to 100/yrExpected number (2yr mission):20 to 200
Expected rate: 10 to 1000/yrExpected number (5yr mission): 50 to 5000
Extreme Mass Ratio Inspiral Expected rate: 1 to 100/yrExpected number (2yr): 10 to 20
Expected rate: 10 to 1000/yrExpected number (5yr): a few 10s
Testing GR Capability of observing 50% of all z≈2 coalescing binary systems consisting of objects with masses between 105 and 106 M
Capability of observing 50% of all z≈2 coalescing binary systems consisting of objects with masses between 105 and 106 M
Cosmology Capability of detecting gravitational wave backgrounds from cosmic strings or phase transitions
Capability of detecting gravitational wave backgrounds from cosmic strings or phase transitionsDE equation of state parameter measured through BH mergers
Massive BHs (105--107 Mo) Measurement of mass at z = 1 to ±0.1%, spin a/M to ±0.01. Mass function, central cluster of black holes in ordinary galaxies to z = 0.5.
Evolution of the Cosmic Web at high redshift Observation of objects before re-ionisation: BH mergers at z >> 10. Testing models of how massive BHs formed and evolved from seeds.
Compact WD binaries in the Galaxy Catalogue ~2000 new white-dwarf binary systems in the Galaxy. Precise masses & distances for dozens of systems + all short-period NS-BHs.
Fundamental physics and testing GR Ultra-strong GR: Prove horizon exists; test no-hair theorem, cosmic censorship;
search for scalar gravitational fields, other GR breakdowns. Fundamental physics: look for cosmic GW background, test the order of the
electroweak phase transition, search for cosmic strings.
To conclude, list presented by B. Schutz at the L1 selection:
ESA Space Science Advisory Committee recommendations
NGO unanimously recognized first from point of view of • scientific importance, • strategic value, • strategic importance for Europe.
earliest launch date for NGO: 2025 to 2028
eLISA Science Working Groups
• ultra-compact binaries• astrophysical black holes• EMRI• cosmology: backgrounds, cosmography, formation of large structures• tests of fundamental laws • data analysis• science of measurement
eLISA webite
http://www.elisa-ngo.org/