Post on 23-May-2020
Florent RobinetLaboratoire de l’Accélérateur Linéaire robinet@lal.in2p3.fr
Detection of gravitational-wave signals from binary black hole mergers
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The second one is usually better than the first one!
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GW151226
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GW151226
Rewind
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On Sep. 14, 2015, both LIGO detectors detected the gravitational-wave signal produced by the coalescence of a binary black hole system:
GW150914
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Inspiral Merger Ringdown
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0.25 0.50 0.75 1.000.00
LIGO - LivingstonLIGO - Livingston
LIGO - HanfordLIGO - Hanford
0.25 0.50 0.75 1.000.00
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Gμν=Rμ ν−12
gμ ν R=8 πG
c4 T μν=0
Add a small perturbation to the Minkowski metric:
gμν=ημν+hμν |hμ ν|≪1
– obeys a plane-wave equation– the wave propagates at the speed of light– 2 degrees of freedom: and
h
h+ hx
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Gravitational waves
L±Δ L
h=2Δ LL
h+
hx
Gμν=Rμ ν−12
gμ ν R=8 πG
c4 T μν=0
Add a small perturbation to the Minkowski metric:
gμν=ημν+hμν |hμ ν|≪1
– obeys a plane-wave equation– the wave propagates at the speed of light– 2 degrees of freedom: and
h
h+ hx
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Gravitational waves
L±Δ L
h=2Δ LL
h+
hx
When they propagate, gravitational waves– do not interact with matter– are attenuated by 1/r
→ Gravitational waves are the perfect probe! → BUT... h~10–21
Gravitational wave detectors
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Poutput (t)=P input
2[1+C cos (δ ϕ( t))]
Poutput (t)≃Pinput
2[1+C cos(δϕOP)−C sin(δ ϕOP)×δϕGW (t )]
δϕ(t )=δϕOP+δϕGW
Michelson interferometer
L
→ A gravitational wave is detected as a power variation
Gravitational wave detectorsLIGOsuspensions
Virgosuspensions
O(100 kW)
Kilometer sca
leSuspended test masses
Virgo interferometer
Detector sensitivityThe detector's sensitivity: amplitude spectrum densityThe detector's sensitivity: amplitude spectrum density
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Fundamental noises:– f < 10 Hz seismic noise→– 10 Hz < f < 200 Hz thermal noise→– f > 200 Hz quantum shot noise→
+ technical noise (environment, scattered light, control...)
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LIGO Livingston, USALIGO Livingston, USA
LIGO Hanford, USALIGO Hanford, USA Virgo Pisa, ItalyVirgo Pisa, Italy
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Scientific runs
02 03 04 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 21
S5 S6 O1
VSR1 VSR2VSR3
VSR4 VSR5
O2 O3
LIGO
Virgo VSR6
K1
KAGRA
LIGO
Indi
a
I1
?
?
?
initial enhanced advanced
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LIGO sensitivity
2010 (enhanced)
2015 (advanced, O1)
2018 (advanced, O3)
2020+2020+
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LIGO O1 run: Sep 12, 2015 Jan 19, 2016→
GW150914analysis
weeks
~ 50 days ofcoincident time
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h(t) data are transferred to computing centers (< 1 s)where low-latency searches are conducted
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h(t) data are transferred to computing centers (< 1 s)where low-latency searches are conducted
Hannover:– unmodeled burst search (cWB)
Caltech:– CBC modeled search (GstLAL)– unmodeled burst search (olib)
Virgo:– CBC-modeled search (MBTA)
Online searchesGW151226
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Online searchesGW151226
Modeled search
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Online searchesGW151226
~ 950 yr-1
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Online searchesGW151226
Detected after ~ 1 min
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Online searchesGW151226
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Online searches
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+9 min
+12 min
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0.50 1.00 1.50 2.000.00
LIGO - LivingstonLIGO - Livingston
LIGO - HanfordLIGO - Hanford
0.50 1.00 1.50 2.000.00
GW150914
0.50 1.00 1.50 2.000.00
LIGO - LivingstonLIGO - Livingston
LIGO - HanfordLIGO - Hanford
0.50 1.00 1.50 2.000.00
0.50 1.00 1.50 2.000.00
LIGO - LivingstonLIGO - Livingston
LIGO - HanfordLIGO - Hanford
0.50 1.00 1.50 2.000.00
GW151226GW150914
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Modeled search (offline)Theoretical input:Theoretical input:– 90s: CBC PN waveforms (Blanchet, Iyer, Damour, Deruelle, Will, Wiseman, …)– 00s: CBC Effective One Body “EOB” (Damour, Buonanno)– 06: BBH numerical simulation (Pretorius, Baker, Loustos, Campanelli)
The intrinsic waveform parameters:The intrinsic waveform parameters:– Masses:
– Spins and orbital angular momentum:
The waveform models used for the search:The waveform models used for the search:– Inspiral, PN3.5 for – Inspiral/Merger/Ringdown EOB + numerical relativity for– Spins and orbital angular momentum are aligned Template bank match-filtering technique→Template bank match-filtering technique→
M tot<4 M sun
M tot>4 M sun
S⃗ tot=S⃗1+ S⃗2+ J⃗
M tot=M1+M 2
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Modeled search (offline)
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2 modeled searches are conducted offline: pyCBC and GstLAL
They use the same template bank but they differ when it comes to:– estimate the background– rank the events
Modeled search
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Full O1 analysis, final calibration
Iterative process → remove the loudest event (GW) from background before
estimating the second-loudest event significance
pyCBC GstLAL
Modeled search
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Full O1 analysis, final calibration
Iterative process → remove the loudest event (GW) from background before
estimating the second-loudest event significance
pyCBC GstLAL
Modeled search
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Full O1 analysis, final calibration
pyCBCGW151226
● SNR = 13.0
● Significance > 5.3 σ
Monitoring noise200,000 auxiliary channels are used to monitor the instrument– environmental sensors– detector sub-systems– detector control
Noise injection campaigns are conducted to identify the detector's response to different noise stimulation
Multiple transient noises were identified during the run → Anthropogenic noise → Earthquakes → Radio-frequency modulation …→
Option #1: fix the detectorOption #2: remove transient
events in the data
No indication of external disturbanceat the time of the event
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Parameter estimationBayesian inference + MCMC analyses using accurate waveform models
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Parameter estimation
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Black hole population
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Source location
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DL=420−180+150 Mpc
DL=440−190+180 Mpc
z=0.09−0.04+0.03
z=0.09−0.04+0.03
90% credible region for sky location: → GW150914 = 230 deg2
→ GW151226 = 850 deg2
GW150914:GW151226:
Event rate
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– Simulated signals with parameters drawn from astrophysical populations– Noise distribution from CBC searches
p(m1 ,m2)∝m1−1m2
−1
underestimates the rate
p(m1)∝m1−2.35
overestimates the rate
p(m2)=cte
R=9−240Gpc−3 yr−1
Detection rate
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False-alarm rate = 1 / 100 yearsN>10N>35
N>70
Waveform
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Testing GR
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Opportunity to study GR in a strong-field regime (update GW150914 results)Opportunity to study GR in a strong-field regime (update GW150914 results)Test #1 signal waveform/GR consistency: residual compatible with noise→
Test #2 BBH parameter consistency before/after merger: excellent→
Test #3 deviation from PN waveforms: constraints on PN coefficients→
Test #4 consistency with the least-damped quasi-normal-mode of the remnant black hole→
Test #5 theory with massive graviton: best constraints on the graviton mass→
Upper bounds onthe fractional deviation in PN coefficients
Conclusions & outlook → 22ndnd gravitational-wave event was detected gravitational-wave event was detected :
– lower masses than GW150914 (compatible with known X-ray binaries)– at least one companion black hole is spinning– population of binary black holes
→ Observations consistent with GR
→ Gravitational-wave events can be detected with a minute latency: first step in GW astronomy
The future is promisingThe future is promising
→ Additional O1 results will be released soon (CBC, burst sources, pulsars)
→ Improved detector sensitivity
→ More events: population, new types of sources (supernovae, neutron stars)
→ New instruments will join the network (Virgo this year!)
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THANK YOUTHANK YOU
Event significanceThe background of a gravitational-wave search is estimated using the time-slide techniqueAssumption = uncorrelated noise between detectors
Coincidence time window
+δ t
True experiment = noise + signal
List of background events
Fake experiment = noise only
List of candidates
time time
A very large number of fake experiments can be simulatedusing multiple offsets
→ background estimated using a fake experiment of O(100,000 years)
Hanford
Livingston