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Imagining the Future. What can we do about the Quantum Noise Limit in Gravitational-wave Detectors?. Nergis Mavalvala Penn State October 2004. Quantum Noise in Optical Measurements. Measurement process Interaction of light with test mass Counting signal photons with a photodetector
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Imagining the Future What can we do about the Quantum Noise Limit in Gravitational-wave Detectors? Nergis MavalvalaPenn StateOctober 2004
Quantum Noise in Optical Measurements • Measurement process • Interaction of light with test mass • Counting signal photons with a photodetector • Noise in measurement process • Poissonian statistics of force on test mass due to photons radiation pressure noise (RPN) (amplitude fluctuations) • Poissonian statistics of counting the photons shot noise (SN) (phase fluctuations)
Limiting Noise Sources: Optical Noise • Shot Noise • Uncertainty in number of photons detected a • Higher circulating power Pbsa low optical losses • Frequency dependence a light (GW signal) storage time in the interferometer • Radiation Pressure Noise • Photons impart momentum to cavity mirrorsFluctuations in number of photons a • Lower power, Pbs • Frequency dependence a response of mass to forces Optimal input power depends on frequency
uncorrelated 0.1 MW 1 MW 10 MW Free particle SQL
In the presence of correlations • Heisenberg uncertainty principle in spectral domain • Follows that
Quantum LIGO I LIGO II Test mass thermal Suspension thermal Seismic A Quantum Limited Interferometer
How will we get there? • Seismic noise • Active isolation system • Mirrors suspended as fourth (!!) stage of quadruple pendulums • Thermal noise • Suspension fused quartz; ribbons • Test mass higher mechanical Q material, e.g. sapphire; more massive (40 kg) • Optical noise • Input laser power increase to ~200 W • Optimize interferometer response signal recycling
Cavity forms compound output coupler with complex reflectivity. Peak response tuned by changing position of SRM ℓ Reflects GW photons back into interferometer to accrue more phase SignalRecycling Signal-recycled Interferometer 800 kW 125 W signal
Advanced LIGO SensitivityImproved and Tunable broadband detunednarrowband thermal noise
GW signal in the phase quadrature Not true for all interferometer configurations Detuned signal recycled interferometer GW signal in both quadratures Orient squeezed state to reduce noise in phase quadrature X- X- X- X+ X- X+ X+ X+ Squeezed input vacuum state in Michelson Interferometer
Squeezing produced by back-action force of fluctuating radiation pressure on mirrors a2 b2 a1 ba f b1 Back Action Produces Squeezing • Vacuum state enters anti-symmetric port • Amplitude fluctuations of input state drive mirror position • Mirror motion imposes those amplitude fluctuations onto phase of output field
Coupling coefficient k converts Da1 to Db2 • k and squeeze angle f depends on I0, fcav, losses, f a b Conventional Interferometer with Arm Cavities Amplitude b1 = a1 Phase b2 = -k a1 + a2 + h Radiation Pressure Shot Noise
Optimal Squeeze Angle • If we squeeze a2 • Shot noise is reduced at high frequencies BUT • Radiation pressure noise at low frequencies is increased • If we could squeeze -k a1+a2 instead • Could reduce the noise at all frequencies • “Squeeze angle” describes the quadrature being squeezed
Realizing a frequency-dependent squeeze angle filter cavities • Filter cavities • Difficulties • Low losses • Highly detuned • Multiple cavities • Conventional interferometers • Kimble, Levin, Matsko, Thorne, and Vyatchanin, Phys. Rev. D 65, 022002 (2001). • Signal tuned interferometers • Harms, Chen, Chelkowski, Franzen, Vahlbruch, Danzmann, and Schnabel, gr-qc/0303066 (2003).
Squeezing – the ubiquitous fix? • All interferometer configurations can benefit from squeezing • Radiation pressure noise can be removed from readout in certain cases • Shot noise limit only improved by more power (yikes!) or squeezing (eek!) • Reduction in shot noise by squeezing can allow for reduction in circulating power (for the same sensitivity) – important for power-handling
X- X+ Sub-quantum-limited interferometer Quantum correlations(Buonanno and Chen) Input squeezing
Squeezed vacuum • Requirements • Squeezing at low frequencies (within GW band) • Frequency-dependent squeeze angle • Increased levels of squeezing • Generation methods • Non-linear optical media (c(2) and c(3) non-linearites) crystal-based squeezing (recent progress at ANU and MIT) • Radiation pressure effects in interferometers ponderomotive squeezing (in design & construction phase) • Challenges • Frequency-dependence filter cavities • Amplitude filters • Squeeze angle rotation filters • Low-loss optical systems
Vacuum seeded OPO ANU group quant-ph/0405137
The principle • A “tabletop” interferometer to generate squeezed light as an alternative nonlinear optical media • Use radiation pressure as the squeezing mechanism • Relies on intrinsic quantum physics of optical field-mechanical oscillator correlations • Squeezing produced even when the sensitivity is far worse than the SQL • Due to noise suppression a la optical springs
Key ingredients • High circulating laser power • 10 kW • High-finesse cavities • 25000 • Light, low-noise mechanical oscillator mirror • 1 gm with 1 Hz resonant frequency • Optical spring • Detuned arm cavities
Optical Springs • Modify test mass dynamics • Suppress displacement noise (compared to free mass case) • Why not use a mechanical spring? • Thermal noise • Connect low-frequency mechanical oscillator to (nearly) noiseless optical spring
Speed meters • Principle weakly coupled oscillators • Energy sloshes between the oscillators • p phase shift after one slosh cycle • Driving one oscillator excites the other
homodyne detection Implementation of a speed meter • Position signal from arm cavity enters “sloshing” cavity • Exits “sloshing” cavity with p phase shift • Re-enters arm cavity and cancels position signal • Remaining signal relative velocity of test masses sloshing cavity Purdue and Chen, Phys. Rev. D66, 122004 (2002)
Intra-cavity readouts • Non-classical states of light exist inside cavities (ponderomotive squeezing) • Probe those intra-cavity squeezed fields Braginsky et al., Phys. Lett. A255, (1999)
Optical Bars and Optical Levers • Couple a second “probe” mass to the test mass • Probe mass does not interact with the strong light field in the cavity • Analogous to mechanical lever with advantage in the ratio of unequal lever arms Braginsky et al., Phys. Lett. A232, (1997)
White Light Interferometers • Broadband antenna response • Make cavity longer for longer wavelengths L0 b a L0 Guido Muller
LASER All-reflective Interferometers • Higher power-handling capability • Grating beamsplitters Peter Byersdorf
Technologies needed • Low-noise high-power lasers • What wavelength? • Low absorption and scatter loss optics • Low loss diffraction gratings • High non-linearity optical materials • High quantum efficiency photodetection • Low mechanical loss oscillators • With optical spring effect, oooh
Next generation – quantum noise limited • Squeezing being pursued on two fronts • Nonlinear optical media • Back-action induced correlations • Other Quantum Non-Demolition techniques • Evade measurement back-action by measuring of an observable that does not effect a later measurement • Speed meters (Caltech, Moscow, ANU) • Optical bars and levers (Moscow) • Correlating SN and RPN quadratures • Variational readout • Power handling • All-reflective • Quadrature squeezing
Imagining the Future What can we do about the Quantum Noise Limit in Gravitational-wave Detectors? Plenty!