Broadband reduction of quantum radiation pressure noise via squeezed light injection
Min Jet Yap, Jonathan Cripe, Georgia L. Mansell, Terry G. McRae, Robert L. Ward, Bram J.J. Slagmolen, Daniel A. Shaddock, Paula Heu, David Follman, Garrett D. Cole, David E. McClelland, Thomas Corbitt
BBroadband reduction of quantum radiation pressure noise via squeezed light injection
Min Jet Yap ∗ , Jonathan Cripe , Georgia L. Mansell , , Terry G. McRae , Robert L. Ward , Bram J.J. Slagmolen ,Daniel A. Shaddock , Paula Heu , David Follman , Garrett D. Cole , , David E. McClelland , and Thomas Corbitt OzGrav, Department of Quantum Science,Research School of Physics and Engineering,Australian National University, Acton,Australian Capital Territory 2601, Australia Department of Physics & Astronomy,Louisiana State University,Baton Rouge, LA 70803, USA LIGO Hanford Observatory, P.O. Box 159,Richland, Washington 99352, USA Massachusetts Institute of Technology,Cambridge, Massachusetts 02139, USA Crystalline Mirror Solutions LLC and GmbH,Santa Barbara, CA, 93101 and 1060 Vienna, Austria Vienna Center for Quantum Science and Technology (VCQ),Faculty of Physics, University of Vienna,A-1090 Vienna, Austria ∗ Corresponding author: [email protected]
We present the reduction and manipulation of quantum radiation pressure noise (QRPN) in anoptomechanical cavity with the injection of squeezed light. The optomechanical system consists ofa high-reflectivity single-crystal microresonator which serves as one mirror of a Fabry-Perot cavity.The experiment is performed at room temperature and is QRPN dominated between 10 kHz and 50kHz, frequencies relevant to gravitational wave observatories. We observed a reduction of 1.2 dB inthe measurement noise floor with the injection of amplitude squeezed light generated from a below-threshold degenerate optical parametric oscillator. This experiment is a crucial step in realizingthe reduction of QRPN for future interferometric gravitational wave detectors and improving theirsensitivity.
INTRODUCTION
Effects due to quantum mechanics are becoming signif-icantly important in the precision measurement of con-tinuous variables. As the precision of an observable in-creases, a back action effect governed by the Heisenberguncertainty principle results in a increased uncertainlyin the conjugate variable. This can be observed in op-tomechanical systems where the mechanical motion of anoscillator is coupled to an optical cavity mode, such asgravitational wave (GW) interferometers. Increasing thelaser drive power lowers the photon counting uncertaintyand reduces shot noise. The increased power, however,results in an increase in the back action effect in the formof quantum radiation pressure noise (QRPN). When GW detectors such as the Advanced Laser In-terferometer Gravitational Wave Observatory (LIGO), Advanced Virgo, and KAGRA, reach their design sen-sitivity, quantum noise will be the dominant noise sourceacross most of the detection band, with QRPN dominat-ing at low frequencies between 10 Hz and 100 Hz. Thisquantum noise arises from vacuum fluctuations whichcouple to the interferometer via the dark readout port.The injection of squeezed vacuum into the interferometerdark port allows the quantum noise to be manipulated. Squeezed injection has been demonstrated to reduce theshot noise level of previous generation of GW detec-tors at both LIGO Hanford, and GEO-600, and is currently being implemented in current GW detectors.Other QRPN mitigation techniques such as variationalreadout, conditional squeezing, and the use of nega-tive mass systems, have also been proposed to improvethe low frequency sensitivity of GW detectors.As GW detectors approach their design sensitivity, itis important study the effects of QRPN to help decidewhich QRPN reduction technique to employ. The ef-fects and manipulation of QRPN has only been recentlyobserved on tabletop experiments as it is typicallydominated by mechanical thermal noise and other clas-sical noise sources such as seismic vibrations. However,many of the previous observations of QRPN were madein high frequencies (MHz-GHz), around the mechanicalresonance, and thus are not fully applicable for GW de-tectors which will be QRPN dominated over a large fre-quency band away from the mechanical resonance. Ameasurement of QRPN away from the mechanical reso-nance of the oscillator and at frequencies in the GW bandhas only recently been performed. Here, we investigate the injection of squeezed light ina QRPN limited optomechanical system, and report thereduction and manipulation of broadband QRPN awayfrom the mechanical resonance and at frequencies rele-vant to gravitational wave detectors. Our experimentutilizes low-loss single-crystal microresonators with lowstructural noise property for the effects of QRPN to beobserved at room temperature. a r X i v : . [ qu a n t - ph ] D ec THE EXPERIMENT
Figure 1 shows the schematic of the experiment. Theoptomechanical system is a Fabry-Perot cavity with amicro-mechanical oscillator as one of the end mirrors.The system is installed on a suspended breadboard in-side a vacuum chamber at 10 − Torr in order to pro-vide passive seismic and acoustic isolation. The microres-onator consist of a roughly 70- µ m diameter mirror padsuspended from a single crystal GaAs cantilever with athickness of 220-nm, width of 8- µ m, and a length of 55- µ m. The mirror pad is made up of 23 pairs of quarter-wave optical thickness GaAs/Al Ga As layers for atransmission of T = 250 ppm and exhibits both low opti-cal losses and a high mechanical quality factor.
Themicroresonator has a mass of 50 ng, a natural mechanicalfrequency of Ω m = 2 π ×
876 Hz, and a measured mechan-ical quality factor of Q m = 16000 at room temperature. The cavity has a length of slightly less than 1 cm, a fi-nesse of F = 13000 and linewidth (HWHM) of 2 π × The optical spring effect is stabilized bymonitoring the cavity reflection and transmission field,and providing active feedback around the optical springfrequency to the laser power and frequency via an electro-optic amplitude modulator (AM) and phase modulator(PM).
In the final measurement configuration, onlythe reflected light and PM feedback loop is used to lockthe cavity at a detuning of about 0.6 linewidths, withthe optical spring pushing the mechanical resonance fre-quency above 100 kHz.The squeezed vacuum state is generated from a sub-threshold degenerate optical parametric oscillator (OPO)via the parametric down conversion process. The OPO isa doubly resonant bow tie cavity with a nonlinear crys-tal made of periodically poled potassium titanyl phos-phate (PPKTP) embedded within the cavity. The OPOis pumped by light tapped from the main laser that hasbeen frequency-doubled to 532 nm via a second har-monic generation (SHG) cavity, and is kept on resonancewith the pump light via a Pound-Drever-Hall lockingscheme. Squeezed light is injected into the cavity bycombining the main laser field with a squeezed vacuumstate via an asymmetric 97:3 beamsplitter. Spatial modemismatch is filtered out by passing the combined fieldthrough a short optical fiber before the optomechanicalcavity. An intensity stabilization servo (ISS) is used tosuppress the main laser intensity noise down below shotnoise level.The control of the squeezed ellipse phase with re-spect to the main laser is achieved with a coherent lock-ing scheme which utilizes a coherent locking field (CLF) laser frequency shifted from the main laser by12.5 MHz. The frequency difference between the twolasers is maintained by up-converting a small portion ofthe CLF laser to 532 nm and phase locking the 25 MHzbeat note between the up-converted field and the OPOpump field. The unconverted (1064nm) CLF beam co-propagates with the squeezed vacuum field and is phaselocked with the main laser after the asymmetric beam-splitter at 12.5 MHz. Engaging both the CLF phase locksallows the squeezed ellipse to the track the phase of themain laser field. Rotation of the squeezed ellipse be-tween the amplitude and phase quadrature is achievedby changing the demodulation phase between the twoCLF phase locks.
RESULTS
Figure 2 shows the displacement spectral density mea-sured at the reflection port of the cavity with 220 mWof circulating power. The broad peak at 150 kHz is dueto the mechanical fundamental frequency being shiftedup by the optical spring effect. The dominant noisesource below 10 kHz is the thermal noise of the mi-croresonator which follows a structural damping modelbetween 200 Hz to 30 kHz, and falls off as 1 /f / com-pared to QRPN. With 220 mW of circulating power,QRPN is dominant noise source between 10 kHz and 50kHz. The excess thermal noise above 30 kHz is believedto be related to thermoelastic damping.The spectrum is calibrated by measuring the transferfunction from the main laser piezo to the cavity reflec-tion port. The laser piezo actuates on the main laser fre-quency and has been calibrated separately. The transferfunction measures the closed loop response of the system,and undoes the effect of both the electronic feedback andthe optical spring response. The optical spring effect isreintroduced in the spectrum by measuring separatelythe optical spring frequency and cavity detuning. A 11.2kHz dither tone on the cavity length is used to produce acalibration line, shown in the inset of Figure 3, to ensurethe calibration is constant between all the measurements.In order to manipulate the QRPN, bright squeezedlight is injected into the cavity, which affects the mea-sured displacement spectrum as shown in Figure 3. Withthe injection of amplitude squeezed light, we observe areduction of the total noise floor at frequencies whereQRPN is dominant, with a maximum reduction of 1.2dB at around 20 kHz. Even though thermal noise is thedominant noise source below 10 kHz, QRPN is still amajor contributor to the total noise and the reductionin noise due to squeezed light injection remains visiblebelow 2 kHz. By changing the relative phase betweenthe two CLF locks, we are able to rotate the squeezingellipse to produce phase squeezed light resulting in anincrease of the total noise by 12.6 dB at 20 kHz. The flatand broadband nature of the increase is indicative of thequantum noise being manipulated. Figure 4 shows the
MicroresonatorEnd MirrorPZT
PDM
Main Laser
PDL
AM SA
PM SAAM ISS
Spectrumanalyzer
SHG PM OPO PDGreen CLF PDRed CLF PD OPO feedback to cavity lengthRed CLF feedback to PZT mirrorGreen CLF feedback to laser frequency Single pass SHG
CLF Laser OPO
70 MHz Green BSSQZ BS
FIG. 1. Schematic of the experiment. The generated squeezed light is produced at the frequency of the main 1064 nm laser (redline). The OPO is pumped by light from the main laser that has been frequency-doubled to 532 nm (light green line) by a SHGcavity. The OPO is locked to the pump field via Pound-Drever-Hall locking with 70 MHz phase modulated (PM) sidebandsand the reflected field detected at OPO PD. The generated squeezed vacuum (dashed red) from the OPO is then recombinedwith the main laser field at a 97:3 beamsplitter to produce a bright squeezed field (dotted dash red) which is then injectedinto the in-vacuum optomechanical cavity. In order to control the squeezing quadrature of the bright field, a coherent lockingscheme was implemented that utilizes a Coherent Locking Field (CLF) laser, frequency shifted by 12.5 MHz from the mainlaser (orange line), which co-propagates with the squeezed field. The frequency difference between the two laser is maintainedby stabilizing the 25 MHz beat note at Green CLF PD. The squeezing quadrature of the bright field is stabilized by controllingthe beat note phase of the two lasers detected at Red CLF PD. Frequency (Hz) -18 -17 -16 D i s p l a c e m en t N o i s e ( m / H z / ) Measured SpectrumTotal noiseQuantum noiseThermal noise
FIG. 2. Displacement spectral density of the microresonatorwith a 150 kHz optical spring resonance. The dominant noisesources are thermal noise (orange trace), and quantum noise(yellow trace) which is dominated by QRPN below the op-tical spring resonance. The thermal noise measurement wastaken with low intracativity power, and closely follows a struc-tural damping model. The quantum noise trace also takesinto account the dark noise level of the photodetector. Thequadrature sum of the two noise sources (blue trace) is over-laid with the measured displacement spectrum (black trace)with no squeezed light injection. noise reduction and enhancement at 20 kHz and acrossthe measurement spectrum.The amount of observed reduction in noise is currentlylimited by the collective losses of the system, which de- Frequency [Hz] -17 -16 D i s p l a c e m en t no i s e [ m / H z / ] Total noise with no squeezingTotal noise with amplitude squeezingTotal noise with phase squeezing -17 kHz
FIG. 3. Displacement noise spectrum of the microresonatorwith the injection of squeezed light. Reference trace (black)is measured by tuning the OPO to its anti-resonance to en-sure no squeezed light is generated. Injection of amplitudesqueezed light (red) results in a maximum noise reduction of1.2 dB at 20 kHz. Rotating the squeezed ellipse to the phasequadrature (blue) increased the total noise of the system. In-set: 11.2 kHz calibration line used in the three measurements. grades the squeezed state by mixing it with uncorrelatedvacuum fields. These losses include the OPO cavity es-cape efficiency, optical propagation loss from the OPOto the photodetector, mode matching efficiency of thesqueezed field to the optomechanical cavity, and the pho-todiode quantum efficiency. The optical propagation losswas measured to be 47%, which was predominately dueto optical fiber launching efficiency, and diffraction lossesat the cantilever mirror. The OPO escape efficiency,
FIG. 4. Displacement noise spectrum as a function thesqueezing phase normalized to the reference spectrum at 20kHz and across the measurement frequency band. Horizon-tals lines unchanged with the squeezing phase corresponds tothe higher order mechanical modes of the microresonator. a measure of the the OPO out-coupling efficiency hada measured value of 97%, mode matching efficiency tothe optomechanical cavity was 80%, and the photodiodequantum efficiency was 97%. This resulted in a total lossefficiency of 40%, which is in agreement with the mea-sured amplitude and phase squeezing level.
CONCLUSION
We present the reduction of quantum radiation pres-sure noise of a microresonator far from the mechanical resonance frequency over a broad frequency range via theinjection of squeezed light. This provides useful insight inreducing the radiation pressure forces of future gravita-tional wave observatories in order to improve its sensitiv-ity and detection range. Moreover, a radiation pressurenoise limited optomechanical system provides a usefultestbed for other QRPN reduction proposals andquantum-enhanced displacement sensing. With the optomechanical system at room temperature,the standard quantum limit (SQL) is currently within afactor of five away, with the system predominately dom-inated by thermal noise. By cryogenically cooling thesystem, this paves the way in reaching the SQL, andmeasuring sub-SQL sensitivity with non-classical statesof light. ACKNOWLEDGEMENTS
This research was supported by the AustralianResearch Council under the ARC Centre of Excel-lence for Gravitational Wave Discovery, grand numberCE170100004. J.C and T.C are supported by the Na-tional Science Foundation grant PHY-1150531 and PHY-1806634. B.S. has been supported by ARC Future Fel-lowship FT130100329.— M. Aspelmeyer, T. J. Kippenberg, and F. Marquardt,“Cavity optomechanics,”
Rev. Mod. Phys. , vol. 86,pp. 1391–1452, Dec 2014. C. M. Caves, “Quantum-mechanical radiation-pressurefluctuations in an interferometer,”
Phys. Rev. Lett. , vol. 45,pp. 75–79, Jul 1980. V. B. Braginsky and A. B. Manukin,
Measurement of WeakForces in Physics Experiments . University of ChicagoPress, 6 1977. J. Aasi et al . (LIGO Scientific Collaboration), “AdvancedLIGO,”
Classical and Quantum Gravity , vol. 32, no. 7,p. 074001, 2015. F. Acernese et al . (VIRGO Collaboration), “AdvancedVirgo: a second-generation interferometric gravitationalwave detector,”
Classical and Quantum Gravity , vol. 32,no. 2, p. 024001, 2015. K. Somiya et al . (KAGRA Collaboration), “Detector con-figuration of KAGRAthe Japanese cryogenic gravitational-wave detector,”
Classical and Quantum Gravity , vol. 29, no. 12, p. 124007, 2012. C. M. Caves, “Quantum-mechanical noise in an interfer-ometer,”
Phys. Rev. D , vol. 23, pp. 1693–1708, Apr 1981. “Enhanced sensitivity of the ligo gravitational wave detec-tor by using squeezed states of light,” Nature Photonics ,vol. 7, pp. 613–619, Jul 2013. H. Grote, K. Danzmann, K. L. Dooley, R. Schnabel,J. Slutsky, and H. Vahlbruch, “First long-term applicationof squeezed states of light in a gravitational-wave observa-tory,”
Phys. Rev. Lett. , vol. 110, p. 181101, May 2013. H. J. Kimble, Y. Levin, A. B. Matsko, K. S. Thorne,and S. P. Vyatchanin, “Conversion of conventionalgravitational-wave interferometers into quantum nonde-molition interferometers by modifying their input and/oroutput optics,”
Phys. Rev. D , vol. 65, p. 022002, Dec 2001. Y. Ma, H. Miao, B. H. Pang, M. Evans, C. Zhao,J. Harms, R. Schnabel, and Y. Chen, “Proposal forgravitational-wave detection beyond the standard quan-tum limit through EPR entanglement,”
Nature Physics , vol. 13, pp. 776 EP –, 05 2017. F. Y. Khalili and E. S. Polzik, “Overcoming the standardquantum limit in gravitational wave detectors using spinsystems with a negative effective mass,”
Phys. Rev. Lett. ,vol. 121, p. 031101, Jul 2018. T. P. Purdy, R. W. Peterson, and C. A. Regal, “Obser-vation of radiation pressure shot noise on a macroscopicobject,”
Science , vol. 339, no. 6121, pp. 801–804, 2013. J. D. Teufel, F. Lecocq, and R. W. Simmonds, “Over-whelming thermomechanical motion with microwave ra-diation pressure shot noise,”
Phys. Rev. Lett. , vol. 116,p. 013602, Jan 2016. J. B. Clark, F. Lecocq, R. W. Simmonds, J. Aumentado,and J. D. Teufel, “Observation of strong radiation pressureforces from squeezed light on a mechanical oscillator,”
Na-ture Physics , vol. 12, Mar 2016. T. P. Purdy, K. E. Grutter, K. Srinivasan, and J. M. Tay-lor, “Quantum correlations from a room-temperature op-tomechanical cavity,”
Science , vol. 356, no. 6344, pp. 1265–1268, 2017. V. Sudhir, R. Schilling, S. A. Fedorov, H. Sch¨utz, D. J.Wilson, and T. J. Kippenberg, “Quantum correlationsof light from a room-temperature mechanical oscillator,”
Phys. Rev. X , vol. 7, p. 031055, Sep 2017. J. Cripe, N. Aggarwal, B. Lanza, A. Libson, R. Singh,P. Heu, D. Follman, G. D. Cole, N. Mavalvala, and T. Cor-bitt, “Observation of a room-temperature oscillator’s mo-tion dominated by quantum fluctuations over a broadaudio-frequency band,” 2018. G. D. Cole, S. Gr¨oblacher, K. Gugler, S. Gigan, and M. As-pelmeyer, “Monocrystalline Al x Ga − x As heterostructuresfor high-reflectivity high-q micromechanical resonators inthe megahertz regime,”
Applied Physics Letters , vol. 92,no. 26, p. 261108, 2008. G. D. Cole, “Cavity optomechanics with low-noise crys-talline mirrors,” in
Proc. SPIE 8458, Optics & Photon-ics, Optical Trapping and Optical Micromanipulation IX ,p. 845807, SPIE, August 2012. G. D. Cole, W. Zhang, M. J. Martin, J. Ye, and M. As-pelmeyer, “Tenfold reduction of brownian noise in high-reflectivity optical coatings,”
Nat Photon , vol. 7, pp. 644–650, Aug. 2013. G. D. Cole, W. Zhang, B. J. Bjork, D. Follman, P. Heu,C. Deutsch, L. Sonderhouse, J. Robinson, C. Franz,A. Alexandrovski, M. Notcutt, O. H. Heckl, J. Ye, andM. Aspelmeyer, “High-performance near- and mid-infraredcrystalline coatings,”
Optica , vol. 3, pp. 647–656, Jun 2016. R. Singh, G. D. Cole, J. Cripe, and T. Corbitt, “Stable op-tical trap from a single optical field utilizing birefringence,”
Phys. Rev. Lett. , vol. 117, p. 213604, Nov 2016. B. S. Sheard, M. B. Gray, C. M. Mow-Lowry, D. E. McClel-land, and S. E. Whitcomb, “Observation and characteriza-tion of an optical spring,”
Phys. Rev. A , vol. 69, p. 051801,May 2004. T. Corbitt, Y. Chen, E. Innerhofer, H. M¨uller-Ebhardt,D. Ottaway, H. Rehbein, D. Sigg, S. Whitcomb, C. Wipf,and N. Mavalvala, “An all-optical trap for a gram-scalemirror,”
Phys. Rev. Lett. , vol. 98, p. 150802, Apr 2007. J. Cripe, N. Aggarwal, R. Singh, R. Lanza, A. Libson, M. J.Yap, G. D. Cole, D. E. McClelland, N. Mavalvala, andT. Corbitt, “Radiation-pressure-mediated control of an op-tomechanical cavity,”
Phys. Rev. A , vol. 97, p. 013827, Jan2018. R. W. P. Drever, J. L. Hall, F. V. Kowalski, J. Hough,G. M. Ford, A. J. Munley, and H. Ward, “Laser phase andfrequency stabilization using an optical resonator,”
AppliedPhysics B , vol. 31, no. 2, pp. 97–105, 1983. S. S. Y. Chua, M. S. Stefszky, C. M. Mow-Lowry, B. C.Buchler, S. Dwyer, D. A. Shaddock, P. K. Lam, andD. E. McClelland, “Backscatter tolerant squeezed lightsource for advanced gravitational-wave detectors,”
Opt.Lett. , vol. 36, pp. 4680–4682, Dec 2011. H. Vahlbruch, S. Chelkowski, B. Hage, A. Franzen,K. Danzmann, and R. Schnabel, “Coherent control of vac-uum squeezing in the gravitational-wave detection band,”
Phys. Rev. Lett. , vol. 97, p. 011101, Jul 2006. V. B. Braginsky, Y. I. Vorontsov, and K. S. Thorne,“Quantum nondemolition measurements,”
Science ,vol. 209, no. 4456, pp. 547–557, 1980. V. B. Braginsky, M. L. Gorodetsky, F. Y. Khalili, and K. S.Thorne, “Dual-resonator speed meter for a free test mass,”
Phys. Rev. D , vol. 61, p. 044002, Jan 2000. J. Harms, Y. Chen, S. Chelkowski, A. Franzen,H. Vahlbruch, K. Danzmann, and R. Schnabel, “Squeezed-input, optical-spring, signal-recycled gravitational-wavedetectors,”
Phys. Rev. D , vol. 68, p. 042001, Aug 2003. E. Oelker, T. Isogai, J. Miller, M. Tse, L. Barsotti,N. Mavalvala, and M. Evans, “Audio-band frequency-dependent squeezing for gravitational-wave detectors,”
Phys. Rev. Lett. , vol. 116, p. 041102, Jan 2016. C. Grf et al ., “Design of a speed meter interferome-ter proof-of-principle experiment,”
Class. Quantum Grav. ,vol. 31, p. 215009, 2014. V. Giovannetti, S. Lloyd, and L. Maccone, “Quantum-enhanced measurements: Beating the standard quantumlimit,”
Science , vol. 306, no. 5700, pp. 1330–1336, 2004. V. B. Braginsky, “Classical and quantum restrictions onthe detection of weak disturbances of a macroscopic oscil-lator,”