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Quantum optomechanics: possible applications to

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1 Quantum optomechanics: possible applications to
Investigation of Planck-scale physics P. Mataloni Quantum Optics Group, Dipartimento di Fisica Sapienza Università di Roma, 00185, Italy INO – CNR, Firenze, Italy ENEA Frascati,

2 Quantum Optomechanics: to generate, control and manipulate quantum states of a mechanical system by Quantum Optics. The optical mode and the mechanical mode interact via momentum transfer (i.e. radiation pressure) within an optical cavity. Nonlinear interaction occur when the light is confined in a cavity modified by the mechanical motion. Implemented by direct change of cavity length. Current optical technology based on high quality optomechanical devices makes possible experiments in this field. 2

3 Model of optomechanical setup
Pump laser field with large amplitude |ac|>>1 and frequency wL ac , ac+: optical field bc , bc+: mechanical motion 3

4 Mechanical resonators
b) c) a) Fabry-Perot cavity b) microtoroid structure c) optomechanical crystal

5 Interaction Hamiltonian
1st term: Energy transfer between laser field and joint excitation of optical and mechanical mode. Allows to generate correlated/anticorrelated modes and also entanglement between optical and mechanical fields. 2nd term: Energy transfer between the two modes. Equivalent to a quantum optical beam splitter interaction. May allow cooling of the optomechanical mode. Interaction tuned by choosing the right detuning D.

6 Mechanical mode is in a thermal mixed state
Optical mode is in a pure state T < 50 mK needed for a mechanical mode bandwidth = 1 MHz

7 Quantization of spacetime may result in a modification of the Heisenberg uncertainty relation due to quantum gravitational effects. Deformation of the commutator [x, p]  xp – px leads to a generalized uncertainty relation:

8 The Idea Use quantum optics to test quantum gravitational effects by probing the canonical commutation of the centre-of-mass mode of a mechanical oscillator. Probe the commutator of a quantum oscillator with mass close to the Planck mass by a sequence of interactions with a strong optical field in an optomechanical setting, which uses radiation pressure inside an optical cavity. Need to perform a high-sensitivity measurement of the uncertainty relation

9 1) Displacement Operator
Xm , Pm: quadrature operators

10 2) Choose a sequence of four optomechanical interactions to displace the mechanical state around a loop in phase-space Note: Xm , Pm don’t commute any change in the optical field depends on the commutator [Xm , Pm]. Moreover: Coherent states |a> with photon number Np>>1: A deformed commutator affects the optical field by introducing an additional displacement in phase space. Measured with optical imprecision:

11 3) How to realize the displacement operator?
Within a single oscillation a 4-pulse interaction U(q) = eiq is implemented in a sequence which allows Xm and Pm to be interchanged after a quarter of the oscillator period. After the four-pulse interaction the optical field can be analysed by an interferometric measurement (homodyne technique) yielding the phase information of the light with very high precision.

12 4) How to implement the four pulse interaction?
Mean value and variance of the mechanical state after a short input pulse << T = 2p/wm: PL: measurement outcome W: momentum transfer Divide in 4 quarters the oscillation period Look at the momentum in the 1st quarter, then at the position in the 2nd one, then viceversa in the 3rd and 4th quarters. Four operations performed within one oscillation period

13 5) Experimental scheme

14 6) some number….. (1) determines the resolution db0, dm0, dg0 . sout: quantum noise of the output pulse The inaccuracy (2) (3)

15 7) Micromechanical mirror
Works with a flat suspended mirror. Cavity length = 4l l = 1064 nm Effective mass m = 10 ng

16 The quantum opto-mechanics experiment in Italy
- Univ. of Camerino (P- Tombesi, G. Di Giuseppe, D. Vitali) - Univ. Di Firenze (G. Tino) coll. with Roma Sapienza (G. A. Camelia)

17 Univ. Firenze (F. Marin, F. Cataliotti): towards quantum effects in the mechanical interaction of light with macroscopic objects Supported by LENS (UniFI), INFN (CSN5, SQUALO)

18 World record for Q and Finesse in oscillating micro-mirrors
Mass = 2x10-7 Kg Freq. = 85 KHz Q = 2.6 x 106 Finesse = 6 x 104 T = 5 K World record for Q and Finesse in oscillating micro-mirrors Unpublished-Confidential Also required: Q > 10 6 T < 100mK SiN membrane are being studied for mass ~ Kg Also required Q > 106 , T < 100 mK

19 Thank you!


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