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Opto-mechanics with a 50 ng membrane Henning Kaufer, A. Sawadsky, R. Moghadas Nia, D.Friedrich, T. Westphal, K. Yamamoto and R. Schnabel GWADW 2012, 16.5.2012.

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Presentation on theme: "Opto-mechanics with a 50 ng membrane Henning Kaufer, A. Sawadsky, R. Moghadas Nia, D.Friedrich, T. Westphal, K. Yamamoto and R. Schnabel GWADW 2012, 16.5.2012."— Presentation transcript:

1 Opto-mechanics with a 50 ng membrane Henning Kaufer, A. Sawadsky, R. Moghadas Nia, D.Friedrich, T. Westphal, K. Yamamoto and R. Schnabel GWADW 2012, 16.5.2012

2 Henning Kaufer www.qi.aei-hannover.de Radiation pressure noise 2 Ligo Livingston Advanced LIGO anticipated strain sensitivty A limiting factor for low frequencies Often referred to as back-action noise Next generation detectors will observe back-action noise Is it observeable with tabletop experiments? Radiation pressure noise Shot noise

3 Henning Kaufer www.qi.aei-hannover.de Opto-mechanics Transfer of photon momentum 3 T.J. Kippenberg and K.J. Vahala, Science 321, 1172 (2008) 40 nm thickness m eff = 80 ng Q factor = 500.000 f res = 100 kHz R = 17 % @ 1064 nm (refractive index + ethalon effect) Standard approach: Build Cavity 1.5 mm

4 Henning Kaufer www.qi.aei-hannover.de Michelson-Sagnac interferometer 4 SIN membrane used as common end-mirror Recycling mirror in interferometer output No drawback from low power reflectivity Laser noise rejection

5 Henning Kaufer www.qi.aei-hannover.de Experimental setup 5 Setup features -Arm length = 6 cm -0.5 “ Optics and piezos -Double seismic isolation -Operated at 10 -6 mbar -Remote control for alignment InputOutput

6 Henning Kaufer www.qi.aei-hannover.de Currently limited by thermal noise 6

7 Henning Kaufer www.qi.aei-hannover.de Quantum noise 7 Cryogenic cooling and signal recycling R sr = 99,97 % K. Yamamoto et al, Phys. Rev. A 81, 033849 (2010)

8 Henning Kaufer www.qi.aei-hannover.de Ponderomotive squeezing 8 Requires homodyne readout (Read out phase quadrature) 0.3 dB @ 500 mW input power Amplitude Phase fluctuation Membrane acts as coupling device Calculation : H. Miao

9 Henning Kaufer www.qi.aei-hannover.de Balanced homodyne read out (no recycling) 9

10 Henning Kaufer www.qi.aei-hannover.de With recycling mirror : Induced oscillations 10 Cavity operated with R sr = 99,97 % Optical linewidth = 30 kHz Stable and Anti-stable behavior Induced parametric (de-) amplification of Membrane motion

11 Henning Kaufer www.qi.aei-hannover.de Optical cooling 11 Spectra obtained with DC read out Only slightly improved displacement sensitivty Unknown noise background (most propably laser frequency noise) Changed oscillator parameters, Calculated T eff = 7 K and Q eff = 4500 With R sr = 99 % and P in = 100 mW

12 Henning Kaufer www.qi.aei-hannover.de Questions? Thank you for your attention 12

13 Henning Kaufer www.qi.aei-hannover.de Dissipative opto-mechanics 13 Usual idea: use cavity and detune Supress lower sideband E ph = hf Require : l opt << f mech For strong cooling Dissipative cooling Require system with

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