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Squeeze Amplitude Filters

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Presentation on theme: "Squeeze Amplitude Filters"— Presentation transcript:

1 Squeeze Amplitude Filters
Thomas Corbitt and Nergis Mavalvala MIT Stan Whitcomb Caltech

2 March 2003 LSC meeting Thomas asked… Assumptions then… Result = Yes
Is squeezing useful in an AdLIGO configuration? What is an optimal configuration? Assumptions then… ~10 dB of squeezing at fixed squeeze angle Result = Yes Slightly different detuning and SEM reflectivity to get best advantage

3 Frequency INdependent Squeeze Angle
Baseline 0 db 5 db 10 db

4 Basics of squeezing in interferometers
Today… Filtering to Rotate squeeze angle Tailor squeeze amplitude Basics of squeezing in interferometers

5 Conventional Interferometer
b Amplitude  b1 = a1 Phase  b2 = k a1 + a2 + h Radiation Pressure Shot Noise

6 If we could squeeze k a1+a2 instead
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

7 Frequency INdependent Squeeze Angle
Baseline 0 db 5 db 10 db

8 Frequency-dependent squeeze angle
Corbitt and Mavalvala, gr-qc/ (2003)

9 Realizing a frequency-dependent squeeze angle
filter cavities Filter cavities Some difficulties Low losses Highly detuned Multiple cavities Conventional interferometers  Kimble, Levin, Matsko, Thorne, and Vyatchanin, Phys. Rev. D 65, (2001). Signal tuned interferometers  Harms, Chen, Chelkowski, Franzen, Vahlbruch, Danzmann, and Schnabel, gr-qc/ (2003).

10 Other alternatives Squeeze at an angle to reduce noise at an intermediate frequency  narrowband performance Squeeze at an angle to reduce high frequency noise  reduced sensitivity at low frequency (same effect as increasing power) Squeeze at an angle to reduce high frequency noise and filter squeezed light to destroy (anti-) squeezing at low frequencies  improved performance at high frequencies without compromising low-frequency sensitivity

11 Amplitude filtered squeezing

12 Principle of amplitude filter
Losses allow vacuum to leak in Ordinary vacuum replaces the squeezed field but only at frequencies where the anti-squeezing dominates a d b  v c

13 Extend to multiple filters

14 Filter properties a  attenuation factor (anti-squeeze)
b  maximum squeeze (vacuum leakage)

15 Application to a conventional interferometer

16 Astrophysical Performance

17 Conclusion Squeeze magnitude filtering does not give as good a broadband performance as FD-squeeze angle BUT Good wideband improvement over fixed squeeze angle AND Amplitude filters easier to implement Flexible design depending on filter cavity linewidth

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