4 research outputs found
Paired carriers as a way to reduce quantum noise of multi-carrier gravitational-wave detectors
We explore new regimes of laser interferometric gravitational-wave detectors
with multiple optical carriers which allow to reduce the quantum noise of these
detectors. In particular, we show that using two carriers with the opposite
detunings, homodyne angles, and squeezing angles, but identical other
parameters (the antisymmetric carriers), one can suppress the quantum noise in
such a way that its spectrum follows the Standard Quantum Limit (SQL) at low
frequencies. Relaxing this antisymmetry condition, it is also possible to
slightly overcome the SQL in broadband. Combining several such pairs in the
xylophone configuration, it is possible to shape the quantum noise spectrum
flexibly
A new type of quantum speed meter interferometer: measuring speed to search for intermediate mass black holes
The recent discovery of gravitational waves (GW) by LIGO has impressively
launched the novel field of gravitational astronomy and it allowed us to
glimpse at exciting objects we could so far only speculate about. Further
sensitivity improvements at the low frequency end of the detection band of
future GW observatories rely on quantum non-demolition (QND) methods to
suppress fundamental quantum fluctuations of the light fields used to readout
the GW signal. Here we invent a novel concept of how to turn a conventional
Michelson interferometer into a QND speed meter interferometer with coherently
suppressed quantum back-action noise by using two orthogonal polarisations of
light and an optical circulator to couple them. We carry out a detailed
analysis of how imperfections and optical loss influence the achievable
sensitivity and find that the configuration proposed here would significantly
enhance the low frequency sensitivity and increase the observable event rate of
binary black hole coalescences in the range of by a factor
of up to .Comment: 8 pages, 5 figures. Modified figures and text in v
A new quantum speed-meter interferometer: Measuring speed to search for intermediate mass black holes article
The recent discovery of gravitational waves (GW) by Advanced LIGO (Laser Interferometric Gravitational-wave Observatory) has impressively launched the novel field of gravitational astronomy and allowed us to glimpse exciting objects about which we could previously only speculate. Further sensitivity improvements at the low-frequency end of the detection band of future GW observatories must rely on quantum non-demolition (QND) methods to suppress fundamental quantum fluctuations of the light fields used to readout the GW signal. Here we present a novel concept of how to turn a conventional Michelson interferometer into a QND speed-meter interferometer with coherently suppressed quantum back-action noise. We use two orthogonal polarizations of light and an optical circulator to couple them. We carry out a detailed analysis of how imperfections and optical loss influence the achievable sensitivity. We find that the proposed configuration significantly enhances the low-frequency sensitivity and increases the observable event rate of binary black-hole coalescences in the range of 102 - 103,M⊙ 1 0 2 - 1 0 3 M ⊙ by a factor of up to ∼300