Your search keyword '"Evans, Matthew"' showing total 13 results

1. Parameter estimation for binary black holes with networks of third-generation gravitational-wave detectors.

Author

Vitale, Salvatore and Evans, Matthew

Subjects

*BINARY black holes, *GRAVITATIONAL waves, *DETECTORS

Abstract

The two binary black hole (BBH) coalescences detected by LIGO, GW150914, and GW151226, were relatively nearby sources, with a redshift of ~0.1. As the sensitivity of Advanced LIGO and Virgo increases in the next few years, they will eventually detect stellar-mass BBHs up to redshifts of ~1. However, these are still relatively small distances compared with the size of the Universe, or with those encountered in most areas of astrophysics. In order to study BBH during the epoch of reionization, or black holes born from population III stars, more sensitive instruments are needed. Third-generation gravitational-wave detectors, such as the Einstein Telescope or the Cosmic Explorer, are already in an advanced R&D stage. These detectors will be roughly a factor of 10 more sensitive in strain than the current generation, and they will be able to detect BBH mergers beyond a redshift of 20. In this paper we quantify the precision with which these new facilities will be able to estimate the parameters of stellar-mass, heavy, and intermediate-mass BBHs as a function of their redshifts and the number of detectors. We show that having only two detectors would result in relatively poor estimates of black hole intrinsic masses: a situation improved with three or four instruments. Larger improvements are visible for the sky localization, although it is not yet clear whether BBHs are luminous in the electromagnetic or neutrino band. The measurement of the spin parameters, on the other hand, does not improve significantly as more detectors are added to the network since redshift information is not required to measure spin. [ABSTRACT FROM AUTHOR]

Published

2017

2. Multimaterial coatings with reduced thermal noise.

Author

Yam, William, Gras, Slawek, and Evans, Matthew

Subjects

*NOISE control, *THERMAL noise, *COATING processes, *SURFACE coatings, *GRAVITATIONAL wave detectors, *SPACETIME

Abstract

The most sensitive measurements of time and space are made with resonant optical cavities, and these measurements are limited by coating thermal noise. The mechanical and optical performance requirements placed on coating materials, especially for interferometric gravitational wave detectors, have proven extremely difficult to meet despite a lengthy search. In this paper we propose a new approach to high performance coatings, the use of multiple materials at different depths in the coating. To support this we generalize previous work on thermal noise in two-material coatings to an arbitrary multimaterial stack, and develop a means of estimating absorption in these multimaterial coatings. This new approach will allow for a broadening of the search for high performance coating materials. [ABSTRACT FROM AUTHOR]

Published

2015

3. Searching for axion dark matter with birefringent cavities.

Author

Hongwan Liu, Elwood, Brodi D., Evans, Matthew, and Thaler, Jesse

Subjects

*AXIONS, *LASER interferometers, *DARK matter

Abstract

Axionlike particles are a broad class of dark matter candidates which are expected to behave as a coherent, classical field with a weak coupling to photons. Research into the detectability of these particles with laser interferometers has recently revealed a number of promising experimental designs. Inspired by these ideas, we propose the axion detection with birefringent cavities (ADBC) experiment, a new axion interferometry concept using a cavity that exhibits birefringence between its two, linearly polarized laser eigenmodes. This experimental concept overcomes several limitations of the designs currently in the literature and can be practically realized in the form of a simple bowtie cavity with tunable mirror angles. Our design thereby increases the sensitivity to the axion-photon coupling over a wide range of axion masses. [ABSTRACT FROM AUTHOR]

Published

2019

4. Frequency-dependent responses in third generation gravitational-wave detectors.

Author

Essick, Reed, Vitale, Salvatore, and Evans, Matthew

Subjects

*GRAVITATIONAL waves, *NEUTRON stars, *DETECTORS

Abstract

Interferometric gravitational-wave detectors are dynamic instruments. Changing gravitational-wave strains influence the trajectories of null geodesics and therefore modify the interferometric response. These effects will be important when the associated frequencies are comparable to the round-trip light travel time down the detector arms. The arms of advanced detectors currently in operation are short enough that the strain can be approximated as static, but planned 3rd generation detectors, with arms an order of magnitude longer, will need to account for these effects. We investigate the impact of neglecting the frequency-dependent detector response for compact binary coalescences and show that it can introduce large systematic biases in localization, larger than the statistical uncertainty for 1.4 - 1.4 M⊙ neutron star coalescences at z ≲ 1.7. Analysis of 3rd generation detectors therefore must account for these effects. [ABSTRACT FROM AUTHOR]

Published

2017

5. Gravitational wave detector with cosmological reach.

Author

Dwyer, Sheila, Sigg, Daniel, Ballmer, Stefan W., Barsotti, Lisa, Mavalvala, Nergis, and Evans, Matthew

Subjects

*GRAVITATIONAL wave measurement, *BLACK hole evaporation, *SCATTERING amplitude (Physics), PULSAR detection

Abstract

Twenty years ago, construction began on the Laser Interferometer Gravitational-wave Observatory (LIGO). Advanced LIGO, with a factor of 10 better design sensitivity than Initial LIGO, will begin taking data this year, and should soon make detections a monthly occurrence. While Advanced LIGO promises to make first detections of gravitational waves from the nearby universe, an additional factor of 10 increase in sensitivity would put exciting science targets within reach by providing observations of binary black hole inspirais throughout most of the history of star formation, and high signal to noise observations of nearby events. Design studies for future detectors to date rely on significant technological advances that are futuristic and risky. In this paper we propose a different direction. We resurrect the idea of using longer arm lengths coupled with largely proven technologies. Since the major noise sources that limit gravitational wave detectors do not scale trivially with the length of the detector, we study their impact and find that 40 km arm lengths are nearly optimal, and can incorporate currently available technologies to detect gravitational wave sources at cosmological distances (z ≳ 7). [ABSTRACT FROM AUTHOR]

Published

2015

6. Prospects for doubling the range of Advanced LIGO.

Author

Miller, John, Barsotti, Lisa, Vitale, Salvatore, Fritschel, Peter, Evans, Matthew, and Sigg, Daniel

Subjects

*QUANTUM noise, *OPTICAL quantum computing, *THERMAL noise, *ELECTRONIC noise, *TEMPERATURE effect

Abstract

In the coming years, the gravitational-wave community will be optimizing detector performance to target a variety of astrophysical sources which make competing demands on detector sensitivity in different frequency bands. In this paper we describe a number of technologies that are being developed as anticipated upgrades to the Advanced LIGO detectors and quantify the potential sensitivity improvement they offer. Specifically, we consider squeezed light injection for the reduction of quantum noise, detector design and materials changes which mitigate thermal noise and mirrors with significantly increased mass. We explore how each of these technologies impacts the detection of the most promising gravitational-wave sources and suggest an effective progression of upgrades which culminates in a twofold improvement in broadband sensitivity. [ABSTRACT FROM AUTHOR]

Published

2015

7. Effect of squeezing on parameter estimation of gravitational waves emitted by compact binary systems.

Author

Lynch, Ryan, Vitale, Salvatore, Barsotti, Lisa, Dwyer, Sheila, and Evans, Matthew

Subjects

*PARAMETER estimation, *GRAVITATIONAL waves, *QUANTUM noise, *MONTE Carlo method, *ELECTROMAGNETISM, *SIGNAL-to-noise ratio

Abstract

The LIGO gravitational wave (GW) detectors will begin collecting data in 2015, with Virgo following shortly after. These detectors are expected to reach design sensitivity before the end of the decade, and yield the first direct detection of GWs before then. The use of squeezing has been proposed as a way to reduce the quantum noise without increasing the laser power, and has been successfully tested at one of the LIGO sites and at GEO in Germany. When used in Advanced LIGO without a filter cavity, the squeezer improves the performances of detectors above ~100 Hz, at the cost of a higher noise floor in the low-frequency regime. Frequency-dependent squeezing, on the other hand, will lower the noise floor throughout the entire band. Squeezing technology will have a twofold impact: it will change the number of expected detections and it will impact the quality of parameter estimation for the detected signals. In this work we consider three different GW detector networks, each utilizing a different type of squeezer-all corresponding to plausible implementations. Using LALInference, a powerful Monte Carlo parameter estimation algorithm, we study how each of these networks estimates the parameters of GW signals emitted by compact binary systems, and compare the results with a baseline advanced LIGO-Virgo network. We find that, even in its simplest implementation, squeezing has a large positive impact: the sky error area of detected signals will shrink by ~30% on average, increasing the chances of finding an electromagnetic counterpart to the GW detection. Similarly, we find that the measurability of tidal deformability parameters for neutron stars in binaries increases by ~30%, which could aid in determining the equation of state of neutron stars. The degradation in the measurement of the chirp mass, as a result of the higher low-frequency noise, is shown to be negligible when compared to systematic errors. Implementations of a quantum squeezer coupled with a filter cavity will yield a better overall network sensitivity. They will give less drastic improvements over the baseline network for events of fixed signal-to-noise ratio but greater improvements for identical events. [ABSTRACT FROM AUTHOR]

Published

2015

8. Low-frequency terrestrial gravitational-wave detectors.

Author

Jan Harms, Slagmolen, Bram J. J., Adhikari, Rana X., Miller, M. Coleman, Evans, Matthew, Chen, Yanbei, Müller, Holger, and Ando, Masaki

Subjects

*GRAVITATIONAL wave detectors, *RELATIVITY (Physics), *ASTROPHYSICS, *LASER interferometers, *MICROSEISMS

Abstract

Direct detection of gravitational radiation in the audio band is being pursued with a network of kilometer-scale interferometers (LIGO, Virgo, KAGRA). Several space missions (LISA, DECIGO, BBO) have been proposed to search for sub-hertz radiation from massive astrophysical sources. Here we examine the potential sensitivity of three ground-based detector concepts aimed at radiation in the 0.1-10 Hz band. We describe the plethora of potential astrophysical sources in this band and make estimates for their event rates and thereby, the sensitivity requirements for these detectors. The scientific payoff from measuring astrophysical gravitational waves in this frequency band is great. Although we find no fundamental limits to the detector sensitivity in this band, the remaining technical limits will be extremely challenging to overcome. [ABSTRACT FROM AUTHOR]

Published

2013

9. Gravitational-wave physics with Cosmic Explorer: Limits to low-frequency sensitivity.

Author

Hall, Evan D., Kuns, Kevin, Smith, Joshua R., Yuntao Bai, Wipf, Christopher, Biscans, Sebastien, Adhikari, Rana X., Koji Arai, Ballmer, Stefan, Barsotti, Lisa, Yanbei Chen, Evans, Matthew, Fritschel, Peter, Harms, Jan, Kamai, Brittany, Rollins, Jameson Graef, Shoemaker, David, Slagmolen, Bram J. J., Weiss, Rainer, and Hiro Yamamoto

Subjects

*GRAVITATIONAL waves, *QUANTUM noise, *NOISE control, *EXPLORERS, *PHYSICS, *NEUTRON stars

Abstract

Cosmic Explorer is a next-generation ground-based gravitational-wave observatory concept, envisioned to begin operation in the 2030s and expected to be capable of observing binary neutron star and black hole mergers back to the time of the first stars. Cosmic Explorer's sensitive band will extend below 10 Hz, where the design is predominantly limited by geophysical, thermal, and quantum noises. In this work, thermal, seismic, gravity-gradient, quantum, residual gas, scattered-light, and servo-control noises are analyzed in order to motivate facility and vacuum system design requirements, potential test mass suspensions, Newtonian noise reduction strategies, improved inertial sensors, and cryogenic control requirements. Our analysis shows that, with improved technologies, Cosmic Explorer can deliver a strain sensitivity better than 10-23 Hz-1/2 down to 5 Hz. Our work refines and extends previous analysis of the Cosmic Explorer concept and outlines the key research areas needed to make this observatory a reality. [ABSTRACT FROM AUTHOR]

Published

2021

10. Tuning Advanced LIGO to kilohertz signals from neutron-star collisions.

Author

Ganapathy, Dhruva, McCuller, Lee, Rollins, Jameson Graef, Hall, Evan D., Barsotti, Lisa, and Evans, Matthew

Subjects

*TUNING (Musical instruments), *STELLAR collisions, *GRAVITATIONAL waves, *SIGNAL detection, *NEUTRON stars, *QUANTUM noise, *SIGNAL-to-noise ratio, *MICHELSON interferometer

Abstract

Gravitational waves produced at kilohertz frequencies in the aftermath of a neutron star collision can shed light on the behavior of matter at extreme temperatures and densities that are inaccessible to laboratory experiments. Gravitational-wave interferometers are limited by quantum noise at these frequencies but can be tuned via their optical configuration to maximize the probability of postmerger signal detection. We compare two such tuning strategies to turn Advanced LIGO into a postmerger-focused instrument: first, a wideband tuning that enhances the instrument's signal-to-noise ratio 40-80% broadly above 1 kHz relative to the baseline, with a modest sensitivity penalty at lower frequencies; second, a "detuned" configuration that provides even more enhancement than the wideband tuning, but over only a narrow frequency band and at the expense of substantially worse quantum noise performance elsewhere. With an optimistic accounting for instrument loss and uncertainty in postmerger parameters, the detuned instrument has a 40 % sensitivity improvement compared to the wideband instrument. [ABSTRACT FROM AUTHOR]

Published

2021

11. Demonstration of an amplitude filter cavity at gravitational-wave frequencies.

Author

Komori, Kentaro, Ganapathy, Dhruva, Whittle, Chris, McCuller, Lee, Barsotti, Lisa, Mavalvala, Nergis, and Evans, Matthew

Subjects

*GRAVITATIONAL wave detectors, *GRAVITATIONAL waves, *SQUEEZED light, *QUANTUM noise, *QUANTUM fluctuations, *RADIATION pressure, *OPTICAL measurements

Abstract

Quantum vacuum fluctuations fundamentally limit the precision of optical measurements, such as those in gravitational-wave detectors. The injection of a conventional squeezed vacuum can be used to reduce quantum noise in the readout quadrature, but this reduction is at the cost of increasing noise in the orthogonal quadrature. For detectors near the limits imposed by quantum radiation pressure noise (QRPN), both quadratures impact the measurement, and the benefits of conventional squeezing are limited. In this paper, we demonstrate the use of a critically coupled 16 m optical cavity to diminish antisqueezing at frequencies below 90 Hz, where it exacerbates QRPN, while preserving beneficial squeezing at higher frequencies. This is called an amplitude filter cavity, and it is useful for avoiding degradation of detector sensitivity at low frequencies. The attenuation from the cavity also provides technical advantages such as mitigating backscatter. [ABSTRACT FROM AUTHOR]

Published

2020

12. Optimal detuning for quantum filter cavities.

Author

Whittle, Chris, Komori, Kentaro, Ganapathy, Dhruva, McCuller, Lee, Barsotti, Lisa, Mavalvala, Nergis, and Evans, Matthew

Subjects

*GRAVITATIONAL wave detectors, *QUANTUM noise, *RADIATION pressure, *QUANTUM fluctuations, *FILTERS & filtration

Abstract

Vacuum quantum fluctuations impose a fundamental limit on the sensitivity of gravitational-wave interferometers, which rank among the most sensitive precision measurement devices ever built. The injection of conventional squeezed vacuum reduces quantum noise in one quadrature at the expense of increasing noise in the other. While this approach improved the sensitivity of the Advanced LIGO and Advanced Virgo interferometers during their third observing run (O3), future improvements in arm power and squeezing levels will bring radiation pressure noise to the forefront. Installation of a filter cavity for frequency-dependent squeezing provides broadband reduction of quantum noise through the mitigation of this radiation pressure noise, and it is the baseline approach planned for all of the future gravitational-wave detectors currently conceived. The design and operation of a filter cavity requires careful consideration of interferometer optomechanics as well as squeezing degradation processes. In this paper, we perform an in-depth analysis to determine the optimal operating point of a filter cavity. We use our model alongside numerical tools to study the implications for filter cavities to be installed in the upcoming "A+" upgrade of the Advanced LIGO detectors. [ABSTRACT FROM AUTHOR]

Published

2020

13. Mitigation of the instrumental noise transient in gravitational-wave data surrounding GW170817.

Author

Pankow, Chris, Chatziioannou, Katerina, Chase, Eve A., Littenberg, Tyson B., Evans, Matthew, McIver, Jessica, Cornish, Neil J., Haster, Carl-Johan, Kanner, Jonah, Raymond, Vivien, Vitale, Salvatore, and Zimmerman, Aaron

Subjects

*ASTROPHYSICS, *GRAVITATIONAL waves

Abstract

In the coming years gravitational-wave detectors will undergo a series of improvements, with an increase in their detection rate by about an order of magnitude. Routine detections of gravitational-wave signals promote novel astrophysical and fundamental theory studies, while simultaneously leading to an increase in the number of detections temporally overlapping with instrumentally- or environmentally-induced transients in the detectors (glitches), often of unknown origin. Indeed, this was the case for the very first detection by the LIGO and Virgo detectors of a gravitational-wave signal consistent with a binary neutron star coalescence, GW170817. A loud glitch in the LIGO-Livingston detector, about one second before the merger, hampered coincident detection (which was initially achieved solely with LIGO-Hanford data). Moreover, accurate source characterization depends on specific assumptions about the behavior of the detector noise that are rendered invalid by the presence of glitches. In this paper, we present the various techniques employed for the initial mitigation of the glitch to perform source characterization of GW170817 and study advantages and disadvantages of each mitigation method. We show that, despite the presence of instrumental noise transients louder than the one affecting GW170817, we are still able to produce unbiased measurements of the intrinsic parameters from simulated injections with properties similar to GW170817. [ABSTRACT FROM AUTHOR]

Published

2018