Optimization of a composite quadrupole mass at high-speed rotation

Frajuca, Carlos; Souza, M. A.; Coppedé, Daniel; Nogueira, Paulo R. M.; Bortoli, F. S.; Santos, Givanildo Alves dos; Nakamoto, Francisco Yastami

doi:10.1007/s40430-018-1239-9

Cited by 24 publications

(7 citation statements)

References 27 publications

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“…The instrument will be maintained at low temperatures (∼ 4 K) by cryogenic chambers (dewars), cooled down by a He flow [9]. The antenna is coupled to parametric transducers that will monitor the vibrations of the quadrupolar/monopolar normal modes of the sphere [10][11][12][13][14]. One of the main advantages of a GW spherical resonant antenna is its omnidirectional sensitivity, which makes it equally responsive to all wave directions and polarizations [15].…”

Section: Introductionmentioning

confidence: 99%

The Design Strain Sensitivity of the Schenberg Spherical Resonant Antenna for Gravitational Waves

Liccardo

Lenzi

Marinho

et al. 2023

Preprint

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The main purpose of this study is to review the Schenberg resonant antenna transfer function and to recalculate the antenna design strain sensitivity for gravitational waves. We consider the spherical antenna with six transducers in the semi dodecahedral configuration. When coupled to the antenna, the transducer-sphere system will work as a mass-spring system with three masses. The first one is the antenna effective mass for each quadrupolemode, the second one is the mass of the mechanical structure of the transducer first mechanical mode and the third one is the effective mass of the transducer membrane that makes one of the transducer microwave cavity walls. All the calculations are done for the degenerate (all the sphere quadrupole mode frequencies equal) and non-degenerate sphere cases. We have come to the conclusion that the “ultimate” sensitivity of an advanced version of Schenberg antenna (aSchenberg) is around the standard quantum limit (although the parametric transducers used could, in principle, surpass this limit). However, this sensitivity, in the frequency range where Schenberg operates, has already been achieved by the two aLIGOs in the O3 run, therefore, the only reasonable justification for remounting the Schenberg antenna and trying to place it in the sensitivity of the standard quantum limit would be to detect gravitational waves with another physical principle, different from the one used by laser interferometers. This other physical principle would be the absorption of the gravitational wave energy by a resonant mass like Schenberg.

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Section: Introductionmentioning

confidence: 99%

The Design Strain Sensitivity of the Schenberg Spherical Resonant Antenna for Gravitational Waves

Liccardo

Lenzi

Marinho

et al. 2023

Preprint

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show abstract

Section: Introductionmentioning

confidence: 99%

“…When the detector is in operation, the motion of the antenna's surface is monitored by six parametric microwave transducers with their distribution on the shape of half a dodecahedron circumscribed to the antenna sphere (Frajuca et al 2008). More details on the SCHENBERG detector and on spherical resonant-mass GW detectors can be found in Aguiar et al 2002;Bortoli et al 2016;Bortoli et al 2019;Bortoli et al 2020;Bortoli et al 2010;Costa et al 2004;Frajuca et al 2018;Magalhaes et al 1995. When a GW passes through a resonant-mass detector, its antenna vibrates, whose surface motion is measured by transducers that generate electrical signals as outputs (Frajuca et al 2006). These signals are then analyzed and the intensity of such GW can be obtained; in the case of a spherical antenna, even the source's direction can be determined with only one detector (Magalhaes et al 1997).…”

Section: Introductionmentioning

confidence: 99%

Coherent quantum states in resonant‐mass gravitational wave detectors

et al. 2023

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“…These antennas, located in front of the parametric transducers, conduct the microwaves into the resonant cavity and another set of antennas pick up the returned signal. The Brazilian efforts on the field can be summarized in Frajuca et al (2002Frajuca et al ( ,2005Frajuca et al ( ,2006Frajuca et al ( ,2008Frajuca et al ( ,2018, Aguiar et al (2002Aguiar et al ( ,2004Aguiar et al ( ,2005Aguiar et al ( ,2012, Magalhaes et. al (1995Magalhaes et.…”

Section: Introductionmentioning

confidence: 99%

Estimation of Fibrilatory Atrial Signal Parameters in Electrocardiogram

Paulo¹,

Bock²,

Moreira³

2020

Engenharia Na Prática: Importância Teórica E Tecnológica

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Optimization of a composite quadrupole mass at high-speed rotation

Cited by 24 publications

References 27 publications

The Design Strain Sensitivity of the Schenberg Spherical Resonant Antenna for Gravitational Waves

The Design Strain Sensitivity of the Schenberg Spherical Resonant Antenna for Gravitational Waves

Coherent quantum states in resonant‐mass gravitational wave detectors

Estimation of Fibrilatory Atrial Signal Parameters in Electrocardiogram

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