Results 211 to 220 of about 1,462 (258)
Quantum sensing and metrology with free electrons. [PDF]
Nat CommunVelasco CI, García de Abajo FJ.
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Modeling and Simulation of Inter-Satellite Laser Communication for Space-Based Gravitational Wave Detection. [PDF]
Sensors (Basel)Liang H, Yi Z, Ling H, Luo K.
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Thermal Fisher Information for a Rotating BTZ Black Hole. [PDF]
Entropy (Basel)Patterson EA, Mann RB.
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Real-time inference for binary neutron star mergers using machine learning. [PDF]
NatureDax M +9 more
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Electromagnetic follow-up of gravitational waves: review and lessons learned. [PDF]
Philos Trans A Math Phys Eng SciNicholl M, Andreoni I.
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Resonant detectors for gravitational waves
Advances in Space Research, 2000Abstract For the first time a number of cryogenic resonant bar detectors of gravitational waves — ALLEGRO, AURIGA, EXPLORER, NAUTILUS, NIOBE — are on the air, in a continuous search for impulsive events. We present their capabilities, the foreseen upgrades and their role in a future global network with interferometric detectors.
L. Baggio +14 more
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Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences, 1979
As outlined in the preceding talk by Dr Thome, there are many possible sources of gravitational radiation, ranging from the interactions of supermassive black holes to supernova explosions of stars. Detection of such radiation could give information which cannot be obtained otherwise, for example on events occurring in the cores of stellar
Drever, R. W. P. +6 more
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As outlined in the preceding talk by Dr Thome, there are many possible sources of gravitational radiation, ranging from the interactions of supermassive black holes to supernova explosions of stars. Detection of such radiation could give information which cannot be obtained otherwise, for example on events occurring in the cores of stellar
Drever, R. W. P. +6 more
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2020
In this chapter, we describe the laser interferometric gravitational wave detectors, like LIGO, which was used to make the first detection of gravitational waves in 2015. A gravitational wave passing through a circle of test particles will cause the shape to oscillate from a circle to an ellipse to a circle repeatedly, because of the periodic ...
Ajit Kembhavi, Pushpa Khare
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In this chapter, we describe the laser interferometric gravitational wave detectors, like LIGO, which was used to make the first detection of gravitational waves in 2015. A gravitational wave passing through a circle of test particles will cause the shape to oscillate from a circle to an ellipse to a circle repeatedly, because of the periodic ...
Ajit Kembhavi, Pushpa Khare
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Gravitational Waves and Gravitational Wave Detectors
2020Just over 100 years ago, Albert Einstein published his General Theory of Relativity, which describes the interaction between matter, energy, space, and time and explains that the force of gravity is a result of the curvature of space and time (Einstein in Die feldgleichungen der gravitation. Preussische Akademie der Wissenschaften, Sitzungsberichte, pp
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Resonant detectors for gravitational waves
Rendiconti del Seminario Matematico e Fisico di Milano, 1995The principles of the gravitational wave detection by means of resonant antennas are illustrated and a review of the resonant antenna experiments in the world is given. Possible plans for the future resonant antennas are indicated.
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