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Books on the topic 'Black hole waves'

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Published: 1 June 2024

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1

Veske, Doga. Searching for new discoveries in binary black hole mergers and of multi-messenger detections with gravitational-waves. [New York, N.Y.?]: [publisher not identified], 2022.

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2

D'Eath, P. D. Black holes: Gravitational interactions. Oxford: Clarendon Press, 1996.

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3

Takashi, Nakamura, Oohara Kenichi, and Kojima Yasufumi, eds. General relativistic collapse to black holes and gravitational waves from black holes. Kyoto: Research Institute for Fundamental Physics and the Physical Society of Japan, 1987.

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4

S, Chandrasekhar. The mathematical theory of black holes and of colliding plane waves. Chicago: University of Chicago Press, 1991.

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5

V, Vishveshwara C., Iyer B. R, and Bhawal Biplab, eds. Black holes, gravitational radiation, and the universe: Essays in honor of C.V. Vishveshwara. Dordrecht: Kluwer, 1999.

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6

Maurice H. P. M. Van Putten. Gravitational radiation, luminous black holes, and gamma-ray burst supernovae. Cambridge, UK: Cambridge University Press, 2005.

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7

Christodoulou, Demetrios. The formation of black holes in general relativity. Züich, Switzerland: European Mathematical Society, 2009.

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8

Sibgatullin, N. R. Oscillations and waves in strong gravitational and electromagnetic fields. Berlin: Springer-Verlag, 1991.

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9

Spanish Relativity Meeting (1995 La Laguna, Tenerife, Spain). Relativistic astrophysics and cosmology: Proceedings of the Spanish Relativity Meeting, La Laguna, Tenerife, Spain, September 4-7, 1995. Edited by Buitrago J, Mediavilla E, and Oscoz A. Singapore: World Scientific, 1995.

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10

Häfner, Dietrich. Sur la théorie de la diffusion pour l'équation de Klein-Gordon dans la métrique de Kerr. Warszawa: Polska Akademia Nauk, Instytut Matematyczny, 2003.

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11

Clay Mathematics Institute. Summer School. Evolution equations: Clay Mathematics Institute Summer School, evolution equations, Eidgenössische Technische Hochschule, Zürich, Switzerland, June 23-July 18, 2008. Edited by Ellwood, D. (David), 1966- editor of compilation, Rodnianski, Igor, 1972- editor of compilation, Staffilani, Gigliola, 1966- editor of compilation, and Wunsch, Jared, editor of compilation. Providence, Rhode Island: American Mathematical Society, 2013.

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12

Moffat, John W. Shadow of the Black Hole. Oxford University Press, Incorporated, 2020.

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13

Moffat, John W. The Shadow of the Black Hole. Oxford University Press, 2020. http://dx.doi.org/10.1093/oso/9780190650728.001.0001.

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The author visits one of the two Laser Interferometer Gravitational- Wave Observatory (LIGO) sites in the United States, at Hanford, Washington. This is where scientists are detecting gravitational waves generated by faraway merging black holes and neutron stars. He meets the people who work there and has discussions with some of them. The director gives him a tour of the LIGO experimental installation, describing the work, the technological details of the apparatus, and answers his questions. On the final day of the visit, the author gives a talk to the LIGO group on gravitational waves and on an alternative gravitational theory.
14

Levin, Janna. Black Hole Blues and Other Songs from Outer Space. Penguin Random House, 2017.

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15

Levin, Janna. Black Hole Blues and Other Songs from Outer Space. Penguin Random House, 2016.

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16

Levin, Janna. Black hole blues: And other songs from outer space. 2016.

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17

Maggiore, Michele. Gravitational Waves. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198570899.001.0001.

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A comprehensive and detailed account of the physics of gravitational waves and their role in astrophysics and cosmology. The part on astrophysical sources of gravitational waves includes chapters on GWs from supernovae, neutron stars (neutron star normal modes, CFS instability, r-modes), black-hole perturbation theory (Regge-Wheeler and Zerilli equations, Teukoslky equation for rotating BHs, quasi-normal modes) coalescing compact binaries (effective one-body formalism, numerical relativity), discovery of gravitational waves at the advanced LIGO interferometers (discoveries of GW150914, GW151226, tests of general relativity, astrophysical implications), supermassive black holes (supermassive black-hole binaries, EMRI, relevance for LISA and pulsar timing arrays). The part on gravitational waves and cosmology include discussions of FRW cosmology, cosmological perturbation theory (helicity decomposition, scalar and tensor perturbations, Bardeen variables, power spectra, transfer functions for scalar and tensor modes), the effects of GWs on the Cosmic Microwave Background (ISW effect, CMB polarization, E and B modes), inflation (amplification of vacuum fluctuations, quantum fields in curved space, generation of scalar and tensor perturbations, Mukhanov-Sasaki equation,reheating, preheating), stochastic backgrounds of cosmological origin (phase transitions, cosmic strings, alternatives to inflation, bounds on primordial GWs) and search of stochastic backgrounds with Pulsar Timing Arrays (PTA).
18

Blundell, Katherine. 8. Black holes and spin-offs. Oxford University Press, 2015. http://dx.doi.org/10.1093/actrade/9780199602667.003.0008.

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Black holes influence and interact with their surroundings. Plasma lobes exhibited by some active galaxies are created by jets that are squirted out from the immediate surroundings of a black hole, outside the event horizon. When the jets impinge on the intergalactic medium, shock waves form within which spectacular particle acceleration occurs, and the energized plasma which originated from near the black hole, billows up and flows out of the immediate shock region. As the plasma expands, it imparts enormous quantities of energy to the intergalactic medium. ‘Black holes and spin-offs’ describes the powerful luminosity of quasars, their synchrotron radiation, and the much smaller microquasars.
19

Kyutoku, Koutarou. Black Hole-Neutron Star Binary Merger in Full General Relativity: Dependence on Neutron Star Equations of State. Springer London, Limited, 2013.

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20

Kyutoku, Koutarou. The Black Hole-Neutron Star Binary Merger in Full General Relativity: Dependence on Neutron Star Equations of State. Springer, 2015.

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21

Kyutoku, Koutarou. The Black Hole-Neutron Star Binary Merger in Full General Relativity: Dependence on Neutron Star Equations of State. Springer, 2013.

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22

Maggiore, Michele. Supermassive black holes. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198570899.003.0007.

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The supermassive BH at the center of our Galaxy. Formation and evolution of SMBH binaries. Perspective for detection with LISA. Extreme mass ratio inspirals (EMRIs). Computation of the EMRI’s waveform with the self-force approach. Stochastic backgrounds of gravitational waves produced by SMBH binaries. Perspective for detection at pulsar timing arrays
23

On Black Holes and Gravitational Waves. La Goliardica Pavese, 2002.

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24

Vigdor, Steven E. The Dark Side. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198814825.003.0006.

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Chapter 6 deals with the remaining mysteries in cosmology—dark matter, dark energy, and inflationary expansion—and the experiments aimed at solving them. It reviews the evidence for dark matter, and experiments to detect the microscopic particles proposed as its constituents: weakly interacting massive particles and invisible axions. Contrasts are drawn between the failure to understand the scale of dark energy theoretically and the ambitious new survey telescopes, such as the Large Synoptic Survey Telescope (or LSST), that aim to constrain its equation of state. The theoretical concepts and possible experimental signatures of cosmic inflation are described. Searches for possible imprints from primordial inflation-induced gravitational waves on the polarization of the cosmic microwave background (CMB polarization) are discussed in the context of the pioneering first detection by the Laser Interferometer Gravitational-Wave Observatory (or LIGO) of gravitational waves from distant black-hole mergers. Philosophical questions regarding the falsifiability of inflation are raised.
25

Mee, Nicholas. The Cosmic Mystery Tour. Oxford University Press, 2019. http://dx.doi.org/10.1093/oso/9780198831860.001.0001.

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The Cosmic Mystery Tour is a brief account of modern physics and astronomy presented in a broad historical and cultural context. The book is attractively illustrated and aimed at the general reader. Part I explores the laws of physics including general relativity, the structure of matter, quantum mechanics and the Standard Model of particle physics. It discusses recent discoveries such as gravitational waves and the project to construct LISA, a space-based gravitational wave detector, as well as unresolved issues such as the nature of dark matter. Part II begins by considering cosmology, the study of the universe as a whole and how we arrived at the theory of the Big Bang and the expanding universe. It looks at the remarkable objects within the universe such as red giants, white dwarfs, neutron stars and black holes, and considers the expected discoveries from new telescopes such as the Extremely Large Telescope in Chile, and the Event Horizon Telescope, currently aiming to image the supermassive black hole at the galactic centre. Part III considers the possibility of finding extraterrestrial life, from the speculations of science fiction authors to the ongoing search for alien civilizations known as SETI. Recent developments are discussed: space probes to the satellites of Jupiter and Saturn; the discovery of planets in other star systems; the citizen science project SETI@Home; Breakthrough Starshot, the project to develop technologies to send spacecraft to the stars. It also discusses the Fermi paradox which argues that we might actually be alone in the cosmos
26

Kolata, James J. Neutron Stars, Black Holes, and Gravitational Waves. Morgan & Claypool Publishers, 2019.

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27

Kolata, James J. Neutron Stars, Black Holes, and Gravitational Waves. Morgan & Claypool Publishers, 2019.

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28

Kolata, James J. Neutron Stars, Black Holes, and Gravitational Waves. Morgan & Claypool Publishers, 2019.

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29

Deruelle, Nathalie, and Jean-Philippe Uzan. The physics of black holes I. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786399.003.0049.

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This chapter describes two physical processes related to the Schwarzschild and Kerr solutions which can be induced by the gravitational field of a black hole. The first is the Penrose process, which suggests that rotating black holes are large energy reservoirs. Next is superradiance, which is the first step in the study of black-hole stability. The study of the stability of black holes involves the linearization of the Einstein equations about the Schwarzschild or Kerr solution. As this chapter shows, the equations of motion for perturbations of the metric are wave equations. The problem then is to determine whether or not these solutions are bounded.
30

Maurice H. P. M. van Putten. Gravitational Radiation, Luminous Black Holes and Gamma-Ray Burst Supernovae. Cambridge University Press, 2006.

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31

Maurice H. P. M. van Putten. Gravitational Radiation, Luminous Black Holes and Gamma-Ray Burst Supernovae. Cambridge University Press, 2009.

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32

Maurice H. P. M. van Putten. Gravitational Radiation, Luminous Black Holes and Gamma-Ray Burst Supernovae. Cambridge University Press, 2010.

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33

Maurice H. P. M. van Putten. Gravitational Radiation, Luminous Black Holes and Gamma-Ray Burst Supernovae. Cambridge University Press, 2006.

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34

Iyer, B. R., and B. Bhawal. Black Holes, Gravitational Radiation and the Universe: Essays in Honor of C.V. Vishveshwara. Springer, 2010.

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35

Guidry, Mike. Modern General Relativity: Black Holes, Gravitational Waves, and Cosmology. Cambridge University Press, 2019.

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36

Guidry, Mike. Modern General Relativity: Black Holes, Gravitational Waves, and Cosmology. Cambridge University Press, 2020.

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37

Maurice H. P. M. Van Putten. Gravitational Radiation, Luminous Black Holes and Gamma-Ray Burst Supernovae. Cambridge University Press, 2005.

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38

Maurice H. P. M. Van Putten. Gravitational Radiation, Luminous Black Holes, and Gamma-ray Burst Supernovae. Cambridge University Press, 2005.

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39

Iyer, B. R., and B. Bhawal. Black Holes, Gravitational Radiation and the Universe: Essays in Honor of C. V. Vishveshwara. Springer, 2013.

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40

Hogan, Peter A., and Claude Barrabès. Advanced General Relativity: Gravity Waves, Spinning Particles, and Black Holes. Oxford University Press, 2013.

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41

Hogan, Peter A. Advanced General Relativity: Gravity Waves, Spinning Particles, and Black Holes. Oxford University Press, Incorporated, 2013.

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42

Advanced General Relativity Gravity Waves Spinning Particles And Black Holes. Oxford University Press, 2013.

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43

KODUKULA, Siva Prasad. new type of black holes for wave Genetics. Lulu Press, Inc., 2010.

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44

Choquet-Bruhat, Yvonne. Introduction to General Relativity, Black Holes and Cosmology. Oxford University Press, 2014.

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45

Choquet-Bruhat, Yvonne. Introduction to General Relativity, Black Holes and Cosmology. Oxford University Press, Incorporated, 2014.

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46

Choquet-Bruhat, Yvonne. Introduction to General Relativity Black Holes and Cosmology. Oxford University Press, 2014.

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47

Hall, Michael J. W. General Relativity: An Introduction to Black Holes, Gravitational Waves, and Cosmology. Morgan & Claypool Publishers, 2018.

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48

Hall, Michael J. W. General Relativity: An Introduction to Black Holes, Gravitational Waves, and Cosmology. IOP Concise Physics, 2018.

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49

Hall, Michael J. W. General Relativity: An Introduction to Black Holes, Gravitational Waves, and Cosmology. Morgan & Claypool Publishers, 2018.

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50

Sedda, Manuel Arca, Elisa Bortolas, and Mario Spera. Black Holes in the Era of Gravitational-Wave Astronomy. Elsevier, 2023.

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