The Large Observatory for X-ray Timing (LOFT)

Feroci, M.; Stella, L.; Klis, M. van der; Courvoisier, T. J. L.; Hernanz, M.; Hudec, R.; Santangelo, A.; Walton, D.; Zdziarski, A. A.; Barret, D.; Belloni, T.; Braga, J.; Brandt, S.; Budtz-Jørgensen, Carl; Campana, S.; Herder, J. W. den; Huovelin, J.; Israel, G. L.; Pohl, M.; Ray, Paul S.; Vacchi, A.; Zane, S.; Argan, A.; Attinà, Primo; Bertuccio, G.; Bozzo, E.; Campana, R.; Chakrabarty, Deepto; Costa, E.; Rosa, A. De; Monte, E. Del; Cosimo, Sergio Di; Donnarumma, I.; Evangelista, Y.; Haas, D.; Jonker, P. G.; Korpela, Seppo A.; Labanti, C.; Malcovati, P.; Mignani, Roberto; Muleri, Fabio; Rapisarda, M.; Rashevsky, A.; Rea, N.; Rubini, A.; Tenzer, C.; Wilson-Hodge, C.; Winter, B.; Wood, K. S.; Zampa, G.; Zampa, N.; Abramowicz, Marek A.; Alpar, M. A.; Altamirano, D.; Álvarez, Jose M.; Amati, L.; Amoros, C.; Antonelli, L. A.; Artigue, R.; Azzarello, P.; Bachetti, Matteo; Baldazzi, G.; Barbera, Marco; Barbieri, C.; Basa, S.; Baykal, A.; Belmont, R.; Boirin, L.; Bonvicini, V.; Burderi, L.; Burša, Milan; Cabanac, C.; Cackett, Edward M.; Caliandro, G. A.; Casella, P.; Chaty, S.; Chenevez, J.; Coe, M. J.; Collura, A.; Corongiu, A.; Covino, S.; Cusumano, G.; D'Amico, F.; Dall’Osso, S.; Martino, D. de; Paris, G. De; Persio, G. Di; Salvo, T. Di; Done, Chris; Dovčiak, Michal; Drago, A.; Ertan, Ünal; Fabiani, Sergio; Falanga, M.; Fender, R. P.; Ferrando, P.; Ferreira, Desiree Della Monica; Fraser, George W.; Frontera, F.; Fuschino, F.; Gálvez, José Luis; Gandhi, P.; Giommi, P.; Godet, O.; Göǧüş, E.; Goldwurm, A.; Götz, D.; Grassi, M.; Guttridge, P.; Hakala, Pasi; Henri, G.; Hermsen, W.; Horák, Jiří; Hornstrup, A.; Zand, J. J. M. in't; Isern, J.; Kalemci, Emrah; Kanbach, G.; Karas, V.; Kataria, D. O.; Kennedy, T.; Klochkov, D.; Kluźniak, W.; Kokkotas, Kostas D.; Kreykenbohm, I.; Krolik, Julian H.; Kuiper, L.; Kuvvetli, I.; Kylafis, N. D.; Lattimer, James M.; Lazzarotto, F.; Leahy, D. A.; Lebrun, F.; Lin, Dacheng; Lund, N.; Maccarone, Thomas J.; Malzac, J.; Marisaldi, M.; Martindale, A.; Mastropietro, Michele; McClintock, Jeffrey E.; McHardy, I. M.; Méndez, Mariano; Mereghetti, S.; Miller, M. Coleman; Mineo, T.; Morelli, E.; Morsink, Sharon M.; Motch, C.; Motta, S.; Muñoz-Darias, T.; Naletto, G.; Neustroev, V.; Nevalainen, J.; Olive, J. F.; Orio, Marina; Orlandini, M.; Orleański, P.; Özel, Feryal; Pacciani, L.; Paltani, S.; Papadakis, I. E.; Papitto, A.; Patruno, A.; Pellizzoni, A.; Petráček, V.; Pétri, Jérôme; Petrucci, P.-O.; Phlips, Bernard F.; Picolli, L.; Possenti, A.; Psaltis, Dimitrios; Rambaud, D.; Reig, P.; Remillard, Ron; Rodríguez, J.; Romano, P.; Romanova, M. M.; Schanz, T.; Schmid, Christian; Segreto, A.; Shearer, A.; Smith, A.; Smith, Phil; Soffitta, P.; Stergioulas, Nikolaos; Stolarski, M.; Stuchlík, Zdeněk; Tiengo, A.; Torres, D. F.; Török, Gabriel; Turolla, R.; Uttley, P.; Vaughan, S.; Vercellone, S.; Waters, Rens; Watts, Anna L.; Wawrzaszek, R.; Webb, N.; Wilms, J.; Zampieri, L.; Zezas, A.; Ziółkowski, J.

doi:10.1007/s10686-011-9237-2

Cited by 194 publications

(140 citation statements)

References 31 publications

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“…as suggested for use on the proposed Large Observatory for X-ray Timing, LOFT (Feroci et al 2012). This technology could affordably reach collecting areas two orders of magnitude larger than XMM-Newton at Fe K and harder energies, while maintaining CCD-like energy resolution.…”

Section: Future X-ray Observatoriesmentioning

confidence: 99%

X-ray reverberation around accreting black holes

Uttley

Cackett

Fabian³

et al. 2014

Astron Astrophys Rev

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448

606

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Luminous accreting stellar mass and supermassive black holes produce power-law continuum X-ray emission from a compact central corona. Reverberation time lags occur due to light travel time-delays between changes in the direct coronal emission and corresponding variations in its reflection from the accretion flow. Reverberation is detectable using light curves made in different X-ray energy bands, since the direct and reflected components have different spectral shapes. Larger, lower frequency, lags are also seen and are identified with propagation of fluctuations through the accretion flow and associated corona. We review the evidence for X-ray reverberation in active galactic nuclei and black hole X-ray binaries, showing how it can be best measured and how it may be modelled. The timescales and energy-dependence of the high frequency reverberation lags show that much of the signal is originating from very close to the black hole in some objects, within a few gravitational radii of the event horizon. We consider how these signals can be studied in the future to carry out X-ray reverberation mapping of the regions closest to black holes.

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Section: Future X-ray Observatoriesmentioning

confidence: 99%

X-ray reverberation around accreting black holes

Uttley

Cackett

Fabian³

et al. 2014

Astron Astrophys Rev

Self Cite

448

606

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“…In turn, this would improve the prospects that analysis of gravitational waveforms from NS-NS or NS-BH binaries will inform us about the properties of those stars. In particular, if the radius of these stars as well as their masses can be inferred with precision and reliability, this will serve as a valuable input to nuclear physics theories (see [164,165,166] for a discussion of the current systematics-dominated estimates of radii, as well as of the good prospects for measuring radii using X-ray observations with the NASA mission NICER [167] and the planned European Space Agency (ESA) mission LOFT [168]). Plans are also being made for third-generation detectors such as the proposed Einstein Telescope [169], which would have 10-km underground arms and many other advances; this could reach ten times the sensitivity of Advanced LIGO and would thus greatly increase both the rates and precision of observations.…”

Section: Summary and Future Prospectsmentioning

confidence: 99%

Implications of the gravitational wave event GW150914

Miller

2016

Gen Relativ Gravit

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The era of gravitational-wave astronomy began on 14 September 2015, when the LIGO Scientific Collaboration detected the merger of two ∼ 30 M ⊙ black holes at a distance of ∼ 400 Mpc. This event has facilitated qualitatively new tests of gravitational theories, and has also produced exciting information about the astrophysical origin of black hole binaries. In this review we discuss the implications of this event for gravitational physics and astrophysics, as well as the expectations for future detections. In brief: (1) because the spins of the black holes could not be measured accurately and because mergers are not well calculated for modified theories of gravity, the current analysis of GW150914 does not place strong constraints on gravity variants that change only the generation of gravitational waves, but (2) it does strongly constrain alterations of the propagation of gravitational waves and alternatives to black holes. Finally, (3) many astrophysical models for the origin of heavy black hole binaries such as the GW150914 system are in play, but a reasonably robust conclusion that was reached even prior to the detection is that the environment of such systems needs to have a relatively low abundance of elements heavier than helium.

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“…The development of large-area silicon-drift detectors puts such detector areas within reach for launch in the 2020s, e.g. the proposed LOFT mission (Feroci et al 2012). Furthermore, in the soft X-ray band the ATHENA mission, which is now confirmed for launch in the late 2020s, will allow significant advances in studying lags of disc blackbody components and soft X-ray reverberation in AGN (Nandra et al 2013).…”

Section: Advances In Observational Capabilitiesmentioning

confidence: 99%

Multi-Wavelength Variability

Uttley

Casella

2014

Space Sci Rev

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Multiwavelength variability data, combined with spectral-timing analysis techniques, provides information about the causal relationship between different physical components in accreting black holes. Using fast-timing data and long-term monitoring, we can probe the behaviour of the same components across the black hole mass scale. In this chapter we review the observational status of multiwavelength variability in accreting black holes, from black hole X-ray binaries to AGN, and consider the implications for models of accretion and ejection, primarily considering the evidence for accretion disc and jet variability in these systems. We end with a consideration of future prospects in this quickly-developing field.

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The Large Observatory for X-ray Timing (LOFT)

Cited by 194 publications

References 31 publications

X-ray reverberation around accreting black holes

X-ray reverberation around accreting black holes

Implications of the gravitational wave event GW150914

Multi-Wavelength Variability

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