LOFT: the Large Observatory For X-ray Timing

Feroci, M.; Herder, J. W. den; Bozzo, E.; Barret, D.; Brandt, S.; Hernanz, M.; Klis, M. van der; Pohl, M.; Santangelo, A.; Stella, L.; Watts, Anna L.; Wilms, J.; Zane, S.; Ahangarianabhari, M.; Alpar, A.; Altamirano, D.; Álvarez, Laura; Amati, L.; Amoros, C.; Andersson, Nils; Antonelli, A.; Argan, A.; Artigue, R.; Azzarello, P.; Baldazzi, G.; Balman, Ş.; Barbera, Marco; Belloni, T.; Bertuccio, G.; Bianchi, S.; Bianchini, A.; Bodin, P.; Bidaud, J.-M. Bonnet; Boutloukos, Stratos; Braga, J.; Brown, Edward F.; Bucciantini, N.; Burderi, L.; Burša, Milan; Budtz-Jørgensen, Carl; Cackett, E.; Cadoux, F.; Caïs, Philippe; Caliandro, G. A.; Campana, R.; Campana, S.; Casella, P.; Chakrabarty, Deepto; Chenevez, J.; Coker, J.; Cole, Richard E.; Collura, A.; Courvoisier, T. J. L.; Cros, A.; Cumming, Andrew; Cusumano, G.; D’Aí, A.; D’Elia, V.; Monte, E. Del; Martino, D. de; Rosa, A. De; Cosimo, Sergio Di; Diebold, S.; Salvo, T. Di; Donnarumma, I.; Drago, A.; Durant, Martin; Emmanoulopoulos, D.; Evangelista, Y.; Fabian, A.; Falanga, M.; Favre, Y.; Feldman, Charlotte; Ferrigno, C.; Finger, M. H.; Fraser, G. W.; Fuschino, F.; Galloway, D. K.; Sanchez, J. L. Galvez; Garcı́a–Berro, E.; Gendre, B.; Gezari, Suvi; Giles, A. B.; Gilfanov, M.; Giommi, P.; Giovannini, G.; Giroletti, M.; Goldwurm, A.; Götz, D.; Gouiffès, C.; Grassi, M.; Groot, P.; Guidorzi, C.; Haas, D.; Hansen, Flemming Thorbjørn; Hartmann, D. H.; Haswell, C. A.; Heger, Alexander; Homan, J.; Hornstrup, A.; Hudec, R.; Huovelin, J.; Ingram, Adam; Zand, J. J. M. in't; Isern, J.; Israel, G. L.; Izzo, L.; Jonker, P. G.; Kaaret, P.; Karas, V.; Karelin, D.; Kataria, D. O.; Keek, L.; Kennedy, T.; Klochkov, D.; Kluźniak, W.; Kokkotas, Kostas D.; Korpela, Seppo A.; Kouveliotou, C.; Kreykenbohm, I.; Kuiper, L.; Kuvvetli, I.; Labanti, C.; Lai, Dong; Lamb, F. K.; Lebrun, F.; Lin, Dacheng; Linder, Dietmar; Lodato, Giuseppe; Longo, F.; Lund, N.; Maccarone, Thomas J.; Macera, D.; Maier, Daniel; Malcovati, P.; Mangano, V.; Manousakis, A.; Marisaldi, M.; Markowitz, A.; Martindale, A.; Matt, Giorgio; McHardy, I. M.; Melatos, A.; Méndez, Mariano; Migliari, S.; Mignani, Roberto; Miller, M. Coleman; Miller, J. M.; Mineo, T.; Miniutti, G.; Morsink, Sharon M.; Motch, C.; Motta, S.; Mouchet, M.; Muleri, Fabio; Norton, A. J.; Nowak, Michael A.; O’Brien, P. T.; Orienti, M.; Orio, Marina; Orlandini, M.; Orleański, P.; Osborne, J. P.; Osten, Rachel A.; Özel, Feryal; Pacciani, L.; Papitto, A.; Paul, Bikash Chandra; Perinati, E.; Petráček, V.; Portell, J.; Poutanen, Juri; Psaltis, Dimitrios; Rambaud, D.; Ramsay, Gavin; Rapisarda, M.; Rachevski, A.; Ray, Paul S.; Rea, N.; Reddy, Sanjay; Reig, P.; Aranda, M. Reina; Remillard, Ron; Reynolds, C. S.; Rodríguez‐Gil, P.; Rodríguez, J.; Romano, P.; Rossi, Elena M.; Ryde, F.; Sabau-Graziati, L.; Sala, G.; Salvaterra, R.; Sanna, A.; Schanne, S.; Schee, Jan; Schmid, Christian; Schwenk, A.; Schwope, A. D.; Seyler, J.-Y.; Shearer, A.; Smith, A.; Smith, David M.; Smith, Phil; Sochora, V.; Soffitta, P.; Soleri, P.; Stappers, B. W.; Steltzer, B.; Stergioulas, Nikolaos; Stratta, G.; Strohmayer, Tod E.; Stuchlík, Zdeněk; Suchy, S.; Sulemainov, V.; Takahashi, Tomohiro; Tamburini, Fabrizio; Tenzer, C.; Tolós, Laura; Török, Gabriel; Torrejón, José M.; Torres, D. F.; Tramacere, A.; Trois, A.; Turriziani, S.; Uter, P.; Uttley, P.; Vacchi, A.; Varnière, P.; Vaughan, S.; Vercellone, S.; Vrba, V.; Walton, D.; Watanabe, Shigeto; Wawrzaszek, R.; Webb, N.; Weinberg, Nevin N.; Wende, H.; Wheatley, P. J.; Wijers, R. A. M. J.; Wijnands, Rudy; Wille, M.; Wilson-Hodge, C.; Winter, B.; Wood, K. S.; Zampa, G.; Zampa, N.; Zampieri, L.; Zdziarski, A. A.; Zhang, Bing

doi:10.1117/12.926310

Cited by 56 publications

(52 citation statements)

References 40 publications

(29 reference statements)

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“…The largest effective area for fast X-ray timing presently being planned is ESA's LOFT (Feroci et al 2012). The Large Area Detector on LOFT would consist of ≈12 m 2 of silicon detectors and due to the larger collecting area and better (flatter) response above 6-7 keV would provide an increase in source count rate compared to the PCA on RXTE of about a factor of 30 (though the exact scaling would depend on the X-ray spectrum of the source being considered).…”

Section: Future Capabilities and Sensitivitiesmentioning

confidence: 99%

“…In Section 4 we discuss possible mode identifications for the best candidate frequency in J1751. We also briefly discuss how future observations with larger collecting area missions, such as ESA's Large Observatory for X-Ray Timing (LOFT; Feroci et al 2012) and the Advanced X-Ray Timing Array (Ray et al 2010), can improve the sensitivity of such searches. We conclude with a brief summary of our findings in Section 5.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A Non-Radial Oscillation Mode in an Accreting Millisecond Pulsar?

Strohmayer

Mahmoodifar

2014

ApJ

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We present results of targeted searches for signatures of non-radial oscillation modes (such as r-and g-modes) in neutron stars using RXTE data from several accreting millisecond X-ray pulsars (AMXPs). We search for potentially coherent signals in the neutron star rest frame by first removing the phase delays associated with the star's binary motion and computing fast Fourier transform power spectra of continuous light curves with up to 2 30 time bins. We search a range of frequencies in which both r-and g-modes are theoretically expected to reside. Using data from the discovery outburst of the 435 Hz pulsar XTE J1751−305 we find a single candidate, coherent oscillation with a frequency of 0.5727597 × ν spin = 249.332609 Hz, and a fractional Fourier amplitude of 7.46 × 10 −4 . We estimate the significance of this feature at the 1.6 × 10 −3 level, slightly better than a 3σ detection. Based on the observed frequency we argue that possible mode identifications include rotationally modified g-modes associated with either a helium-rich surface layer or a density discontinuity due to electron captures on hydrogen in the accreted ocean. In the latter case the presence of sufficient hydrogen in this ultracompact system with a likely helium-rich donor would present an interesting puzzle. Alternatively, the frequency could be identified with that of an inertial mode or a core r-mode modified by the presence of a solid crust; however, the r-mode amplitude required to account for the observed modulation amplitude would induce a large spin-down rate inconsistent with the observed pulse timing measurements. For the AMXPs XTE J1814−338 and NGC 6440 X−2 we do not find any candidate oscillation signals, and we place upper limits on the fractional Fourier amplitude of any coherent oscillations in our frequency search range of 7.8 × 10 −4 and 5.6 × 10 −3 , respectively. We briefly discuss the prospects and sensitivity for similar searches with future, larger X-ray collecting area missions.

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Section: Future Capabilities and Sensitivitiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Non-Radial Oscillation Mode in an Accreting Millisecond Pulsar?

Strohmayer

Mahmoodifar

2014

ApJ

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“…A possible way to circumvent this problem is to rely on the fact that all NSs in nature are spinning. Considering rotating NSs is of interest because near-future experiments in the electromagnetic spectrum -such as NICER (Gendreau et al 2012), LOFT (Feroci et al 2012), Astro-H (Takahashi et al 2012) and SKA (Watts et al 2015) -or in the gravitationalwave spectrum -such as Advanced LIGO (Aasi et al 2015), Advanced Virgo (Acernese et al 2015), KAGRA (Somiya 2012) and the Einstein Telescope (Sathyaprakash et al 2012) -could measure or constrain the additional multipoles that determine the structure of rotating NSs or other properties (such as the "Love numbers") that are related to their deformability. Spin-orbit coupling in binary pulsars may allow us to measure the moment of inertia (Damour & Schaefer 1988;Lattimer & Schutz 2005;Bejger et al 2005;Kramer & Wex 2009) and gravitationalwave observations may be used to infer the tidal Love numbers, as well as additional information on the EOS (Mora & Will 2004;Berti et al 2008;Read et al 2009;Hinderer et al 2010;Vines et al 2011;Damour et al 2012;Del Pozzo et al 2013;Favata 2014;Lackey et al 2014;Chatziioannou et al 2015b;Dietrich et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Low-mass neutron stars: universal relations, the nuclear symmetry energy and gravitational radiation

Silva

Sotani

Berti

2016

Mon. Not. R. Astron. Soc.

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The lowest neutron star masses currently measured are in the range 1.0 − 1.1 M ⊙ , but these measurement have either large uncertainties or refer to isolated neutron stars. The recent claim of a precisely measured mass M/M ⊙ = 1.174±0.004 (Martinez et al. 2015) in a double neutron star system suggests that low-mass neutron stars may be an interesting target for gravitational-wave detectors. Furthermore, Sotani et al. (2014) recently found empirical formulas relating the mass and surface redshift of nonrotating neutron stars to the star's central density and to the parameter η ≡ (K 0 L 2 ) 1/3 , where K 0 is the incompressibility of symmetric nuclear matter and L is the slope of the symmetry energy at saturation density. Motivated by these considerations, we extend the work by Sotani et al. (2014) to slowly rotating and tidally deformed neutron stars. We compute the moment of inertia, quadrupole moment, quadrupole ellipticity, tidal and rotational Love number and apsidal constant of slowly rotating neutron stars by integrating the Hartle-Thorne equations at second order in rotation, and we fit all of these quantities as functions of η and of the central density. These fits may be used to constrain η, either via observations of binary pulsars in the electromagnetic spectrum, or via near-future observations of inspiralling compact binaries in the gravitationalwave spectrum.

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“…Since the NS equation of state (EoS) -the relation between state variables such as pressure and density -is unknown, one must fit all of these parameters to the data independently, thus diluting the information that can be extracted. Reducing the number of independent parameters in an EoS independent way would help extract more information from observables [17,18], and in particular, it may allow for the precise extraction of the NS mass and radius with NICER [19] and LOFT [20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Four-hair relations for differentially rotating neutron stars in the weak-field limit

2015

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The opportunity to study physics at supra-nuclear densities through X-ray observations of neutron stars has led to in-depth investigations of certain approximately universal relations that can remove degeneracies in pulse profile models. One such set of relations determines all of the multipole moments of a neutron star just from the first three (the mass monopole, the current dipole and the mass quadrupole moment) approximately independently of the equation of state. These three-hair relations were found to hold in neutron stars that rotate rigidly, as is the case in old pulsars, but neutron stars can also rotate differentially, as is the case for proto-neutron stars and hypermassive transient remnants of binary mergers. We here extend the three-hair relations to differentially rotating stars for the first time with a generic rotation law using two approximations: a weak-field scheme (an expansion in powers of the neutron star compactness) and a perturbative differential rotation scheme (an expansion about rigid rotation). These approximations allow us to analytically derive approximately universal relations that allow us to determine all of the multipole moments of a (perturbative) differentially rotating star in terms of only the first four moments. These new fourhair relations for differentially rotating neutron stars are found to be approximately independent of the equation of state to a higher degree than the three-hair relations for uniformly rotating stars. Our results can be instrumental in the development of four-hair relations for rapidly differentially rotating stars in full General Relativity using numerical simulations.

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LOFT: the Large Observatory For X-ray Timing

Cited by 56 publications

References 40 publications

A Non-Radial Oscillation Mode in an Accreting Millisecond Pulsar?

A Non-Radial Oscillation Mode in an Accreting Millisecond Pulsar?

Low-mass neutron stars: universal relations, the nuclear symmetry energy and gravitational radiation

Four-hair relations for differentially rotating neutron stars in the weak-field limit

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