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Institute of Physics, Silesian University in Opava Gabriel Török GAČR 209/12/P740, CZ.1.07/2.3.00/20.0071 Synergy, GAČR 14-37086G, SGS-11-2013, www.physics.cz CO-AUTHORS: Eva Šrámková, Pavel Bakala, Kateřina Goluchová, Andrea Kotrlová, Vladimír Karas, Marek Abramowicz, Zdeněk Stuchlík, Wlodek Kluzniak, Martin Wildner, Dalibor Wzientek Predictions of HF-QPO models explored with LOFT
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Exploring signal from tori and spots with LOFT : Outline 1.Introduction: neutron star rapid X-ray variability, quasiperiodic oscillations, twin peaks, SPOTs and TORI 2.QPO frequencies, BH spin & epicyclic resonance model predictions 2.1 QPO frequencies and BH spin from geodesic models (summary of some older results by Torok et al, 2011, A&A) 2.2 Consideration of a>1 (Kotrlová et al 2014, A&A) 2.3 Nongeodesic effects (Šrámková et al 2014, submitted) 3.Observable signal from ER-tori and spots (RXTE vs. LOFT) 3.1 Spots – harmonic content of the signal (Bakala et al 2014, MNRAS) 3.2 Spots vs. tori (Bakala et al 2014, MNRAS) 4.Summary Tento projekt je spolufinancován Evropským sociálním fondem a státním rozpočtem České republiky
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LMXB Accretion disc 1. Introduction: LMXBs, quasiperiodic oscillations, HF QPOs Upper frequency [Hz] 3:2 HF QPOs
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1. Introduction: LMXBs, quasiperiodic oscillations, HF QPOs
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There is a large variety of ideas proposed to explain the QPO phenomenon [For instance, Alpar & Shaham (1985); Lamb et al. (1985); Stella et al. (1999); Morsink & Stella (1999); Stella & Vietri (2002); Abramowicz & Kluzniak (2001); Kluzniak & Abramowicz (2001); Abramowicz et al. (2003a,b); Wagoner et al. (2001); Titarchuk & Kent (2002); Titarchuk (2002); Kato (1998, 2001, 2007, 2008, 2009a,b); Meheut & Tagger (2009); Miller at al. (1998a); Psaltis et al. (1999); Lamb & Coleman (2001, 2003); Kluzniak et al. (2004); Abramowicz et al. (2005a,b), Petri (2005a,b,c); Miller (2006); Stuchlík et al. (2007); Kluzniak (2008); Stuchlík et al. (2008); Mukhopadhyay (2009); Aschenbach 2004, Zhang (2005); Zhang et al. (2007a,b); Rezzolla et al. (2003); Rezzolla (2004); Schnittman & Rezzolla (2006); Blaes et al. (2007); Horak (2008); Horak et al. (2009); Cadez et al. (2008); Kostic et al. (2009); Chakrabarti et al. (2009), Bachetti et al. (2010)…] For several models one can evaluate predicted QPO frequencies (frequency.mass spin functions) and compare these with observation… 2.1 QPO frequencies and BH spin from the geodesic QPO models
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Comparing the frequency.mass functions to the observation. For instance in the case of GRS 1915+105 (which here well represents all 3:2 microquasars). Spin a 2.1 QPO frequencies and BH spin from the geodesic QPO models Torok et al., (2011) A&A Clearly, different models imply very different spins…
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When the dimensionless spin reads a>1, the situation is more complicated. Nevertheless, some models still imply smooth frequency.mass functions of the spin. 2.2 Consideration of a>1 (naked sigularities or superspinars - NaS) BHNaS Kotrlová et al., (2014) A&A For several models, there is an alternative compatible with existence of a superspinning compact object. Only epicyclic resonance model then implies spin close to unity, while others imply values that are several times higher.
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2.2 Consideration of a>1 (naked sigularities or superspinars - NaS) Kotrlová et al., (2014) A&A More pairs of different 3:2 commensurable frequencies can be expected within a single source when a = 1 + small . Further treatment of this issue is rather difficult considering the present lack and low-resolution of the BH HF QPO data. It should, however, be resolvable using LOFT. The case of epicyclic resonance model
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2.3. Non-geodesic effects consideration within ER model Pressure supported fluid tori (ER tori), impact on the resonant frequency Šrámková et al., (2014), A&A submitted
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2.3. Non-geodesic effects consideration within ER model For low spins the non-geodesic effects are small. For high spins, resonant frequencies are RAPIDLY decreasing instead of increasing as the torus thickness rises. Thus, sources with a moderate spin should exhibit a smaller spread of the measured 3:2 QPO frequencies than sources with a near-extreme spin. Impact of pressure on the resonant frequency (to be tested with LOFT) Šrámková et al., (2014), in prep.
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Global Empirical Model of Variability and Spectra (GRS 1915+105, SPL State) Response Matrices (Detector) “DATA” Time and Spectral Distribution of Detected Counts TIMING ANALYSIS RESULTS TOTAL SOURCE FLUX MODEL + Comparing different orbital QPO models, RXTE and L QPO MODEL (SPOTs or TORUS) 3. Observable signal from ER tori and spots (RXTE vs. LOFT)
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Small spots moving along slightly eccentric orbits close to ISCO Left: RXTE Right: LOFT LOG POWER 3.1 Spots – harmonic content of the signal Bakala et al., 2014, MNRAS
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3.1 Spots vs. tori (comparison between specific models) Drifting spotsDrifting ER tori (opt. thin) Toy models of double peak QPOs assuming preferred orbits Harmonic content… Bakala et al., 2014, MNRAS
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4. Exploring signal from tori and spots with LOFT: Summary Epicyclic resonance model: predicts that individual sources with a moderate spin should exhibit a smaller spread of the measured 3:2 QPO frequencies than sources with a near-extreme spin (GRS-1915+105) or superspinars. Verification of this prediction requires large amount of high resolution data obtained with LOFT. [Kotrlová et. al 2014, A&A; Šrámková et al. 2014, A&A, submitted] Spots: The harmonic content of the circular spot signal should be clearly recognized using LOFT observations. [Bakala et. al 2014, MNRAS, see also poster of Karas et al. here] Spots vs. Tori: Specific model signatures such as harmonics unresolvable with RXTE can be crucial. Good examples of LOFT capabilities (although specific models): -e.g., circ. spot vs. opt. thin torus X elongated spot vs. opt. thick torus -see poster of Karas et al. (opt. thin torus) and talk of Pavel Bakala (opt. thick torus) here for more on this issues….
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THE END Thank you for your attention…
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