Looking for True X-ray Modulation through Energy Quantiles

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Looking for True X-ray Modulation through Energy Quantiles Jaesub Hong Spring, 2011

Outline The X-ray sources in the Galactic Bulge Quantile Analysis Periodic Bulge X-ray Sources and Modulating Energy Quantiles

Galactic Center Region (32’ x 16’) X-ray (Blue, Purple): NASA/CXC/UMass/D. Wang et al. Optical/nIR (Yellow) : NASA/ESA/STScI/D. Wang et al. IR (Red) : NASA/JPL-Caltech/SSC/S. Stolovy

X-ray Sources in the Galactic Center Region Chandra/ACIS shallow survey of 2 deg x 1 deg around Sgr A* ~1300 discrete X-ray sources (Wang et al. 2002)

X-ray sources in the Galactic Center (GC) Chandra’s superb spatial resolution revealed >3000 low luminosity X-ray sources in the Galactic center region Formation and evolutionary history of the inner Galaxy Accreting Binary Systems and their evolution What are these X-ray sources? 8.5’ x 8.5’ Sgr A* (~500 ks Chandra ACIS) Muno et al. 2003

Galactic Bulge Survey Deep Bulge Window Survey (100 ks Chandra, HST & Magellan) Baade’s Window (BW, Av~1.3) Stanek’sWindow (SW, Av~2.0) The Limiting Window (LW, Av~4.0) vs. Galactic Center (GC, Av~25) Hong 2009, van den Berg 2006, 2009 Shallow Bulge Latitude Survey (15 ks Chandra & Magellan) 1 deg x 1.2 deg south and north region of the GC Grindlay 2011

The Limiting Window (1.4 deg south of the GC) 100 ksec Bulge Survey (Hong et al 2009) + 900 ksec Ultra-deep Survey (Revnivtsev et al 2009)

Galactic Ridge X-ray Emission Resolved fraction of X-ray emission 1 Ms Chandra observations of a low extinction region, the Limiting Window, at 1.4 south of the GC ~ 80% of the X-ray emission was resolved at energies > 6 keV Resolved fraction of X-ray emission Revnivtsev et al. 2009

Bulge X-ray Sources At the Galactic Center Low Luminosity: 1030-33 erg/s Relatively Hard X-ray Spectra (Power law Photon Index ~ 0.7) Quiescent High Mass X-ray Binaries (qHMXBs): <10% (Laycock et al 2005) Magnetic Cataclysmic Variables (CVs) In the Window Fields Also see relatively Soft X-ray Sources >1030-31 erg/s Quiescent Low Mass X-ray Binaries (qLMXBs) Non-Magnetic Cataclysmic Variables <1030-31 erg/s Active Binaries (ABs)

Cataclysmic Variables (CVs): Compact Binaries with white dwarf accreting from late type companion Mark Garlick Mark Garlick Non-Magnetic CVs Polars

Cataclysmic Variables (CVs): Compact Binaries with white dwarf accreting from late type companion Mark Garlick Intermediate Polars

Direct Identification At the Galactic Center AV ~ 25, AK~5 Confusion limit: K~15 with Magellan/PANIC (6. 5m) In the Windows fields (AV< 4) mV >20-23 many candidate counterparts, no guarantee HST ACS/F625W image with 1” 95 % conf. radius

Source identification in Windows/HST fields (100 ks) X-ray sources In HST/ACS CV candidates Predicted BW 403 162 4 - 9 7 SW 433 139 2 - 10 14 LW 319 100 13 - 25

X-ray sources in the Galactic Bulge: More from X-ray data Variable X-ray sources e.g. Scargle’s Bayesian Block Searches 4 Transients within 1pc vs. 7 in 25 pc (Muno et al 2005) 8 Transients in the GCR: quiescent LMXBs (Degenaar et al 2009, 2010) Periodic X-ray sources Lomb-Scargle Buccheri’s z2 statistics Epoch Folding ..... 9 Periodic sources in the GCR: magnetic CVs (Muno et al 2003, 2009)

10 periodic sources and 11 candidates The Limiting Window ( 1Ms Chandra/ACIS-I) 10 periodic sources and 11 candidates Hong et al 2010, arXiv:1103.2477

Variable X-ray sources in the Bulge Fields (not complete) Fields Periodic Variables BW (100 ksec) 1 - SW (100 ksec) LW (1 Msec) 10 + 11 ~80 (short + long) GCR (1+1 Msec) (Muno et al) 9 856 (long) + 198 (short)

The Limiting Window ( 1Ms Chandra/ACIS-I) absorption Intrinsically hard Very hard spectra 20-30% of hard X-ray sources can be periodic (Hong et al 2010, arXiv:1103.2477)

Extracting Spectral Properties or Variations from faint X-ray sources Hardness Ratio HR1 =(H-S)/(H+S) or HR2 = log10(H/S) e.g. S: 0.3-2.5 keV, H: 2.5-8.0 keV HR1= 1 HR1 = 1 Bayesian Estimation of Hardness Ratios (BEHR) Park et al, 2006, ApJ

Quantiles Low count requirements for quantiles: spectral-independent 2 counts for median 3 counts for terciles and quartiles No energy binning required Take advantage of energy resolution Optimal use of information Median (E50) = 3.7 keV Median (E50) = 6.5 keV

X-ray Spectral Models of Astronomical Objects Power law (Photon Index: ) Black Body (Temperature: kT) Thermal Brems. (Plasma Temperature: kT) MeKaL or APEC (Plasma Temperature: kT, Abundance, …) …. + Interstellar Absorption (NH) Goal: acquire two parameters to describe basic spectral shapes. cf. Hardness ratio using three bands: S, M, H => HR1 = S/M, HR2 = M/H

Two independent parameters from Quantiles Median (E50) Energy Energy Energy Quartile Ratio (E75/E25) Energy Energy Energy

Quantile Diagram Quantiles are not independent m=Q50 vs Q25/Q75 Power-Law :  & NH Proper spacing in the diagram Absorption More Intrinsically Hard ACIS-S detector 0.3-8.0 keV

50 source count/ 25 background count Quantile Diagram 0.3-8.0 keV Conventional X-ray Color-Color Diagram 0.3-0.9-2.5-8.0 keV

Quantile Diagrams for Windows and Galactic Center Fields

Future Improvement of Quantile Analysis Logit (Median) => Log (Median) Quantiles for Photons with Weighting e.g. Swift/BAT: each count with weight Allows a unified phase space for a given energy band regardless of response function => Atlas of X-ray spectral type, Physical meaning in Quantiles Improve Error Estimates

Magnetic CV in Baade’s Window : CXOPS J180354.3 – 300005 (1028.3 s) absorption Intrinsically hard

Magnetic CV in LW : CXOPS J175118.7 – 293811 (4731 s)

Cataclysmic Variables (CVs): white dwarf with late type companion Intermediate Polars

Evans & Hellier 2007

1576 s 4730 s 9461 s

1576 s 4730 s 9461 s

Bright X-ray source in ChaMPLane (van den Berg et al 2011)

Bright X-ray source in ChaMPLane (Servillat et al 2011)

Bright X-ray source in ChaMPLane

Modulation associated with peculiar spectral state Observables vs. Phase folded at P Phase folded at P’ Not much variations Noticeable variations

Pattern or order of values gives a clue? Observables vs. Phase folded at P Phase folded at P’ Chaotic Orderly e.g. DisCan for quantum gravity photon disperson: Scargle, Norris, Bonnel, 2008 Sharpness : Shannon, Reny, Fisher information, variance

Summary The sheer number of Bulge X-ray sources indicate their importance in understanding the evolutionary history of accreting binaries and the inner Galaxy. But the large number of them are not identified. High obscuration, faint optical flux and source crowding limit direct spectroscopic identification. X-ray variability provides another clue. Sometimes multiple periodicities are observed: not all of them are independent. Energy quantiles (or equivalent quantities) might help revealing the true periodicity. Further study is needed to assign credible statistical significance.

Magnetic CVs in LW

Evans &Hellier 2007

Identifying X-ray Sources by Periodicity (Lomb-Scargle Method) A Magnetic CV in Baade’s Window (100 ks) : CXOPS J180354.3 – 300005 (1028.3 s) Hong et al, ApJ, 2009

Chandra ACIS Image of BW and the LW ~320 – 400 X-ray sources with 100 ks

Realistic Cases E50%= An ideal detector ACIS-I response

Realistic Cases E50%= An ideal detector ACIS-S response

Quantile Diagram Quantiles are not independent m=Q50 vs Q25/Q75 Power-Law :  & NH Proper spacing in the diagram Absorption More Intrinsically Hard An ideal detector 03-8.0 keV