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The Fainting of Alpha Centauri A, Resolved! T. R. Ayres (CASA), and friends.

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Presentation on theme: "The Fainting of Alpha Centauri A, Resolved! T. R. Ayres (CASA), and friends."— Presentation transcript:

1 The Fainting of Alpha Centauri A, Resolved! T. R. Ayres (CASA), and friends

2 Warning: this talk deals with the two bottom-most rungs of Drake’s Ladder, where sadly the sexiness is low, but on positive side the knowledge content was though to be high; even so, a few surprises still were to be found…

3 The Alpha Centauri triple system has two solar-like stars separated by about Sun-Saturn distance, and a dim red dwarf about 10,000 au away (toward us). System is slightly metal rich compared with Sun, and slightly older by ~1 Gyr. The G2 V primary (“Alpha Cen A”) is a near twin of our own star.

4 Alpha Cen first was detected in X-rays by HEAO-I; later resolved by Einstein HRI. Surprising result: smaller Alpha Cen B was twice as X- ray luminous as bigger A. ROSAT HRI could easily separate the two stars during 1990’s, and carried out a long term campaign to measure their coronal activity.

5 M ulti-year ROSAT HRI record showed short term “rotational modulations” (active regions rotating onto, and off, the visible hemisphere); long term changes probably analogous to 11-year sunspot cycle; and conspicuous flares on K dwarf (but not G star). (Schmitt & Liefke)

6 Early in Chandra era (late 1999), LETGS spectrum of Alpha Cen captured both stars: A is at top, B at bottom. The companions were similar in coronal temperature, 1-2 MK, B slightly hotter than A. (Raassen et al.)

7 As in final ROSAT observation, LETG showed both stars at similar coronal intensities, again somewhat below previous values.

8 More recent observations of Alpha Cen by XMM- Newton: MOS1 at top and pn at bottom (0.2-2 keV). Primary star (“A”) is clearly visible in first observation, but disappears by mid-2004: behavior unprecedented for solar corona, challenging our understanding of stellar magnetic dynamos. (Robrade, Schmitt, & Favata)

9 Owing to relatively poor XMM spatial resolution, psf “background” at A contributed by B sets fundamental limit on detectability of primary.

10 Multi-year XMM campaign showed a stunning “fainting” of G star by factor of ~50X in 0.2-2 keV band. Sun’s coronal variations over cycle are thought to be only ~5-6X.

11 Fe XII 195 (1 MK) images of Sun over most recent solar cycle. Significant coronal emission persists even at cycle minimum (left). “Fuzzy ball” appearance arises from small clumps of magnetic flux produced by direct convective “local dynamo” action independent of deep seated “big dynamo” responsible for major sunspot groups and their decadal ebb and flow (right: solar max).

12 Coronal Temperature effect??? Energy conversion factors for 0.2-2 keV band are relatively insensitive to Tcor…

13 Since Y2000, Alpha Cen orbit has been closing rapidly and no longer is easily resolvable by XMM-Newton (but still trivial for Chandra). HRC-I exposures beginning Oct 2005 recovered both stars: A low compared to 1990’s, but not as low as XMM, and B declining. What’s going on? New LETGS spectrum (June 2007) holds key. (Note proper motion & parallax of Alpha Cen.)

14 Chandra LETGS spectrum taken last month. B is at top, A at bottom. Note fading of A at shorter wavelengths: strikingly different appearance than in 1999.

15 LETGS spectra of active Alpha Aur (6 MK), low activity Alpha CMi (3 MK), and Alpha Cen stars in the two epochs. Note weakening of A (blue curves,two bottom panels) in 2007 in T> 1 MK features. (Spectra derived by “optimal extraction” and divided by reference traces-- WD at longer wavelengths, AGN at shorter--to remove EA structure.)

16 In conversion to fluxes in broad 0.06-6 keV band, all the ECFs, particularly XMM, show strong dependence on Tcor. (Higher values= lower sensitivity: fewer counts per unit energy emitted at source.) Dashed curve depicts % of 0.2-2 keV emission in full 0.06-6 keV band: 0.2-2 keV emission is good proxy for total, but only above a few MK.

17 Revised time series: post-2002 ECF’s for A at 1 MK, those for B, 2 MK, for broad 0.06-6 keV band. Now XMM has moved closer to Chandra, less challenging to our expectations for stellar cycles. In hindsight, extreme darkening of Alpha Cen seen by XMM in 0.2-2 keV band has precedence on Sun, but was not so obvious in stars during ROSAT era owing to poor energy discrimination of PSPC. (Yellow shaded: range of solar cycle 0.1-2.4 keV from Judge, Solomon, & Ayres.)

18 Higher-energy Yohkoh imaging, 1996-2006: 2-3 MK emission is almost exclusively associated with active regions overlying sunspot groups.

19 Summary Although XMM-Newton recorded a stunning decline in the 0.2-2 keV L X of Alpha Cen A, Chandra LETGS has revealed that the “disappearance” in X-rays was due to “global cooling,” not a collapse of the coronal emission measure (i.e., “heating” didn’t turn off). This behavior has a natural explanation in the solar cycle, and we thus need not be overly apprehensive concerning the “fainting” of the solar twin (and what it might have foreboded for our own star).


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