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Luminous Dark Matter Brian Feldstein arXiv:1008.1988 -B.F., P. Graham and S. Rajendran.

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Presentation on theme: "Luminous Dark Matter Brian Feldstein arXiv:1008.1988 -B.F., P. Graham and S. Rajendran."— Presentation transcript:

1 Luminous Dark Matter Brian Feldstein arXiv:1008.1988 -B.F., P. Graham and S. Rajendran

2 Dark Matter- The Standard Story -Roughly 23% of the universe seems to consist of some form of non-baryonic dark matter. -A compelling possibility: Weakly Interacting Massive Particles (WIMPs) -Weak Scale cross sections give approximately the right relic abundance:

3 Dark Matter Direct Detection -Look for nuclear recoils due to dark matter scattering. -Many such experiments: CDMS, XENON, CRESST, etc.. -Limits placed on cross section vs mass. -modified from arxiv:1005.0380

4 The DAMA Mystery - DAMA sees an 8.9σ annual modulation in its nuclear recoil events. -arxiv:0804.2741 - Phase is consistent with Dark Matter induced recoils.

5 -There is no recognized standard model explanation for the DAMA signal. -DAMA looked at: Neutron flux, temperature variation, muons, neutrinos, etc.. -All calculated signal rates are much too small to explain the signal. -But: standard WIMPs capable of explaining DAMA also seem completely ruled out!

6 Meanwhile... -CoGeNT reports an excess of events over background predictions.. -CRESST reports an excess of Oxygen band events (not yet published, exposure not specified)... -CDMS-II reports 2 events in signal region with a background of 1 event...

7 Looking for an explanation… -No experiment can rule out a dark matter origin for the DAMA signal in a model independent way. -Many Experimental Uncertainties… Present Status: - Various Light Dark Matter Possibilities.. -May be able to incorporate CoGeNT, but probably ruled out by Xenon10 (see talks by Peter Sorensen). - Inelastic Dark Matter? - More exotic alternatives...

8 Electromagnetic Energy Deposit - A tantalizing possibility..  Most experiments discard electromagnetic events as background.. DAMA does not.  DAMA’s annual modulation search is precisely what allows them to do this!

9 - But.. purely electronic interactions don’t work..  Scattering gives a bad spectrum..  Absorption gives negligible annual modulation. -arxiv:0907.3159 -Pospelov, Ritz, Voloshin

10 Enter Luminous Dark Matter...  Energy is deposited directly through photons.  Upscatter, and then decay to a ~3keV photon. - A line fits the DAMA spectrum well:

11 - A very simple possibility:  A single magnetic dipole operator. - Can mediate both the upscattering and the decay. -Requires only a Dirac fermion with a magnetic dipole interaction, plus a Majorana mass splitting. - We take

12 Note: Upscatter and decay do not both have to occur inside the detector!  Excited state can travel a very large distance. - As long as the decay length is <<, Upscatter Rate ≈ Signal Rate.  Signal rates depend only on detector volume... - Can boost the modulation fraction as in usual inelastic dark matter.

13 Simplifying assumptions... - Composition of the Earth.. - Angular (in)dependence of the scattering.. - assume nuclei are infinitely heavy.. - true cross sections are angular independent at threshold anyway..

14 Calculate the Event Rate... σ ~ e 2 Z 2 / 4πΛ 2 Γ ~ δ 3 / πΛ 2

15 Constraints.. -The upscattering events are undetected at direct detection experiments, for dark matter lighter than a couple of GeV.. -But.. it’s no longer really true that experiments other than DAMA are insensitive to electromagnetic events!!  Our only freedom to avoid problems is the annual modulation fraction. - XENON100, in particular, is fairly constraining.

16 - XENON100 has low electromagnetic background.. XENON10: ~300kg days: XENON100: ~400kg days:

17  XENON100 constrains the modulation fraction to be larger than about 50%.  This puts an upper bound on the allowed dark matter masses.. scattering must be near threshold. - It is actually relevant that XENON100 has only presented data from the winter!  As usual, there may be large experimental uncertainty..

18 X-Ray Satellites - Generally, Earth based experiments have large radioactive background... What about satellite experiments?  Potentially dangerous, since they can probe long distances:

19 - The satellites measure the photon flux in terms of photons/ cm 2 s sr.  We predict roughly ~ L / 4π. Typical decay length ~ v f / Γ  Essentially limits the allowed decay lengths from above.

20  Compare with the cosmic x-ray background measurements of e.g. the SWIFT or RTXE satellites.  Requires decay lengths less than ~1000km. -arxiv:0811.1444

21 Parameter Space Blue: Xenon100 Red: SWIFT Yellow: relic density  DM proton cross sections of

22 Less Important Constraints.. - Collider searches require Λ > TeV. -CDMS analysis of electromagnetic events requires modulation fractions > 25%.

23 CMB Constraint  1 GeV dark matter with thermal relic annihilation cross section to photons seems ruled out.. - Galli, Iocco, Bertone, Melchiorri but…

24  Luminous dark matter has a built in mechanism to avoid this constraint! - In the early universe, both the dark matter particle and its excited state are present in the thermal bath. - Before recombination, however, the excited state is gone…  A single magnetic dipole moment vertex no longer mediates annihilation.  Need two of them… much more suppressed! (perhaps this is a useful mechanism outside the context of this model)

25 Other constraints we checked.... but which are irrelevant: - CoGeNT:  Sensitive to electromagnetic events, but their background is ~10 times too high. (We have nothing to say about a possible signal at CoGeNT.. the energy range is wrong..) - CAST (axion telescope):  Searching for x-rays, but their background is more than ~100 times too high.

26 - X-ray line emission:  The dark matter particle can upscatter off of, e.g., Hydrogen throughout the galaxy. The subsequent decays contribute to the x-ray background, but are safe by ~7 orders of magnitude. - Neutrino detectors, e.g. SuperK:  Trigger thresholds are too high.. ~ MeV. - Directional dark matter detectors:  Thresholds also currently too high.

27 Conclusions -DAMA is still a compelling mystery, but one which is becoming harder to explain as time goes on.. -Unlike most other direct detection experiments, DAMA does not throw away purely electromagnetic events. -Upscattering of dark matter to an excited state which decays via emission of a photon can explain the DAMA result without contradicting other experiments. -Only a single magnetic dipole interaction is needed for both the upscattering and decay. -XENON100 should be able to essentially rule out or confirm the scenario very soon.

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