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Non-minimal cold dark matter particles
Marc Kamionkowski
Caltech
Bonn29 Aug 2005
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Plan
• Review of standard weakly interacting massive particle scenario
• (Possible) problems with CDM on small scales• Self-interacting dark matter• WIMPs from charged-particle decay (Sigurdson,
MK; Sigurdson, Caldwell, Doran, Kurylov, MK)
• “How dark is `dark’?” Dark-matter dipole moments
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What do we know?
• Compelling cosmological evidence that nonbaryonic (non SM) dark matter exists.
• .
• Dark matter must be ‘dark’ matter.
• But empirically, know little else….
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Good news: cosmologists don't need to "invent" new
particle:• Weakly Interacting
Massive Particles (WIMPS). e.g.,neutralinos
• Axions
ma~10-(3-6) eV
arises in Peccei-Quinn
solution to strong-CP
problem
v
cmhχ
sec/103 3272 ×≈Ω(e.g., Jungman, MK, Griest 1996)
(e.g., Raffelt 1990; Turner 1990)
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WIMPsWIMPsRelic Density: Ωχh2≈( 3x10-26 cm3/sec / χχsm)
vh
13272 scm103⋅≈Ω
v Annihilation cross section χχsm of Weak Interaction strength gives right answer
Prospects for detection:
Detection
direct
indirect
Neutrinosfrom sun/earth
anomalouscosmic rays
WIMP candidate motivated by SUSY:Lightest Neutralino, LSP in MSSM
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Typical WIMP-WIMP elastic scatteringcross section ~10-40 cm2 and mass10-1000 GeV; for halo density ~GeV/cm3 and velocity ~300 km/sec, mean-free timefor WIMP scattering is at least 1013/H
0;
thus, WIMPs act as collision-freedark matter.
Axion-axion cross section far smaller,so also collisionless.
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Problem 1: Halo cusps
N-body simulations show "cusp", 1r, for small r for collisionless halos (Navarro, Frenk, White 1996; Moore et al. 1997); however, rotation curves for (at least some, maybe most) galaxies show dark-matter cores.
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Problem 2: Halo substructure
N-body simulations show more than 10 times as many dwarf galaxies in typical galactic halo than are observed in Milky Way (Moore et al. 1999; Klypin et al. 1999)
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Cluster
galactic halo
300 kpc
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The self-interacting dark matter solution (Spergel & Steinhardt 1999):
Hypothesize that dark matter can elastically scatter from itself
Small self-interaction leads to energy transport that reduces sharp subgalactic features like cusp and substructure.
Requires X-sections ~13 OoM bigger than WIMP
Now ruled out by lensing, dynamics, and x-ray observations of elliptical galaxies.
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Lesson from SIDM
Clever observations and argumentscan constrain interactions of dark-matterparticles
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Another possible resolution: Power suppression on small scales from
inflation with broken scale invarianceMK&Liddle, PRL 84, 4525 (2000)
Yokoyama, PRD, 2000I
V(V())
Inflaton
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ad hocBSI
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WIMPs from Charged-Particle Decay
(Sigurdson & MK, PRL 2004)
Charged particles: couple to baryon-photon fluid, have pressure, so growth of structure suppressed.Growth of modes that enter horizon while dark matter is charged is suppressed
If charged particle has lifetime ~3.5 yr, power on <Mpc suppressed
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Effect of Charged NLDP?
k= 30 Mpc-1 3 Mpc-1 0.3 Mpc-1
Dark Matter (Standard Case)Dark Matter (w/Charged NLDP)
Charged Matter (Baryons+NLDP)
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K. Sigurdson and MK Phys. Rev. Lett. 92, 171302 (2004) [astro-ph/0311486]
f = fraction of DM that is initially charged
If
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Small Scale Structure Problem
• Can solve this problem with charged-decay for lifetimes of order years.
• Long lifetime. Weak coupling?
• Measurements of small-scale P(k) can lead to cosmologically interesting lifetimes.
SuperWIMPSJ. Feng et al. (2003)
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Suppression by a factor in the linear power spectrum.
Can charged-particle decay mimicRunning of spectral index?
(Profumo, Sigurdson, Ullio, MK, PRD 2005, astro-ph/0410714)
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21-cm Fluctuations
• Measurement of linear-regime P(k) with 21-cm spin-flip transition during the “Cosmic Dark Ages”, at redshifts z=30-200 may discriminate between running of spectral index, and charged-particle decay
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How Dark is “Dark”? How weak must coupling of DM to photon
be? • Charge? No.
A. Gould et al. (1990)
• Millicharge? S. L. Dubovsky et al. (2004)S. Davidson et al. (2000)
• What about a neutral particle with magnetic or electric dipole moments?
Kris Sigurdson, Michael Doran, Andriy Kurylov, Robert R. Caldwell, Marc
Kamionkowski Phys. Rev. D70 (2004) 083501 [astro-ph/0406355]
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Effective Interaction
The effective interaction Lagrangian:
In the nonrelativistic limit:
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Constraints From
• Cosmological Relic Abundance
• Direct Detection
• Cosmology (CMB and LSS)
• Precision Standard Model
• Production at Accelerators
• Gamma Rays
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Relic Abundance
Standard Cosmological Freeze-out Calculation
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Constraints
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Direct Detection
CDMS (Soudan):
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Constraints
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Direct Detection
But… if the dipole strength is too large dipolar dark matter (DDM) will scatter in the atmosphere and
the rock above the detector and arrive at the detectorwith an energy below the detection threshold.
Strongest constraints from shallowest experiment with a null result. Balloon and Rocket experiments.
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Constraints
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Effects on the Matter Power Spectrum
Black
Red
Blue
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Effects on the CMB
Black
Red
Blue
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Constraints
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Precision Standard Model
Muon g-2
Standard Model EDMs
Z-Pole
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Precision Standard Model
Strongest Constraint:
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Constraints
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Production at Accelerators
B+ and K+ decays:
LEP, Tevatron? Tricky.
Look for missing energy
Need the full theory not the effective theory
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Gamma Rays
• Annihilation at the Galactic center could produce a nearly monoenergetic line.
• EGRET Constraints
• Possible GLAST signal
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Constraints
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Dipolar Dark Matter?
• Dipolar Dark Matter: A phenomenologically viable dark-matter candidate with a mass between an MeV and a GeV and predominantly dipole interactions.
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Kinetic decoupling of WIMPs and a small-scale cutoff to P(k)
Chen, MK, Zhang, PRD 64, 021302[astro-ph/0103452]
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Boehm, Fayet, Schaeffer (2000): calculatedsmoothing scale of WIMP dark matter dueto elastic scattering of WIMPs from SMparticles after freezeoutLed to Moore et al (2004) claim of earth-massWIMP clumps in Galactic halo
However, this work assumes energy-independent cross section for WIMPscattering from light-quark/leptons and photons
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Our work: showed that cross sectionfor elastic scattering of MSSM WIMPsfrom light SM particles is proportionalto energy squared. Kinetic decouplingtherefore takes place muchh earlierleading to much smaller smoothing scalethan obtained by assuming (incorrectly)energy-independent cross sections.
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Particle Decays and the CMBXuelei Chen and MK, PRD 70, 043502 (2004)
also, Kasuya, Kawasaki, Sugiyama (2004)and Pierpaoli (2004)
• Speculation: early reionization from WMAP due to decaying particles rather than early stars
• Can we constrain dark-matter decay channels and lifetimes from the CMB and elsewhere?
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Decays to photons with E>13.6 eV
• Energy loss processes include photoionization, Compton scattering, pair production from electrons, nuclei, background photons, and scattering from background photons
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z=10
z=100
z=300
Photon energy loss rate per Hubble time
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Transparencywindow
Photons absorbed by IGM
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Particles decay to electrons
• Energy lost by ionization or inverse-Compton scattering CMB
• Energy generally deposited in IGM unlessGeV<E<50 TeV, when upscattered CMBphoton in transparency window
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Electron energy-loss rate
ionization
InverseCompton
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IGMoptical depth,temperature,and ionizationfor long-liveddecaying particle
Depends onlyon energy-injection rate
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Ionizationinduced byparticledecaysionizes IGMand affectsCMB powerspectra
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again for l<100
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And for short-lived particles; now depends onenergy-injection rate and lifetime.
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Constraintsfrom CMBto decayswhere energyabsorbed inIGM
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Constraintsfrom diffusebackgroundsfor decaysin transparencywindow
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Covariancewith cosmologicalparameters
Baryon density
Spectral index
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Summary
• Self-interacting dark matter more tightly constrained than one might have thought
• dark matter from charged-particle decay may account for dwarf-galaxy dearth
• Or mimic running of spectral index• Couplings to photons tightly constrained• CMB provides new constraints to dark-matter decays
for decay products that heat IGM rather than propagate undisturbed