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Mia Schelke , Ph.D. Student The University of Stockholm, Sweden. Supersymmetric Dark Matter & coannihilations. Cosmo 03. SUSY DM phenomenology highlights What are coannihilations Why can coannihilations control the relic neutralino density When are coannihilations important
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Mia Schelke, Ph.D. Student The University of Stockholm, Sweden Supersymmetric Dark Matter & coannihilations Cosmo 03
SUSY DM phenomenology highlights What are coannihilations Why can coannihilations control the relic neutralino density When are coannihilations important The SUSY model used in our work:mSUGRA Results of relic density calculations including all coannihilations J. Edsjö, M. Schelke, P. Ullio & P. Gondolo JCAP 0304 (2003) 001 (hep-ph/0301106) Outline
Broken N=1 SUSY with conserved R-parity Multiplicatively conserved even nb of susy’s in vertex The lightest susy particle (LSP) is stable susy susy yes SM R-parity SM susy no SM Minimal N=1 Supersymmetric extension of the Standard Model one new particle for each elementary particle Partners are identical except for the spin, and when SUSY is broken also the mass differ.
LSP = Neutralino = WIMP The lightest supersymmetric particle (LSP) will often be a neutralinoc0 But lightest might meanO(100 GeV) a weakly interacting massive particle (WIMP) a naturalcold dark mattercandidate
Coannihilations and relic density Coannihilations* *Griest & Seckel,1991 Binetruy, Girardi & Salati,1984 Coannihilations processes in the early Universe determine the relic density of neutralinos : The neutralinos freeze out of thermal equilibrium approx. when: The Hubble expansion rate >the effective neutralino annihilation rate(H >s v n) # The comoving c0 relic density will stay constant ever after. NOTE:large ssmall n #Solve Boltzmann eq. for nc0 with I.e. a coupled system of annihilations/interactions But all `leftover´ susy particles decay into c0 So don’t solve for n1,n2,…., but for ∑ni = nc0
Coannihilation & mass splitting So seff is large when sij and are large. m<<T; Boltzmann suppression smallmass splittings effectivecoannihilations lowering (in general)nc0 (i.e. WCDM) Freeze out:
Effective coannihilations -- small masssplittings-- another illustration ; p.1/3 • Thermal averaging of all s v • Boltzmann suppression of high velocities (fixed T) Effective distribution function LSP-LSP CM frame Effective s v JCAP 0304 (2003) 001
Effective coannihilations -- small masssplittings-- another illustration; p.2/3 Coannihilation processes in individual CM frames (m1<m2<m3….): etc p11 p12 p22 Translatation to neutralino annihilations CM frame: p22 p11 p12 p11 Initial states look like final state thresholds
Effective coannihilations -- small masssplittings-- another illustration; p.3/3 • Thermal averaging of the effective s v • Boltmann suppression of heavy initial states Fig: JCAP 0304 (2003) 001
Our work in mSUGRA J. Edsjö, M. Schelke, P. Ullio & P. Gondolo JCAP 0304 (2003) 001 (hep-ph/0301106) We include all coannihilations and use the DarkSUSY package: Gondolo, Edsjö, Ullio, Bergström, Schelke and Baltz http://www.physto.se/~edsjo/darksusy/ DarkSUSY is a public fortran package for accurate calculations of neutralino relic density and detection rates. DarkSUSY solves the Boltzmann equation accurately (including resonances and thresholds).
Minimal supergravity • N=1 local susy with gravity mediated breakdown of susy • Effective model:N=1 global susy (MSSM) plus soft susy breaking terms • The five free mSUGRA parameters: • m1/2:GUT unification value of soft susy breaking fermionic mass parameters • m0 :GUT unification value of soft susy breaking bosonic mass parameters • A0 :GUT unification value of soft susy breaking trilinear scalar coupling parameters • tanb = v2/v1 : ratio of the Higgs fields vev’s • sign(m) :m is the Higgs superfield parameter
The most effective coannihilations (different regions of the parameterspace): stau ( ): partner of t chargino ( ): partners of charged higgs and gauge bosons stop ( ): partner of top All coannihilations are included The DarkSUSY code includes all channels of all 2 -> 2 tree-level coannihilation processes (Except initial state gluinos) To gain computational speed: Only include initial state sparticles with m<1.5m(c0)(better than 1% accuracy)
JCAP 0304 (2003) 001 The stau coannihilation region: Neutralino relic density isolevel curves.
JCAP 0304 (2003) 001 ~45 ~100 ~200 ~300 ~400 The stau coannihilation region: Effective coannihilations -- small mass splittings
JCAP 0304 (2003) 001 ~45 ~100 ~200 ~300 ~400 The stau coannihilation region: Increasing the upper bound on the neutralino mass. ---Wh2 without coannih.
JCAP 0304 (2003) 001 neutralino -- stau The stau coannihilation region: Increasing the upper bound on the neutralino mass.
No REWB No REWB Chargino coannihilation region (high mass focus point region) Increasing the upper bound on the neutralino mass. Coannihilations in this region had not been discussed in detail before
For mc > mt, a light stop is important even without coann.’s, as it boosts this annih. channel: Stop coannihilation region Coannihilations decrease the lower bound on the neutralino mass in this region JCAP 0304 (2003) 001 stau coannihilation region
Conclusions • The relic neutralino density can be wrong by as much as 100s or 1000s percent if coannihilations are not included • Coannihilations open up new regions of parameter space where the density is otherwise too high • In the stau and chargino coannihilation regions the upper mass bound to the c0 mass is increased, while its lower bound is decreased in the stop coann. region • The efficiency of the coannihilation with a certain sparticle and the mass splitting between this sparticle and the c0 are highly correlated • Efficient coannihilations are found for small mass splittings