Paolo Ciarcelluti · 2011. 12. 23. · ULB-TH - 16-12-2011 Mirror baryons as dark matter 2 mirror...

ULB-TH - 16-12-2011

Paolo Ciarcelluti

ASTROPHYSICAL PROPERTIES OF ASTROPHYSICAL PROPERTIES OF

MIRROR DARK MATTERMIRROR DARK MATTER

16 December 2011

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Motivation of this researchMotivation of this research

We are now in the

ERA OF PRECISION COSMOLOGY

and...

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We are now in the

ERA OF PRECISION COSMOLOGY

and... ?

We don't know the nature of

MORE THAN 90% OF THE UNIVERSE!!

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dark energy (cosmological constant or quintessence) → ΩΛ = 1 − Ωm

dark matter (CDM, WDM, some HDM)

→ ΩDM = Ωm − Ωb

visible (baryonic) matter → Ωb ≅ 0.02 h−2

matter → Ωm ≈ 0.2-0.3

radiation (relic γ and ν) → ΩR ∼ 10−5 << Ωm

Components of a flat Universe Components of a flat Universe

in standard cosmology:in standard cosmology:

search for dark matter candidates search for dark matter candidates

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dark energy (cosmological constant or quintessence) → ΩΛ = 1 − Ωm

dark matter (CDM, WDM, some HDM)

→ ΩDM = Ωm − Ωb

visible (baryonic) matter → Ωb ≅ 0.02 h−2

matter → Ωm ≈ 0.2-0.3

radiation (relic γ and ν) → ΩR ∼ 10−5 << Ωm

Components of a flat Universe Components of a flat Universe

in standard cosmology:in standard cosmology:

Every dark matter candidate has a typical signature in the Universe.

The Universe itself is a giant laboratory for testing new physics.

search for dark matter candidates search for dark matter candidates

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What is mirror matter ?What is mirror matter ?

Lee & Yang, Lee & Yang, Question of parity conservation in weak interactionsQuestion of parity conservation in weak interactions, 1956: “If such asymmetry is indeed found, the question could still be raised whether there could not exist corresponding elementary particles exhibiting opposite asymmetry such that in the broader sense there will still be over-all right-left symmetry.”

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IdeaIdea: there can exist a hidden mirror sector of particles and interactions which is the exact duplicate of our observable world, except for the handedness of weak interactions.

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TheoryTheory: product G×G′ of two sectors with the identical particle contents. Two sectors communicate via gravity. A symmetry P(G→G′), called mirror parity, implies that both sectors are described by the same Lagrangians. (Foot,Lew,Volkas,1991)

GSM = SU(3) × SU(2) × U(1) → standard model of observable particles

G′SM = [SU(3) × SU(2) × U(1)]′ → mirror counterpart with analogous particles

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Mirror photons cannot interact with ordinary baryonsMirror photons cannot interact with ordinary baryons ⇒⇒ dark matter !dark matter !

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Until now mirror particles can exist without violating any known experiment we need to compare their astrophysical consequences with observations.

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Their microphysics is the same but… cosmology is not the same !!

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Mirror baryons as dark matterMirror baryons as dark matter

2 mirror parameters2 mirror parameters

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BBN boundsBBN boundsIf particles in the two sectors O and M had the same cosmological densities → conflict with BBN (T ~ 1MeV)!!

If T′ =T , mirror photons, electrons and neutrinos → ΔNν = 6.14

Bound on effective number of extra-neutrinos: ⇒

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BBN boundsBBN bounds

The primordial abundance of 4He: evidence for non-standard big bang nucleosynthesisY. I. Izotov, T. X. Thuan [arXiv:1001.4440]

If particles in the two sectors O and M had the same cosmological densities → conflict with BBN (T ~ 1MeV)!!

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the two sectors have different initial conditions

they communicate only very weakly

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Due to the temperature difference, in the M sector all key epochs proceed at somewhat different conditions than in the O sector!

the two sectors have different initial conditions

they communicate only very weakly

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Effects on neutron starsEffects on neutron stars

If dark matter is an ingredient of the Universe, it should be present in all gravitationally bound structures.

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The mass–radius relation is significantly modified in the presence of a few percent mirror baryons. This effect mimics that of other exotica, e.g., quark matter.

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The NS equilibrium sequence depends on the relative number of mirror baryons to ordinary baryons, i.e., it is history dependent.

In contrast to the mass–radius relation of ordinary NS, it is not a one-parameter sequence:

non-uniqueness of the equilibrium sequence!

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The NS equilibrium sequence depends on the relative number of mirror baryons to ordinary baryons, i.e., it is history dependent.

In contrast to the mass–radius relation of ordinary NS, it is not a one-parameter sequence:

non-uniqueness of the equilibrium sequence!

Key point: since mirror baryons are stable dark matter particles, they can accumulate into stars.

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The distribution of mirror DM in galaxies is expected to be non-homogeneous, because mirror baryons should form complex structures in a similar way as ordinary baryons do.

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Besides the mirror matter already present at star formation, three possibilities for its capture by an ordinary NS (or the opposite):

accretion of particles from the homoge-neous mirror interstellar medium;

enhanced accretion rate if a NS passes through a high-density region of space, e.g., a mirror molecular cloud or planetary nebula;

merging with macroscopic bodies in the mirror sector, causing violent events and possibly a collapse into a black hole (low probability, high energy output).

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Besides the mirror matter already present at star formation, three possibilities for its capture by an ordinary NS (or the opposite):

accretion of particles from the homoge-neous mirror interstellar medium;

enhanced accretion rate if a NS passes through a high-density region of space, e.g., a mirror molecular cloud or planetary nebula;

merging with macroscopic bodies in the mirror sector, causing violent events and possibly a collapse into a black hole (low probability, high energy output).

The mass and radius are independent of the present DM accretion on the star, but depend on the whole DM capture process integrated over the stellar lifetime, i.e., the effects of mirror matter should depend on the location and history of each star.

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Have neutron stars a dark matter core?Have neutron stars a dark matter core?Recent observational results for masses and radii of some neutron stars are in contrast with theoretical predictions for “normal” neutron stars, and indicate that there might not exist a unique equilibrium sequence.

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Is this a signature of a dark matter core inside NS?

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Only hypothesis: DM is made of some stable or long-living, non-annihilating particles, that can accumulate in the star.

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In the proposed scenario all mass-radius measurements can be explained with one nuclear matter equation of state and a dark core of varying relative size.

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Possibility to distinguish between scenarios: a spread of mass-radius measurements that cannot be interpreted with just one or two equilibrium sequences.

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Possibility to distinguish between scenarios: a spread of mass-radius measurements that cannot be interpreted with just one or two equilibrium sequences.

With the estimated density for galactic DM, either the DM is present already during the star formation process, or the density distribution of DM is highly non-homogeneous, with events like mergers with compact astrophysical objects with stellar sizes made of DM.

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ThermodynamicsThermodynamics

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During the Universe expansion, the two sectors evolve with separately conserved entropies.

is time independentx≡ s 's 1 /3

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x free parameter

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x free parameter

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x free parameter

is time independent

the contribution of the mirror species is negligible in view of the BBN constraint!while the ordinary particles are crucial on the thermodynamics of the M ones!

x≡ s 's 1 /3

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Degrees of freedom in a Mirror UniverseDegrees of freedom in a Mirror Universe

During the expansion of the Universe:

the two sectors evolve with separately conserved entropies;

for each sector, after neutrino decouplings the entropies of (photons + electrons-positrons) and neutrinos are separately conserved.

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e+-e- annihilation epoch changes according with x

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e+-e- annihilation epoch changes according with x

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Mangano et al. (astro-ph/0612150) show some tension between degrees of freedom at different epochs.

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Mangano et al. (astro-ph/0612150) show some tension between degrees of freedom at different epochs.

Mirror matter naturally predicts different degrees of freedom at BBN (1 MeV) and recombination (1 eV) epochs!

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Big Bang nucleosynthesisBig Bang nucleosynthesis

2 fundamental parameters:

degrees of freedom (extra- families), baryon to photon ratio:

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The M sector has a negligible influence on the nucleosynthesis in the O sector.

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The O sector has a big influence (higher for lower x) on the nucleosynthesis in the M sector!

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The O sector has a big influence (higher for lower x) on the nucleosynthesis in the M sector!

Mirror sector is a He-world!

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Mirror dark starsMirror dark stars (evolution) (evolution)

Massive Astrophysical Compact Massive Astrophysical Compact Halo Objects (MACHOs)Halo Objects (MACHOs)

microlensing microlensing eventsevents ⇒⇒

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Mirror dark starsMirror dark stars (evolution) (evolution)

Massive Astrophysical Compact Massive Astrophysical Compact Halo Objects (MACHOs)Halo Objects (MACHOs)

microlensing microlensing eventsevents ⇒⇒

L∝7.5M 5.5

T e4∝7.5

tMS∝X

faster evolutionary times!faster evolutionary times!

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Photon-mirror photon kinetic Photon-mirror photon kinetic mixing and DAMA experimentmixing and DAMA experiment

Besides gravity, mirror particles could interact with the ordinary ones via renormalizable photon-mirror photon kinetic mixing, that enables mirror charged particles to couple to ordinary photons with charge εe.

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R. Foot [arXiv:0804.4518]: mirror dark matter provides a simple explanation of the positive signal of DAMA/Libra consistently with the null results of the other direct detection experiments.

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This scenario requires that: the halo is dominated by He' with a small O' component ordinary matter interacts with mirror dark matter via photon-mirror photon kinetic mixing of strength ε ~ 10-9.

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This scenario requires that: the halo is dominated by He' with a small O' component ordinary matter interacts with mirror dark matter via photon-mirror photon kinetic mixing of strength ε ~ 10-9.

Mirror baryons should constitute the dark halos of galaxies, primarily made of primordial He'. The high He' abundance induces fast stellar formation and evolution, that produce heavier nuclei, as O', ejected in SN explosions.

The dark halo is mainly constituted of He' and O'.⇒

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BBN with photon-mirror photon kinetic mixingBBN with photon-mirror photon kinetic mixingAssuming an effective initial condition T' << T, this mixing can populate the mirror sector in the early Universe, via the process , implying a generation of energy density in the mirror sector:

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at T ≤ 1 MeV:

The e+′, e−′ will interact with each other via mirror weak and electromagnetic interactions, populating the γ′, ν′ , and thermalizing to a common temperature T′.

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at T ≤ 1 MeV:

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at T ≤ 1 MeV:

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Constraint from ordinary BBN: δNν ≤ 0.5 ⇒ T'/T < 0.6.

More stringent constraint from CMB and LSS: T'/T ≤ 0.3 ⇒ ε ≤ 3 10-9.

The photon-mirror photon mixing necessary to interpret dark matter detection experiments is consistent with constraints from ordinary BBN as well as the more stringent constraints from CMB and LSS.

at T ≤ 1 MeV:

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A more accurate modelA more accurate modelUsing a more accurate model for energy transfer from ordinary to mirror sector, the generation of energy density in the mirror sector is:

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Mirror nucleosynthesis is so fast that we may neglect neutron decay:

Mirror sector starts with T' much lower than T, and later the photon–mirror photon kinetic mixing increases only the temperature of mirror electron-positrons and photons, since neutrinos are decoupled.

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Structure formationStructure formation

Matter-radiation equality (MRE) epochMatter-radiation equality (MRE) epoch

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Baryon-photon decoupling Baryon-photon decoupling (MRD) epoch(MRD) epoch

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The MRD in the M sector occurs earlier than in the O one!The MRD in the M sector occurs earlier than in the O one!

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For small x the M matter decouples before the MRE moment → it manifests as the CDM as far as the LSS is concerned (but there still can be crucial differences at smaller scales which already went non-linear).

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For small x the M matter decouples before the MRE moment → it manifests as the CDM as far as the LSS is concerned (but there still can be crucial differences at smaller scales which already went non-linear).

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The Jeans massThe Jeans mass

M J '=43b ' J '

J '=v S '

M J ' adec ' =3.2⋅1014M⊙−1/2

1−3 /2 x4

1x4 3 /2

b h2−2

M J ' adec ' ≈−1 /2 x4

1x4 3/2

M J adec

M J 'max 2 xeq≈64M J 'maxx eq

x=0.6=2

M J '≈0.03M J≈1014M⊙

M J 'max xeq /2≈0.005MJ 'max xeq

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M J '=43b ' J '

J '=v S '

M J ' adec ' =3.2⋅1014M⊙−1/2

1−3 /2 x4

1x4 3 /2

b h2−2

M J ' adec ' ≈−1 /2 x4

1x4 3/2

M J adec

x=0.6=2

M J '≈0.03M J≈1014M⊙

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M J '=43b ' J '

J '=v S '

M J ' adec ' =3.2⋅1014M⊙−1/2

1−3 /2 x4

1x4 3 /2

b h2−2

M J ' adec ' ≈−1 /2 x4

1x4 3/2

M J adec

x=0.6=2

M J '≈0.03M J≈1014M⊙

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The M baryons density fluctuations should undergo the strong collisional damping around the time of M recombination due to photon diffusion, which washes out the perturbations at scales smaller than the M Silk scale MS'.

Dissipative effectsDissipative effects

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The M baryons density fluctuations should undergo the strong collisional damping around the time of M recombination due to photon diffusion, which washes out the perturbations at scales smaller than the M Silk scale MS'.

Dissipative effectsDissipative effects

Differences with the WDM free streaming damping:

the M baryons should show acoustic oscillations in the LSS power spectrum;

such oscillations, transmitted via gravity to the O baryons, could cause observable anomalies in the CMB power spectrum.

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ScenariosScenarios

xxeq adec 'aeq xxeq adec 'aeq

M pertM J ' aeq

M S 'M pertM J ' aeq

M pertM S '

growth

grow.oscill.grow.

dissipation

M pertM J ' adec ' growth

M pertM S ' dissipation

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x dependence

Temporal evolution of perturbationsTemporal evolution of perturbations( Ω0 = 1, Ωm = 0.3, ωb = 0.02, h = 0.7 ; λ ≈ 60 Mpc)

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x dependence

Temporal evolution of perturbationsTemporal evolution of perturbations( Ω0 = 1, Ωm = 0.3, ωb = 0.02, h = 0.7 ; λ ≈ 60 Mpc)

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Cosmic Microwave BackgroundCosmic Microwave Background

T=2.725±0.001K TT

≈10−5

∑m=−l

almY lm ,

Cl=al2≡

12l1 ∑

m=−l

∣alm∣2=⟨∣alm∣

T l2≡l l1Cl /2

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We start from a reference model

and we replace CDM…

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low x → similar to CDM

low dependence on Ωb′

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Large Scale StructureLarge Scale Structure

Field of density perturbations:

The transfer function: T(k)

The power spectrum:

P k ; t f =[ D t f

D t i ]2

T 2k ;t f P k ; t i

P k ≡⟨∣k∣2⟩=A k n

x ≡x −0

23∫k e

−ik⋅x d3k

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At linear scales…At linear scales…

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low x → similar to CDM

high dependence on x

high dependence on Ωb'

At linear scales…At linear scales…

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Comparison with observationsComparison with observations

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• for high x → high Ωb' excluded

• for low x → every Ωb' permitted

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analyses based on numerical simulations of CMB and LSS suggest:

T'/T ≤ 0.3

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Mirror summaryMirror summaryT

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Thermodynamics of the early Universe

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Big Bang Nucleosynthesis

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Primordial nuclear abundances

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Star formation

Star evolution

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Star formation

Star evolution

DAMA annual modulation signal

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Star formation

Star evolution

Gravitational waves

MACHOs population

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Structure formation

Star formation

Star evolution

Gravitational waves

MACHOs population

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Structure formation

Star formation

Star evolution

CMB and LSS power spectra

Gravitational lensing

Gravitational waves

MACHOs population

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Structure formation

N-body simulations

Galaxy formation and evolution

Star formation

Star evolution

Gravitational waves

MACHOs population

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Structure formation

N-body simulations

Star formation

Star evolution

Galactic DM distribution

Strange events:dark galaxies, bullet galaxies, ...

Gravitational waves

MACHOs population

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Structure formation

N-body simulations

Star formation

Star evolution

Gravitational waves

MACHOs population

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Structure formation

N-body simulations

Star formation

Star evolution

Gravitational waves

MACHOs population

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Comments?Comments?Suggestions?Suggestions?

Collaborations?Collaborations?

And now your mirror feedback!And now your mirror feedback!

P. Ciarcelluti, A. Lepidi, Phys. Rev. D 78, 123003 (2008) [arXiv:0809.0677]

Structure formation

Cosmic Microwave Background and Large Scale Structure

and Big Bang Nucleosynthesis

P. Ciarcelluti, Int. J. Mod. Phys. D 14, 187-222 (2005) [astro-ph/0409630]

P. Ciarcelluti, Int. J. Mod. Phys. D 14, 223-256 (2005) [astro-ph/0409633]

P. Ciarcelluti, AIP Conf. Proc. 1038, 202-210 (2008) [arXiv:0809.0668]

P. Ciarcelluti, R. Foot,Phys. Lett. B679, 278-281 (2009) [arXiv:0809.4438]

DAMA signal compatibility

Review: P. Ciarcelluti, Int. J. Mod. Phys. D 19, 2151-2230 (2010) [arXiv:1102.5530]

P. Ciarcelluti, R. Foot,Phys. Lett. B690, 462-465 (2010) [arXiv:1003.0880]

Mirror dark stars (MACHOs)and neutron stars

Z.Berezhiani, P.Ciarcelluti, S.Cassisi, A.Pietrinferni, Astropart. Phys. 24, 495-510 (2006) [astro-ph/0507153]

P. Ciarcelluti, F. Sandin, Phys. Lett. B 695, 19-21 (2011) [arXiv:1005.0857]

F. Sandin, P. Ciarcelluti, Astropart. Phys. 32, 278-284 (2009), [arXiv:0809.2942]

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Effects on neutron stars Effects on neutron stars the Chandrasekhar massthe Chandrasekhar mass

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At smaller scales…At smaller scales…

Cut-off scale dependent on x

Paolo Ciarcelluti · 2011. 12. 23. · ULB-TH - 16-12-2011 Mirror baryons as dark matter 2 mirror...

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