why the cosmological constant goes to zero, and why we see it now
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QuintessenceQuintessence
C.WetterichC.Wetterich
A.Hebecker, M.Doran, M.Lilley, J.Schwindt,A.Hebecker, M.Doran, M.Lilley, J.Schwindt,C.MC.Müüller, G.Schller, G.Schääfer, E.Thommes,fer, E.Thommes,R.Caldwell, M.Bartelmann, K.Kharwan, G.Robbers,R.Caldwell, M.Bartelmann, K.Kharwan, G.Robbers,T.Dent, S.Steffen, L.Amendola, M.Baldi , N.Brouzakis , N.Tetradis,T.Dent, S.Steffen, L.Amendola, M.Baldi , N.Brouzakis , N.Tetradis,D.Mota, V.Pettorino, T.KrD.Mota, V.Pettorino, T.Krüüger, M.Neubertger, M.Neubert
Dark Energy Dark Energy dominates the Universedominates the Universe
Energy - density in the Energy - density in the UniverseUniverse
==
Matter + Dark EnergyMatter + Dark Energy
25 % + 75 %25 % + 75 %
Cosmological ConstantCosmological Constant- Einstein -- Einstein -
Constant Constant λλ compatible with all symmetries compatible with all symmetries Constant Constant λλ compatible with all compatible with all
observationsobservations No time variation in contribution to energy No time variation in contribution to energy
densitydensity
Why so small ? Why so small ? λλ/M/M44 = 10 = 10-120-120
Why important just today ?Why important just today ?
Cosmological mass scalesCosmological mass scales Energy densityEnergy density
ρρ ~ ( 2.4×10 ~ ( 2.4×10 -3-3 eV )eV )- 4- 4
Reduced Planck Reduced Planck massmass
M=2.44M=2.44×10×101818GeVGeV Newton’s constantNewton’s constant
GGNN=(8=(8ππM²)M²)
Only ratios of mass scales are observable !Only ratios of mass scales are observable !
homogeneous dark energy: homogeneous dark energy: ρρhh/M/M44 = 7 · = 7 · 10ˉ¹²¹10ˉ¹²¹
matter: matter: ρρmm/M/M4= 3 · 10ˉ¹²¹= 3 · 10ˉ¹²¹
QuintessenceQuintessenceDynamical dark energy ,Dynamical dark energy , generated by scalargenerated by scalar fieldfield
(cosmon)(cosmon)
C.Wetterich,Nucl.Phys.B302(1988)668, C.Wetterich,Nucl.Phys.B302(1988)668, 24.9.87 24.9.87P.J.E.Peebles,B.Ratra,ApJ.Lett.325(1988)LP.J.E.Peebles,B.Ratra,ApJ.Lett.325(1988)L17, 20.10.8717, 20.10.87
Prediction :Prediction :
homogeneous dark energy homogeneous dark energyinfluences recent cosmologyinfluences recent cosmology
- of same order as dark - of same order as dark matter -matter -
Original models do not fit the present observationsOriginal models do not fit the present observations……. modifications. modifications
CosmonCosmon Scalar field changes its value even Scalar field changes its value even
in the in the present present cosmological epochcosmological epoch Potential und kinetic energy of Potential und kinetic energy of
cosmon contribute to the energy cosmon contribute to the energy density of the Universedensity of the Universe
Time - variable dark energy : Time - variable dark energy : ρρhh(t) decreases with time !(t) decreases with time !
V(V(φφ) =M) =M44 exp( - exp( - αφαφ/M )/M )
two key featurestwo key features
1 ) Exponential cosmon potential and 1 ) Exponential cosmon potential and
scaling solutionscaling solution
V(V(φφ) =M) =M44 exp( - exp( - αφαφ/M ) /M )
V(V(φφ →→ ∞ ) → 0 ! ∞ ) → 0 !
2 ) Stop of cosmon evolution by 2 ) Stop of cosmon evolution by
cosmological triggercosmological trigger
Evolution of cosmon fieldEvolution of cosmon field
Field equationsField equations
Potential V(Potential V(φφ) determines details of the ) determines details of the modelmodel
V(V(φφ) =M) =M4 4 exp( - exp( - αφαφ/M )/M )
for increasing for increasing φφ the potential the potential decreases towards zero !decreases towards zero !
Cosmic AttractorCosmic Attractor
Solutions independent of initial conditions
V ~ t -2
φ ~ ln ( t )
Ωh ~ const.
early cosmology
exponential potentialexponential potentialconstant fraction in dark constant fraction in dark
energyenergy
can explain order of can explain order of magnitude magnitude
of dark energy !of dark energy !
ΩΩh h = 3(4)/= 3(4)/αα22
realistic quintessencerealistic quintessence
fraction in dark energy has fraction in dark energy has to to
increase in “recent time” !increase in “recent time” !
Quintessence becomes Quintessence becomes important “today”important “today”
No reason why w shouldNo reason why w shouldbe constant in time !be constant in time !
coincidence problemcoincidence problem
What is responsible for increase of What is responsible for increase of ΩΩhh for z < 6 ? for z < 6 ?
Why now ?Why now ?
growing neutrino mass growing neutrino mass triggers transition to triggers transition to
almost static dark energyalmost static dark energy
growinggrowingneutrinoneutrinomassmass
Cosmon coupling to Cosmon coupling to neutrinosneutrinos
can be large !can be large !
interesting effects for cosmology if interesting effects for cosmology if neutrino mass is growingneutrino mass is growing
growing neutrinos can stop the growing neutrinos can stop the evolution of the cosmonevolution of the cosmon
transition from early scaling solution transition from early scaling solution to cosmological constant dominated to cosmological constant dominated cosmologycosmology
L.Amendola,M.Baldi,…L.Amendola,M.Baldi,…
Fardon,Nelson,WeinerFardon,Nelson,Weiner
crossover due to crossover due to non –relativistic non –relativistic
neutrinosneutrinos
growinggrowingneutrinoneutrinomassmass
end of matter end of matter dominationdomination
growing mass of neutrinosgrowing mass of neutrinos
at some moment energy density of at some moment energy density of neutrinos becomes more important than neutrinos becomes more important than energy density of dark matterenergy density of dark matter
end of matter dominated periodend of matter dominated period similar to transition from radiation similar to transition from radiation
domination to matter dominationdomination to matter domination this transition happens in the recent pastthis transition happens in the recent past cosmon plays crucial rolecosmon plays crucial role
cosmological selectioncosmological selection
present value of dark energy density present value of dark energy density set by cosmological event set by cosmological event
( neutrinos become non – relativistic )( neutrinos become non – relativistic )
not given by ground state properties !not given by ground state properties !
connection between dark connection between dark energy energy
and neutrino propertiesand neutrino properties
present present equationequationof state given of state given bybyneutrino mass neutrino mass !!
present dark energy density given by neutrino masspresent dark energy density given by neutrino mass
dark energy fraction dark energy fraction determined by neutrino determined by neutrino
massmass
constant neutrino - cosmon coupling constant neutrino - cosmon coupling ββ
variable neutrino - cosmon couplingvariable neutrino - cosmon coupling
varying neutrino – cosmon varying neutrino – cosmon couplingcoupling
specific modelspecific model can naturally explain why neutrino – can naturally explain why neutrino –
cosmon coupling is much larger than cosmon coupling is much larger than atom – cosmon coupling atom – cosmon coupling
neutrino massneutrino mass
seesaw seesaw andandcascadecascademechanismechanismm
omit generation omit generation structurestructure
triplet expectation value ~ doublet squaredtriplet expectation value ~ doublet squared
cascade mechanismcascade mechanism
triplet expectation value ~triplet expectation value ~
M.Magg , …M.Magg , …G.Lazarides , Q.Shafi , …G.Lazarides , Q.Shafi , …
varying neutrino massvarying neutrino mass
triplet mass depends on cosmon field triplet mass depends on cosmon field φφ
neutrino mass depends on neutrino mass depends on φφ
εε ≈≈ -0.05 -0.05
““singular” neutrino masssingular” neutrino mass
triplet mass vanishes for triplet mass vanishes for φφ → → φφtt
neutrino mass diverges for neutrino mass diverges for φφ → → φφtt
strong effective strong effective neutrino – cosmon neutrino – cosmon
coupling coupling for for φφ → → φφtt
crossover fromcrossover fromearly scaling solution to early scaling solution to
effective cosmological effective cosmological constantconstant
early scaling solution ( tracker early scaling solution ( tracker solution )solution )
neutrino mass unimportant in early cosmologyneutrino mass unimportant in early cosmology
growing neutrinos growing neutrinos change cosmon evolutionchange cosmon evolution
modification of conservation equation for neutrinosmodification of conservation equation for neutrinos
effective stop of cosmon effective stop of cosmon evolutionevolution
cosmon evolution almost stops cosmon evolution almost stops onceonce
neutrinos get non –relativisticneutrinos get non –relativistic ß gets largeß gets large
This alwaysThis alwayshappens happens for for φφ → → φφt t !!
effective cosmological effective cosmological triggertrigger
for stop of cosmon for stop of cosmon evolution :evolution :
neutrinos get non-neutrinos get non-relativisticrelativistic
this has happened recently !this has happened recently ! sets scales for dark energy !sets scales for dark energy !
dark energy fraction dark energy fraction determined by neutrino determined by neutrino
massmass
constant neutrino - cosmon coupling constant neutrino - cosmon coupling ββ
variable neutrino - cosmon couplingvariable neutrino - cosmon coupling
Hubble parameter ( z < Hubble parameter ( z < zzc c ))
only small only small differencedifferencefrom from ΛΛCDM !CDM !
Can time evolution of Can time evolution of neutrino mass be neutrino mass be
observed ?observed ? Experimental determination of Experimental determination of
neutrino mass may turn out higher neutrino mass may turn out higher than upper bound in model for than upper bound in model for cosmological constant cosmological constant
( KATRIN, neutrino-less double beta ( KATRIN, neutrino-less double beta decay )decay )
GERDAGERDA
neutrino fluctuationsneutrino fluctuations
neutrino structures become nonlinear neutrino structures become nonlinear at z~1 for supercluster scalesat z~1 for supercluster scales
stable neutrino-cosmon lumps exist stable neutrino-cosmon lumps exist N.Brouzakis , N.Tetradis ,…N.Brouzakis , N.Tetradis ,…
D.Mota , G.Robbers , V.Pettorino , …D.Mota , G.Robbers , V.Pettorino , …
neutrino fluctuationsneutrino fluctuations time when neutrinos become non – time when neutrinos become non –
relativisticrelativistic sets free streaming scalesets free streaming scale
neutrino structures become nonlinear at neutrino structures become nonlinear at z~1 for supercluster scalesz~1 for supercluster scales
stable neutrino-cosmon lumps exist stable neutrino-cosmon lumps exist N.Brouzakis , N.Tetradis ,…N.Brouzakis , N.Tetradis ,…
D.Mota , G.Robbers , V.Pettorino , …D.Mota , G.Robbers , V.Pettorino , …
ConclusionsConclusions
Cosmic event triggers qualitative Cosmic event triggers qualitative change in evolution of cosmonchange in evolution of cosmon
Cosmon stops changing after Cosmon stops changing after neutrinos become non-relativisticneutrinos become non-relativistic
Explains why nowExplains why now Cosmological selectionCosmological selection Model can be distinguished from Model can be distinguished from
cosmological constantcosmological constant
two key featurestwo key features
1 ) Exponential cosmon potential and 1 ) Exponential cosmon potential and
scaling solutionscaling solution
V(V(φφ) =M) =M44 exp( - exp( - αφαφ/M ) /M )
V(V(φφ →→ ∞ ) → 0 ! ∞ ) → 0 !
2 ) Stop of cosmon evolution by 2 ) Stop of cosmon evolution by
cosmological triggercosmological trigger
Time dependent Dark Time dependent Dark Energy :Energy :
QuintessenceQuintessence What changes in time ?What changes in time ?
Only dimensionless ratios of mass scales Only dimensionless ratios of mass scales are observable !are observable !
V : potential energy of scalar field or cosmological V : potential energy of scalar field or cosmological constantconstant
V/MV/M4 4 is observableis observable
Imagine the Planck mass M increases …Imagine the Planck mass M increases …
Cosmon and Cosmon and fundamental mass scalefundamental mass scale
Assume all mass parameters are Assume all mass parameters are proportional to scalar field proportional to scalar field χχ (GUTs, (GUTs, superstrings,…)superstrings,…)
MMpp~ ~ χχ , m , mprotonproton~ ~ χχ , , ΛΛQCDQCD~ ~ χχ , M , MWW~ ~ χχ ,… ,…
χχ may evolve with time : may evolve with time : cosmoncosmon mmnn/M : ( almost ) constant - /M : ( almost ) constant - observationobservation !!
Only ratios of mass scales are Only ratios of mass scales are observableobservable
Example :Example :
Field Field χχ is connected to mass scale of transition is connected to mass scale of transitionfrom higher dimensional physicsfrom higher dimensional physicsto effective four dimensional descriptionto effective four dimensional description
theory without explicit theory without explicit mass scalemass scale
Lagrange density:Lagrange density:
realistic theoryrealistic theory
χχ has no gauge interactions has no gauge interactions χχ is effective scalar field after is effective scalar field after
“integrating out” all other scalar “integrating out” all other scalar fieldsfields
Dilatation symmetryDilatation symmetry Lagrange density:Lagrange density:
Dilatation symmetry forDilatation symmetry for
Conformal symmetry for Conformal symmetry for δδ=0=0
Asymptotically vanishing Asymptotically vanishing effective “cosmological effective “cosmological
constant”constant” Effective cosmological constant ~ V/MEffective cosmological constant ~ V/M4 4
λλ ~ ( ~ (χχ//μμ) ) –A–A
V ~ (V ~ (χχ//μμ) ) –A –A χχ4 4 V/MV/M4 4 ~(~(χχ//μμ) ) –A –A
M = M = χχ
It is sufficient that V increases less It is sufficient that V increases less fast than fast than χχ4 4 !!
CosmologyCosmology
Cosmology : Cosmology : χχ increases with time ! increases with time !
( due to coupling of ( due to coupling of χχ to curvature scalar to curvature scalar ))
for large for large χχ the ratio V/M the ratio V/M4 4 decreases to decreases to zerozero
Effective cosmological constant vanishes Effective cosmological constant vanishes asymptotically for large t !asymptotically for large t !
Weyl scalingWeyl scaling
Weyl scaling : gWeyl scaling : gμνμν→→ (M/ (M/χχ))2 2 ggμνμν , ,
φφ/M = ln (/M = ln (χχ 44/V(/V(χχ))))
Exponential potential : V = MExponential potential : V = M44 exp(- exp(-φφ/M)/M)
No additional constant !No additional constant !
geometrical runaway and geometrical runaway and the problem of time varying the problem of time varying
constantsconstants It is not difficult to obtain quintessence It is not difficult to obtain quintessence
potentials from higher dimensional ( or potentials from higher dimensional ( or string ? ) theoriesstring ? ) theories
Exponential form rather generic Exponential form rather generic
( after Weyl scaling)( after Weyl scaling) Potential goes to zero for Potential goes to zero for φφ →→ ∞∞ But most models show too strong time But most models show too strong time
dependence of constants !dependence of constants !
runaway solutionsrunaway solutions
geometrical runawaygeometrical runaway
anomalous runawayanomalous runaway
geometrical adjustmentgeometrical adjustment
Quintessence Quintessence from higher dimensionsfrom higher dimensions
An instructive example:An instructive example:
Einstein – Maxwell theory in six Einstein – Maxwell theory in six dimensionsdimensions
with J. Schwindtwith J. Schwindthep-th/0501049hep-th/0501049
MetricMetricAnsatz with particular metric ( not Ansatz with particular metric ( not
most general ! )most general ! )which is consistent withwhich is consistent with
d=4 homogeneous and isotropic d=4 homogeneous and isotropic UniverseUniverse
and internal and internal U(1) x ZU(1) x Z22 isometry isometry
B ≠ 1 : football shaped internal geometryB ≠ 1 : football shaped internal geometry
Conical singularitiesConical singularities
deficit angledeficit angle
singularities can be included with singularities can be included with energy momentum tensor on braneenergy momentum tensor on brane
bulk point of view : bulk point of view : describe everything in terms of bulk geometry describe everything in terms of bulk geometry ( not possible for modes on brane without tail ( not possible for modes on brane without tail
in bulk )in bulk )
Exact solutionExact solution
m : monopole number ( integer)m : monopole number ( integer)
cosmology with scalarcosmology with scalar
and potential V :and potential V :
NaturalnessNaturalness
No tuning of parameters or integration No tuning of parameters or integration constantsconstants
Radiation and matter can be implementedRadiation and matter can be implemented Asymptotic solution depends on details of Asymptotic solution depends on details of
model, e.g. solutions with constant model, e.g. solutions with constant ΩΩhh ≠ 1 ≠ 1
problem :problem :
time variation of time variation of fundamental constantsfundamental constants
relative change order one for z relative change order one for z around onearound onegauge coupling goes to zero for gauge coupling goes to zero for large timelarge time
primordial abundances primordial abundances for three GUT modelsfor three GUT models
T.Dent,T.Dent,S.Stern,…S.Stern,…
present present observatioobservations : 1ns : 1σσ
HeHe
DD
LiLi
three GUT modelsthree GUT models unification scale ~ Planck scaleunification scale ~ Planck scale 1) All particle physics scales ~1) All particle physics scales ~ΛΛQCDQCD
2) Fermi scale and fermion masses ~ 2) Fermi scale and fermion masses ~ unification scaleunification scale
3) Fermi scale varies more rapidly than 3) Fermi scale varies more rapidly than ΛΛQCDQCD
ΔαΔα//αα ≈ 4 10 ≈ 4 10-4-4
allowed for GUT 1 and 3 , larger for GUT 2allowed for GUT 1 and 3 , larger for GUT 2
ΔΔln(Mln(Mnn/M/MPP) ≈40 ) ≈40 ΔαΔα//αα ≈ 0.015 allowed ≈ 0.015 allowed
toy model for toy model for asymptotically vanishing asymptotically vanishing
dark energydark energy effective d=4 cosmology involves graviton, effective d=4 cosmology involves graviton,
cosmon and gauge bosons ( radiation )cosmon and gauge bosons ( radiation ) asymptotically : gauge bosons are free , asymptotically : gauge bosons are free ,
cosmon becomes masslesscosmon becomes massless dark energy goes to zero without tuning as dark energy goes to zero without tuning as
a consequence of simple geometrya consequence of simple geometry example that naïve estimate of size of example that naïve estimate of size of
cosmological constant from quantum cosmological constant from quantum fluctuations fails badlyfluctuations fails badly
can be understood in terms of effective can be understood in terms of effective dilatation symmetrydilatation symmetry
stabilizing the stabilizing the couplings…couplings…
in toy model : gauge couplings go to in toy model : gauge couplings go to zero as volume of internal space zero as volume of internal space increasesincreases
ways to solve this problem: ways to solve this problem: volume or curvature of internal space volume or curvature of internal space
is irrelevant for modes on braneis irrelevant for modes on brane possible stabilization by fixed points possible stabilization by fixed points
in scale free modelsin scale free models
Warped branesWarped branes
model is similar to first co-dimension two model is similar to first co-dimension two
warped brane model : C.W. warped brane model : C.W. Nucl.Phys.B255,480(1985); Nucl.Phys.B255,480(1985);
see also B253,366(1985)see also B253,366(1985) first realistic warped modelfirst realistic warped model see Rubakov and Shaposhnikov for earlier see Rubakov and Shaposhnikov for earlier
work ( no stable solutions, infinitely many work ( no stable solutions, infinitely many chiral fermions)chiral fermions)
see Randjbar-Daemi, C.W. for arbitrary see Randjbar-Daemi, C.W. for arbitrary dimensionsdimensions
Brane stabilizationBrane stabilization
idea :idea : all masses and couplings of standard model all masses and couplings of standard model
depend only on characteristic scale and depend only on characteristic scale and geometry of branegeometry of brane
generalized curvature invariant , which is generalized curvature invariant , which is relevant for V, scales with inverse power of relevant for V, scales with inverse power of characteristic length scale L characteristic length scale L
L → ∞ while brane scale remains constant L → ∞ while brane scale remains constant analogy with black hole in cosmological analogy with black hole in cosmological
background background
scales in gravityscales in gravity
gravity admits solutions with very gravity admits solutions with very different length or mass scalesdifferent length or mass scales
example : black hole in expanding example : black hole in expanding universeuniverse
Dilatation symmetryDilatation symmetry Lagrange density:Lagrange density:
Dilatation symmetry forDilatation symmetry for
Conformal symmetry for Conformal symmetry for δδ=0=0
Dilatation anomalyDilatation anomaly
Quantum fluctuations responsible Quantum fluctuations responsible forfor
dilatation anomalydilatation anomaly Running couplings:Running couplings: hypothesishypothesis
Renormalization scale Renormalization scale μμ : : ( momentum scale )( momentum scale )
λλ~(~(χχ//μμ) ) –A–A
Asymptotic behavior of Asymptotic behavior of effective potentialeffective potential
λλ ~ ( ~ (χχ//μμ) ) –A–A
V ~ (V ~ (χχ//μμ) ) –A –A χχ44
VV ~ ~ χχ 4–A 4–A
crucial : behavior for large χ !crucial : behavior for large χ !
Without dilatation – anomaly :V= const. Massless Goldstone boson = dilaton
Dilatation – anomaly :V (φ )Scalar with tiny time dependent mass : cosmon
Dilatation anomaly and Dilatation anomaly and quantum fluctuationsquantum fluctuations
Computation of running couplings Computation of running couplings ( beta functions ) needs unified theory !( beta functions ) needs unified theory !
Dominant contribution from modes Dominant contribution from modes with momenta ~with momenta ~χχ ! !
No prejudice on “natural value “ of No prejudice on “natural value “ of anomalous dimension should be anomalous dimension should be inferred from tiny contributions at inferred from tiny contributions at QCD- momentum scale !QCD- momentum scale !
quantum fluctuations and quantum fluctuations and naturalnessnaturalness
Jordan- and Einstein frame completely Jordan- and Einstein frame completely equivalent on level of effective action equivalent on level of effective action and field equations ( and field equations ( afterafter computation computation of quantum fluctuations ! )of quantum fluctuations ! )
Treatment of quantum fluctuations Treatment of quantum fluctuations depends on frame : Jacobian for depends on frame : Jacobian for variable transformation in functional variable transformation in functional integralintegral
What is natural in one frame may look What is natural in one frame may look unnatural in another frameunnatural in another frame
quantum fluctuations quantum fluctuations and framesand frames
Einstein frame : quantum fluctuations Einstein frame : quantum fluctuations make zero cosmological constant look make zero cosmological constant look unnaturalunnatural
Jordan frame : quantum fluctuations Jordan frame : quantum fluctuations are at the origin of dilatation anomaly;are at the origin of dilatation anomaly;
may be key ingredient for may be key ingredient for solutionsolution of of cosmological constant problem !cosmological constant problem !
fixed points and fluctuation fixed points and fluctuation contributions of individual contributions of individual
componentscomponents
If running couplings influenced by fixed points:If running couplings influenced by fixed points:individual fluctuation contribution can be huge individual fluctuation contribution can be huge
overestimate !overestimate !
here : fixed point at vanishing quartic coupling and here : fixed point at vanishing quartic coupling and anomalous dimension anomalous dimension VV ~ ~ χχ 4–A 4–A
it makes no sense to use naïve scaling argument to it makes no sense to use naïve scaling argument to infer individual contribution infer individual contribution VV ~ h ~ h χχ 4 4
conclusionsconclusions
naturalness of cosmological constant naturalness of cosmological constant and cosmon potential should be and cosmon potential should be discussed in the light of dilatation discussed in the light of dilatation symmetry and its anomaliessymmetry and its anomalies
Jordan frameJordan frame higher dimensional settinghigher dimensional setting four dimensional Einstein frame and four dimensional Einstein frame and
naïve estimate of individual naïve estimate of individual contributions can be very misleading !contributions can be very misleading !
How can quintessence be How can quintessence be distinguished from a distinguished from a
cosmological constant ?cosmological constant ?
Time dependence of dark Time dependence of dark energyenergy
cosmological constant : Ωh ~ t² ~ (1+z)-3
M.Doran,…
small early and large small early and large presentpresent
dark energydark energy fraction in dark energy has fraction in dark energy has
substantially increased since end of substantially increased since end of structure formationstructure formation
expansion of universe accelerates in expansion of universe accelerates in present epochpresent epoch
effects of early dark effects of early dark energyenergy
modifies cosmological evolution (CMB)modifies cosmological evolution (CMB) slows down the growth of structureslows down the growth of structure
SummarySummary
o ΩΩhh = 0.75 = 0.75
o Q/Q/ΛΛ : dynamical und static dark energy will be : dynamical und static dark energy will be distinguishabledistinguishable
o growing neutrino mass can explain why now growing neutrino mass can explain why now problemproblem
o Q : time varying fundamental coupling Q : time varying fundamental coupling “constants” “constants”
violation of equivalence principleviolation of equivalence principle
A few referencesA few references
C.Wetterich , Nucl.Phys.B302,668(1988) , received 24.9.1987C.Wetterich , Nucl.Phys.B302,668(1988) , received 24.9.1987
P.J.E.Peebles,B.Ratra , Astrophys.J.Lett.325,L17(1988) , received 20.10.1987P.J.E.Peebles,B.Ratra , Astrophys.J.Lett.325,L17(1988) , received 20.10.1987
B.Ratra,P.J.E.Peebles , Phys.Rev.D37,3406(1988) , received 16.2.1988B.Ratra,P.J.E.Peebles , Phys.Rev.D37,3406(1988) , received 16.2.1988
J.Frieman,C.T.Hill,A.Stebbins,I.Waga , Phys.Rev.Lett.75,2077(1995)J.Frieman,C.T.Hill,A.Stebbins,I.Waga , Phys.Rev.Lett.75,2077(1995)
P.Ferreira, M.Joyce , Phys.Rev.Lett.79,4740(1997)P.Ferreira, M.Joyce , Phys.Rev.Lett.79,4740(1997)
C.Wetterich , Astron.Astrophys.301,321(1995)C.Wetterich , Astron.Astrophys.301,321(1995)
P.Viana, A.Liddle , Phys.Rev.D57,674(1998)P.Viana, A.Liddle , Phys.Rev.D57,674(1998)
E.Copeland,A.Liddle,D.Wands , Phys.Rev.D57,4686(1998)E.Copeland,A.Liddle,D.Wands , Phys.Rev.D57,4686(1998)
R.Caldwell,R.Dave,P.Steinhardt , Phys.Rev.Lett.80,1582(1998)R.Caldwell,R.Dave,P.Steinhardt , Phys.Rev.Lett.80,1582(1998)
P.Steinhardt,L.Wang,I.Zlatev , Phys.Rev.Lett.82,896(1999)P.Steinhardt,L.Wang,I.Zlatev , Phys.Rev.Lett.82,896(1999)
Cosmon coupling to Cosmon coupling to atomsatoms
Tiny !!!Tiny !!! Substantially weaker than gravity.Substantially weaker than gravity. Non-universal couplings bounded by Non-universal couplings bounded by
teststests
of equivalence principle.of equivalence principle. Universal coupling bounded by tests of Universal coupling bounded by tests of
Brans-Dicke parameter Brans-Dicke parameter ωω in solar in solar system.system.
Only very small influence on cosmology.Only very small influence on cosmology.
effective cosmological effective cosmological constantconstant
linked to neutrino masslinked to neutrino massrealistic value realistic value αα φφt t / M ≈ 276 :/ M ≈ 276 :needed for neutrinos to become non-needed for neutrinos to become non-relativistic in recent past -relativistic in recent past -as required for observed mass range of as required for observed mass range of neutrino massesneutrino massesφφt t / M : essentially determined by present / M : essentially determined by present neutrino mass neutrino mass adjustment of one dimensionless parameteradjustment of one dimensionless parameterin order to obtain for the present time the in order to obtain for the present time the correct ratio between dark energy and neutrinocorrect ratio between dark energy and neutrinoenergy densityenergy density
no fine tuning !no fine tuning !
effective cosmological effective cosmological constantconstant
realistic value realistic value forforαα φφt t / M ≈ 276/ M ≈ 276
equation of stateequation of state
present equationpresent equationof state given byof state given byneutrino mass !neutrino mass !
crossing timecrossing time
from matching between from matching between
early solution and late early solution and late solutionsolution
approximate late approximate late solutionsolution
variables :variables :
approximate smooth solution approximate smooth solution ( averaged over oscillations )( averaged over oscillations )
Growth of density Growth of density fluctuationsfluctuations
Matter dominated universe with Matter dominated universe with constantconstant ΩΩh h ::
Dark energy slows down structure Dark energy slows down structure formationformation
ΩΩh h < 10% during structure < 10% during structure formationformation
P.Ferreira,M.JoyceP.Ferreira,M.Joyce
Early quintessence slows down Early quintessence slows down the the
growth of structuregrowth of structure
bounds on bounds on Early Dark EnergyEarly Dark Energyafter WMAP’06after WMAP’06
G.Robbers,M.Doran,…G.Robbers,M.Doran,…
Cluster number relative to ΛCDM Two models
with 4% Dark Energy during structure formation
Fixed σ8
( normalization dependence ! )
Little Early Dark Energy can make Little Early Dark Energy can make large effect !large effect !
Non – linear enhancementNon – linear enhancement
More clusters at high redshift !
Bartelmann,Doran,…Bartelmann,Doran,…
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