the spectral action and cosmic topologymatilde/cosmictopsmslides.pdf · 2016-02-18 · this lecture...
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The Spectral Action and Cosmic Topology
Matilde Marcolli
Ma148b Spring 2016Topics in Mathematical Physics
Matilde Marcolli The Spectral Action and Cosmic Topology
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This lecture based on
Matilde Marcolli, Elena Pierpaoli, Kevin Teh, The spectralaction and cosmic topology, Commun.Math.Phys.304 (2011)125–174
Matilde Marcolli, Elena Pierpaoli, Kevin Teh, The coupling oftopology and inflation in noncommutative cosmology, Comm.Math. Phys. 309 (2012), no. 2, 341–369
Branimir Cacic, Matilde Marcolli, Kevin Teh, Coupling ofgravity to matter, spectral action and cosmic topology, J.Noncommut. Geom. 8 (2014), no. 2, 473?504
Kevin Teh, Nonperturbative spectral action of round cosetspaces of SU(2), J. Noncommut. Geom. 7 (2013), no. 3,677–708.
Matilde Marcolli The Spectral Action and Cosmic Topology
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The question of Cosmic Topology:
Nontrivial (non-simply-connected) spatial sections of spacetime,homogeneous spherical or flat spaces: how can this be detectedfrom cosmological observations?
Matilde Marcolli The Spectral Action and Cosmic Topology
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Our approach:
NCG provides a modified gravity model through the spectralaction
The nonperturbative form of the spectral action determines aslow-roll inflation potential
The underlying geometry (spherical/flat) affects the shape ofthe potential
Different inflation scenarios depending on geometry andtopology of the cosmos
Shape of the inflation potential readable from cosmologicaldata (CMB)
Matilde Marcolli The Spectral Action and Cosmic Topology
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Cosmic Microwave Background best source of cosmological dataon which to test theoretical models (modified gravity models,cosmic topology hypothesis, particle physics models)
COBE satellite (1989)
WMAP satellite (2001)
Planck satellite (2009)
Matilde Marcolli The Spectral Action and Cosmic Topology
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Matilde Marcolli The Spectral Action and Cosmic Topology
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Cosmic topology and the CMB
Einstein equations determine geometry not topology (don’tdistinguish S3 from S3/Γ with round metric)
Cosmological data (BOOMERanG experiment 1998, WMAPdata 2003): spatial geometry of the universe is flat or slightlypositively curved
Homogeneous and isotropic compact case: spherical spaceforms S3/Γ or Bieberbach manifolds T 3/Γ
Is cosmic topology detected by the Cosmic Microwave Background(CMB)? Search for signatures of multiconnected topologies
Matilde Marcolli The Spectral Action and Cosmic Topology
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CMB sky and spherical harmonics temperature fluctuations
∆T
T=∞∑`=0
∑m=−`
a`mY`m
Y`m spherical harmonics
Methods to address cosmic topology problem
Statistical search for matching circles in the CMB sky:identify a nontrivial fundamental domain
Anomalies of the CMB: quadrupole suppression, the smallvalue of the two- point temperature correlation function atangles above 60 degrees, and the anomalous alignment of thequadrupole and octupole
Residual gravity acceleration: gravitational effects from otherfundamental domains
Bayesian analysis of different models of CMB sky for differentcandidate topologies
Results: no conclusive evidence of a non-simply connected topologyMatilde Marcolli The Spectral Action and Cosmic Topology
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Simulated CMB sky: Laplace spectrum on spherical space forms
4 S. Caillerie et al.: A new analysis of the Poincare dodecahedral space model
out-diameter of the fundamental domain may well be di!erentfrom the theoretical k1 expectation, since these scales representthe physical size of the whole universe, and the observationalarguments for a k1 spectrum at these scales are only valid byassuming simple connectedness. This can be considered as acaveat for the interpretation of the following results.
Such a distribution of matter fluctuations generates a temper-ature distribution on the CMB that results from di!erent physicale!ects. If we subtract foreground contamination, it will mainlybe generated by the ordinary Sachs-Wolfe (OSW) e!ect at largescales, resulting from the the energy exchanges between theCMB photons and the time-varying gravitational fields on thelast scattering surface (LSS). At smaller scales, Doppler oscilla-tions, which arise from the acoustic motion of the baryon-photonfluid, are also important, as well as the OSW e!ect. The ISW ef-fect, important at larger scales, has the same physical origin asthe OSW e!ect but is integrated along the line of sight ratherthan on the LSS. This is summarized in the Sachs-Wolfe for-mula, which gives the temperature fluctuations in a given direc-tion n as
!T
T(n) =
!1
4
!"
"+ "
"(#LSS) ! n.ve(#LSS) +
# #0#LSS
(" + #) d# (22)
where the quantities " and # are the usual Bardeen potentials,and ve is the velocity within the electron fluid; overdots denotetime derivatives. The first terms represent the Sachs-Wolfe andDoppler contributions, evaluated at the LSS. The last term isthe ISW e!ect. This formula is independent of the spatial topol-ogy, and is valid in the limit of an infinitely thin LSS, neglectingreionization.
The temperature distribution is calculated with a CMBFast–like software developed by one of us1, under the form of temper-ature fluctuation maps at the LSS. One such realization is shownin Fig. 1, where the modes up to k = 230 give an angular res-olution of about 6" (i.e. roughly comparable to the resolutionof COBE map), thus without as fine details as in WMAP data.However, this su$ces for a study of topological e!ects, whichare dominant at larger scales.
Such maps are the starting point for topological analysis:firstly, for noise analysis in the search for matched circle pairs,as described in Sect. 3.2; secondly, through their decompositionsinto spherical harmonics, which predict the power spectrum, asdescribed in Sect. 4. In these two ways, the maps allow directcomparison between observational data and theory.
3.2. Circles in the sky
A multi-connected space can be seen as a cell (called the fun-damental domain), copies of which tile the universal cover. Ifthe radius of the LSS is greater than the typical radius of thecell, the LSS wraps all the way around the universe and inter-sects itself along circles. Each circle of self-intersection appearsto the observer as two di!erent circles on di!erent parts of thesky, but with the same OSW components in their temperaturefluctuations, because the two di!erent circles on the sky are re-ally the same circle in space. If the LSS is not too much biggerthan the fundamental cell, each circle pair lies in the planes oftwo matching faces of the fundamental cell. Figure 2 shows theintersection of the various translates of the LSS in the universalcover, as seen by an observer sitting inside one of them.
1 A. Riazuelo developed the program CMBSlow to take into accountnumerous fine e!ects, in particular topological ones.
Fig. 1. Temperature map for a Poincare dodecahedral space with%tot = 1.02, %mat = 0.27 and h = 0.70 (using modes up tok = 230 for a resolution of 6").
Fig. 2. The last scattering surface seen from outside in the uni-versal covering space of the Poincare dodecahedral space with%tot = 1.02, %mat = 0.27 and h = 0.70 (using modes up tok = 230 for a resolution of 6"). Since the volume of the physicalspace is about 80% of the volume of the last scattering surface,the latter intersects itself along six pairs of matching circles.
These circles are generated by a pure Sachs-Wolfe e!ect; inreality additional contributions to the CMB temperature fluctua-tions (Doppler and ISW e!ects) blur the topological signal. Two
(Luminet, Lehoucq, Riazuelo, Weeks, et al.)
Best spherical candidate: Poincare homology 3-sphere(dodecahedral cosmology)
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Simulated CMB sky for a flat Bieberbach G6-cosmology
(from Riazuelo, Weeks, Uzan, Lehoucq, Luminet, 2003)
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R. Aurich, S. Lustig, F. Steiner, H. Then, Cosmic microwavebackground alignment in multi-connected universes, Class.Quantum Grav. 24 (2007) 1879-1894.
E. Gausmann, R. Lehoucq, J.P. Luminet, J.P. Uzan, J. Weeks,Topological lensing in spherical spaces, Class. Quantum Grav. 18(2001) 5155-5186.
M. Lachieze-Rey, J.P. Luminet, Cosmic topology. Physics Reports,254 (1995) 135- 214.
R. Lehoucq, J. Weeks, J.P. Uzan, E. Gausmann, J.P. Luminet,Eigenmodes of threedimensional spherical spaces and theirapplications to cosmology. Class. Quantum Grav. 19 (2002)4683-4708.
J.P. Luminet, J. Weeks, A. Riazuelo, R. Lehoucq, Dodecahedralspace topology as an explanation for weak wide-angle temperaturecorrelations in the cosmic microwave background, Nature 425(2003) 593-595.
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A. Niarchou, A. Jaffe, Imprints of spherical nontrivial topologies onthe cosmic microwave background, Physical Review Letters, 99(2007) 081302
A. Riazuelo, J.P. Uzan, R. Lehoucq, J. Weeks, Simulating CosmicMicrowave Background maps in multi-connected spaces, Phys.Rev.D69 (2004) 103514
A. Riazuelo, J. Weeks, J.P. Uzan, R. Lehoucq, J.P. Luminet, Cosmicmicrowave background anisotropies in multiconnected flat spaces,Phys. Rev. D 69 (2004) 103518
J.P. Uzan, A. Riazuelo, R. Lehoucq, J. Weeks, Cosmic microwavebackground constraints on lens spaces, Phys. Rev. D, 69 (2004),043003, 4 pp.
J. Weeks, J. Gundermann, Dodecahedral topology fails to explainquadrupole-octupole alignment, Class. Quantum Grav. 24 (2007)1863–1866.
J. Weeks, R. Lehoucq, J.P. Uzan, Detecting topology in a nearlyflat spherical universe, Class. Quant. Grav. 20 (2003) 1529–1542.
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Slow-roll models of inflation in the early universeMinkowskian Friedmann metric on Y × R
ds2 = −dt2 + a(t)2ds2Y
accelerated expansion aa = H2(1− ε) Hubble parameter
H2(φ)
(1− 1
3ε(φ)
)=
8π
3m2Pl
V (φ)
mPl Planck mass, inflation phase ε(φ) < 1
A potential V (φ) for a scalar field φ that runs the inflation
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Slow roll parameters
ε(φ) =m2
Pl
16π
(V ′(φ)
V (φ)
)2
η(φ) =m2
Pl
8π
V ′′(φ)
V (φ)
ξ(φ) =m4
Pl
64π2
V ′(φ)V ′′′(φ)
V 2(φ)
⇒ measurable quantities
ns ' 1− 6ε+ 2η, nt ' −2ε, r = 16ε,
αs ' 16εη − 24ε2 − 2ξ, αt ' 4εη − 8ε2
spectral index ns , tensor-to-scalar ratio r , etc.
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Slow roll parameters and the CMBFriedmann metric (expanding universe)
ds2 = −dt2 + a(t)2ds2Y
Separate tensor and scalar perturbation hij of metric (traceless andtrace part) ⇒ Fourier modes: power spectra for scalar and tensorfluctuations, Ps(k) and Pt(k) satisfy power law
Ps(k) ∼ Ps(k0)
(k
k0
)1−ns+αs2
log(k/k0)
Pt(k) ∼ Pt(k0)
(k
k0
)nt+αt2
log(k/k0)
Amplitudes and exponents: constrained by observationalparameters and predicted by models of slow roll inflation(slow roll potential)
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Poisson summation formula: h ∈ S(R) rapidly decaying function∑k∈Z
h(x + 2πk) =1
2π
∑n∈Z
h(n)e inx
function f (x) =∑
k∈Z h(x + 2πk) is 2π-periodic with Fouriercoefficients
fn =1
2π
∫ 2π
0f (x)e−inxdx =
1
2π
∑k∈Z
∫ 2π
0h(x + 2πk)e−inxdx
=1
2π
∑k∈Z
∫ 2π(k+1)
2πkg(x)e−inxdx =
1
2π
∫Rh(x)e−inxdx =
1
2πh(n)
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Spectral action and Poisson summation formula∑n∈Z
h(x + λn) =1
λ
∑n∈Z
exp
(2πinx
λ
)h(
n
λ)
λ ∈ R∗+ and x ∈ R with
h(x) =
∫Rh(u) e−2πiux du
Idea: write Tr(f (D/Λ)) as sums over lattices- Need explicit spectrum of D with multiplicities- Need to write as a union of arithmetic progressions λn,i , n ∈ Z- Multiplicities polynomial functions mλn,i = Pi (λn,i )
Tr(f (D/Λ)) =∑i
∑n∈Z
Pi (λn,i )f (λn,i/Λ)
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The standard topology S3 Dirac spectrum ±a−1( 12 + n) for n ∈ Z,
with multiplicity n(n + 1)
Tr(f (D/Λ)) = (Λa)3f (2)(0)− 1
4(Λa)f (0) + O((Λa)−k)
with f (2) Fourier transform of v2f (v) 4-dimensional Euclidean S3× S1
Tr(h(D2/Λ2)) = πΛ4a3β
∫ ∞0
u h(u) du−1
2πΛaβ
∫ ∞0
h(u) du+O(Λ−k)
g(u, v) = 2P(u) h(u2(Λa)−2 + v2(Λβ)−2)
g(n,m) =
∫R2
g(u, v)e−2πi(xu+yv) du dv
Spectral action in this case computed in
Ali Chamseddine, Alain Connes, The uncanny precision of thespectral action, arXiv:0812.0165
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A slow roll potential: perturbation D2 7→ D2 + φ2 gives potentialV (φ) scalar field coupled to gravity
Tr(h((D2+φ2)/Λ2))) = πΛ4βa3
∫ ∞0
uh(u)du−π2
Λ2βa
∫ ∞0
h(u)du
+πΛ4βa3 V(φ2/Λ2) +1
2Λ2βaW(φ2/Λ2)
V(x) =
∫ ∞0
u(h(u + x)− h(u))du, W(x) =
∫ x
0h(u)du
Parameters: a = radius of 3-sphere, β = auxiliary inversetemperature parameter (choice of Euclidean S1-compactification),Λ = energy scale
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Slow-roll parameters from spectral action: case S = S3
ε(x) =m2
Pl
16π
(h(x)− 2π(Λa)2
∫∞x h(u)du∫ x
0 h(u)du + 2π(Λa)2∫∞
0 u(h(u + x)− h(u))du
)2
η(x) =m2
Pl
8π
h′(x) + 2π(Λa)2h(x)∫ x0 h(u)du + 2π(Λa)2
∫∞0 u(h(u + x)− h(u))du
In Minkowskian Friedmann metric Λ(t) ∼ 1/a(t)
Also independent of β (artificial Euclidean compactification)
Slow-roll potential, cases of spherical and flat topologies:
Matilde Marcolli, Elena Pierpaoli, Kevin Teh, The spectralaction and cosmic topology, arXiv:1005.2256
Matilde Marcolli, Elena Pierpaoli, Kevin Teh, The coupling oftopology and inflation in noncommutative cosmology,arXiv:1012.0780
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The quaternionic space SU(2)/Q8 (quaternion units ±1,±σk)
Dirac spectrum (Ginoux)
3
2+ 4k with multiplicity 2(k + 1)(2k + 1)
3
2+ 4k + 2 with multiplicity 4k(k + 1)
Polynomial interpolation of multiplicities
P1(u) =1
4u2 +
3
4u +
5
16
P2(u) =1
4u2 − 3
4u − 7
16Spectral action
Tr(f (D/Λ)) =1
8(Λa)3f (2)(0)− 1
32(Λa)f (0) + O(Λ−k)
(1/8 of action for S3) with gi (u) = Pi (u)f (u/Λ):
Tr(f (D/Λ)) =1
4(g1(0) + g2(0)) + O(Λ−k)
from Poisson summation ⇒ Same slow-roll parametersMatilde Marcolli The Spectral Action and Cosmic Topology
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Other spherical space forms: method of generating functions tocompute multiplicities (C. Bar)
Spin structures on S3/Γ: homomorphismsε : Γ→ Spin(4) ∼= SU(2)× SU(2) lifting inclusion Γ ↪→ SO(4)under double cover Spin(4)→ SO(4), (A,B) 7→ ABDirac spectrum for S3/Γ subset of spectrum of S3
Multiplicities given by a generating function: ρ+ and ρ− twohalf-spin irreducible reps, χ± their characters
F+(z) =1
|Γ|∑γ∈Γ
χ−(ε(γ))− zχ+(ε(γ))
det(1− zγ)
F−(z) =1
|Γ|∑γ∈Γ
χ+(ε(γ))− zχ−(ε(γ))
det(1− zγ)
Then F+(z) and F−(z) generating functions of spectralmultiplicities
F+(z) =∞∑k=0
m(3
2+ k ,D)zk F−(z) =
∞∑k=0
m(−(3
2+ k),D)zk
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The dodecahedral space Poincare homology sphere S3/Γbinary icosahedral group 120 elementsusing generating function method (Bar):
from K.Teh, Nonperturbative spectral action of round coset spacesof SU(2), arXiv:1010.1827
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Polynomial interpolation of multiplicities: 60 polynomials Pi (u)
59∑j=0
Pj(u) =1
2u2 − 1
8
Spectral action: functions gj(u) = Pj(u)f (u/Λ)
Tr(f (D/Λ)) =1
60
59∑j=0
gj(0) + O(Λ−k)
=1
60
∫R
∑j
Pj(u)f (u/Λ)du + O(Λ−k)
by Poisson summation ⇒ 1/120 of action for S3
Same slow-roll parameters
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But ... different amplitudes of power spectra:multiplicative factor of potential V (φ)
Ps(k) ∼ V 3
(V ′)2, Pt(k) ∼ V
V 7→ λV ⇒ Ps(k0) 7→ λPs(k0), Pt(k0) 7→ λPt(k0)
⇒ distinguish different spherical topologies
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Topological factors (spherical cases):
• Spherical forms Y = S3/Γ, up to O(Λ−∞):
Tr(f (DY /Λ)) =1
#Γ
(Λ3f (2)(0)− 1
4Λf (0)
)=
1
#ΓTr(f (DS3/Λ))
Y spherical λYsphere 1
lens N 1/N
binary dihedral 4N 1/(4N)
binary tetrahedral 1/24
binary octahedral 1/48
binary icosahedral 1/120
Note: λY does not distinguish all of them
Kevin Teh, Nonperturbative Spectral Action of Round CosetSpaces of SU(2), arXiv:1010.1827.
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The flat tori: Dirac spectrum (Bar)
± 2π ‖ (m, n, p) + (m0, n0, p0) ‖, (1)
(m, n, p) ∈ Z3 multiplicity 1 and constant vector (m0, n0, p0)depending on spin structure
Tr(f (D23/Λ2)) =
∑(m,n,p)∈Z3
2f
(4π2((m + m0)2 + (n + n0)2 + (p + p0)2)
Λ2
)
Poisson summation∑Z3
g(m, n, p) =∑Z3
g(m, n, p)
g(m, n, p) =
∫R3
g(u, v ,w)e−2πi(mu+nv+pw)dudvdw
g(m, n, p) = f
(4π2((m + m0)2 + (n + n0)2 + (p + p0)2)
Λ2
)Matilde Marcolli The Spectral Action and Cosmic Topology
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Spectral action for the flat tori
Tr(f (D23/Λ2)) =
Λ3
4π3
∫R3
f (u2 + v2 + w2)du dv dw + O(Λ−k)
X = T 3 × S1β :
Tr(h(D2X/Λ2)) =
Λ4β`3
4π
∫ ∞0
uh(u)du + O(Λ−k)
using∑(m,n,p,r)∈Z4
2 h
(4π2
(Λ`)2((m + m0)2 + (n + n0)2 + (p + p0)2) +
1
(Λβ)2(r +
1
2)2
)
g(u, v ,w , y) = 2 h
(4π2
Λ2(u2 + v2 + w2) +
y2
(Λβ)2
)∑
(m,n,p,r)∈Z4
g(m+m0, n+n0, p+p0, r +1
2) =
∑(m,n,p,r)∈Z4
(−1)r g(m, n, p, r)
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Different slow-roll potential and parameters Introducing theperturbation D2 7→ D2 + φ2:
Tr(h((D2X + φ2)/Λ2)) = Tr(h(D2
X/Λ2)) +Λ4β`3
4πV(φ2/Λ2)
slow-roll potential
V (φ) =Λ4β`3
4πV(φ2/Λ2)
V(x) =
∫ ∞0
u (h(u + x)− h(u)) du
Slow-roll parameters (different from spherical cases)
ε =m2
Pl
16π
( ∫∞x
h(u)du∫∞0
u(h(u + x)− h(u))du
)2
η =m2
Pl
8π
(h(x)∫∞
0u(h(u + x)− h(u))du
)Matilde Marcolli The Spectral Action and Cosmic Topology
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Bieberbach manifoldsQuotients of T 3 by group actions: G2, G3, G4, G5, G6spin structures
δ1 δ2 δ3
(a) ±1 1 1
(b) ±1 −1 1
(c) ±1 1 −1
(d) ±1 −1 −1
G2(a), G2(b), G2(c), G2(d), etc.Dirac spectra known (Pfaffle)Note: spectra often different for different spin structures... but spectral action same!
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Bieberbach cosmic topologies (ti = translations by ai )• G2 = half turn spacelattice a1 = (0, 0,H), a2 = (L, 0, 0), and a3 = (T ,S , 0), withH, L, S ∈ R∗+ and T ∈ R
α2 = t1, αt2α−1 = t−1
2 , αt3α−1 = t−1
3
• G3 = third turn space
lattice a1 = (0, 0,H), a2 = (L, 0, 0) and a3 = (−12L,
√3
2 L, 0), for Hand L in R∗+
α3 = t1, αt2α−1 = t3, αt3α
−1 = t−12 t−1
3
• G4 = quarter turn spacelattice a1 = (0, 0,H), a2 = (L, 0, 0), and a3 = (0, L, 0), withH, L > 0
α4 = t1, αt2α−1 = t3, αt3α
−1 = t−12
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• G5 = sixth turn space
lattice a1 = (0, 0,H), a2 = (L, 0, 0) and a3 = ( 12L,
√3
2 L, 0),H, L > 0
α6 = t1, αt2α−1 = t3, αt3α
−1 = t−12 t3
• G6 = Hantzsche–Wendt space (π-twist along each coordinateaxis)lattice a1 = (0, 0,H), a2 = (L, 0, 0), and a3 = (0,S , 0), withH, L, S > 0
α2 = t1, αt2α−1 = t−1
2 , αt3α−1 = t−1
3 ,
β2 = t2, βt1β−1 = t−1
1 , βt3β−1 = t−1
3 ,
γ2 = t3, γt1γ−1 = t−1
1 , γt2γ−1 = t−1
2 ,γβα = t1t3.
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Lattice summation technique for Bieberbach manifolds:Example G3 case: λ±klm symmetries R : l 7→ −l ,m 7→ −m,S : l 7→ m,m 7→ l , T : l 7→ l −m,m 7→ −m
Z3 = I ∪ R(I ) ∪ S(I ) ∪ RS(I ) ∪ T (I ) ∪ RT (I ) ∪ {l = m}I = {(k , l ,m) ∈ Z3 : l ≥ 1,m = 0, . . . , l − 1} andI = {(k , l ,m) ∈ Z3 : l ≥ 2,m = 1, . . . , l − 1}
l
m
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Topological factors (flat cases):
• Bieberbach manifolds spectral action
Tr(f (D2Y /Λ2)) =
λY Λ3
4π3
∫R3
f (u2 + v2 + w2)dudvdw
up to oder O(Λ−∞) with factors
λY =
HSL2 G2
HL2
2√
3G3
HL2
4 G4
HLS4 G6
Note lattice summation technique not immediately suitable for G5,but expect like G3 up to factor of 2
Matilde Marcolli The Spectral Action and Cosmic Topology
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Topological factors and inflation slow-roll potential
⇒ Multiplicative factor in amplitude of power spectra
Matilde Marcolli The Spectral Action and Cosmic Topology
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Adding the coupling to matter Y × FNot only product but nontrivial fibrationVector bundle V over 3-manifold Y , fiber HF (fermion content)Dirac operator DY twisted with connection on V (bosons)
Spectra of twisted Dirac operators on spherical manifolds(Cisneros–Molina)
Similar computation with Poisson summation formula
Tr(f (D2Y /Λ2)) =
N
#Γ
(Λ3f (2)(0)− 1
4Λf (0)
)up to order O(Λ−∞)representation V dimension N; spherical form Y = S3/Γ⇒ topological factor λY 7→ NλY
Matilde Marcolli The Spectral Action and Cosmic Topology
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Variant: almost commutative geometries
(C∞(M, E), L2(M, E ⊗ S),DE)
M smooth manifold, E algebra bundle: fiber Ex finitedimensional algebra AF
C∞(M, E) smooth sections of a algebra bundle EDirac operator DE = c ◦ (∇E ⊗ 1 + 1⊗∇S) with spinconnection ∇S and hermitian connection on bundle
Compatible grading and real structure
An equivalent intrinsic (abstract) characterization in:
Branimir Cacic, A reconstruction theorem foralmost-commutative spectral triples, arXiv:1101.5908
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Basic Setup
• Γ ⊂ SU(2) finite group isometries of S3
• spinor bundle on spherical form S3/Γ given byS3 ×σ C2 → S3/Γ, with σ representation of Γ (standardrepresentation of SU(2) on C2)
• unitary representation α : Γ→ U(N) defines a flat bundleVα = S3 ×α CN with a canonical flat connection
• twisting Dirac operator with flat bundle, DΓα on S3/Γ acting on
twisted spinors: Γ-equivariant sections C∞(S3,C2 ⊗ CN)Γ
• Γ acts by isometries on S3 and by σ ⊗ α on C2 ⊗ CN
• DΓα restriction of the Dirac operator D ⊗ idCN to subspace
C∞(S3,C2 ⊗ CN)Γ ⊂ C∞(S3,C2 ⊗ CN)
Matilde Marcolli The Spectral Action and Cosmic Topology
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Dirac spectrum (Cisneros-Molina)
• α : Γ→ GLN(C) representation of Γ and Dirac operator DΓα
• dimCHomΓ(Ek ,C2 ⊗ CN), in terms of pairing 〈χEk, χσ⊗α〉Γ of
characters of corresponding Γ-representations
• eigenvalues of DΓα on S3/Γ
−1
2− (k + 1) with multiplicity 〈χEk+1
, χα〉Γ(k + 1), if k ≥ 0,
−1
2+ (k + 1) with multiplicity 〈χEk−1
, χα〉Γ(k + 1), if k ≥ 1.
Matilde Marcolli The Spectral Action and Cosmic Topology
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• cΓ least common multiple of orders of elements in Γ
• k = cΓl + m with 0 ≤ m < cΓ
1 If −1 ∈ Γ, then
〈χEk, χα〉Γ =
{cΓl#Γ (χα(1) + χα(−1)) + 〈χEm , χα〉Γ if k is even,cΓl#Γ (χα(1)− χα(−1)) + 〈χEm , χα〉Γ if k is odd.
2 If −1 /∈ Γ, then
〈χEk, χα〉Γ =
NcΓl
#Γ+ 〈χEm , χα〉Γ.
Poisson Summation Formula again to compute spectral action
Matilde Marcolli The Spectral Action and Cosmic Topology
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Character tables• Example: binary icosahedral group order 120
Class 1+ 1− 30 20+ 20− 12a+ 12b+ 12a− 12b−Order 1 2 4 6 3 10 5 5 10
χ1 1 1 1 1 1 1 1 1 1
χ2 2 −2 0 1 −1 µ ν −µ −νχ3 2 −2 0 1 −1 −ν −µ ν µ
χ4 3 3 −1 0 0 −ν µ −ν µ
χ5 3 3 −1 0 0 µ −ν µ −νχ6 4 4 0 1 1 −1 −1 −1 −1
χ7 4 −4 0 −1 1 1 −1 −1 1
χ8 5 5 1 −1 −1 0 0 0 0
χ9 6 −6 0 0 0 −1 1 1 −1
with µ =√
5+12 , and ν =
√5−12
Matilde Marcolli The Spectral Action and Cosmic Topology
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Polynomials P+m and P−m interpolating multiplicities of positive and
negative spectrum
cΓ∑m=1
P+m(u) =
cΓ−1∑m=0
P−m(u) =NcΓ
#Γ
(u2 − 1
4
).
Spectral Action after Poisson summation
Trf (D/Λ) =N
#Γ
(Λ3f (2)(0)− 1
4Λf (0)
)+ O(Λ−∞)
with α an N-dimensional representation and with f (2) the Fouriertransform of u2f (u)
Matilde Marcolli The Spectral Action and Cosmic Topology
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Heat Kernel argument
• f (x) = L[φ](x2) for some measurable φ : R+ → C then
Tr (f (D/Λ)) =
∫ ∞0
Tr(e−sD
2/Λ2)φ(s)ds
• V self-adjoint Clifford module bundle on a manifold M and DDirac-type operator on V
Tr (f (D/Λ)) =
∫ ∞0
[∫Mtr(K (s/Λ2, x , x)
)dvol(x)
]with K (t, x , y) heat kernel of D2
• Asymptotic expansion
Tr (f (D/Λ)) ∼∞∑
k=− dimM
Λ−kφk
∫Mak+dimM(x ,D2)dvol(x)
an(x ,D2) Seeley-DeWitt coefficients and φn =∫∞
0 φ(s)sn/2ds
Matilde Marcolli The Spectral Action and Cosmic Topology
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• M → M covering, V → M be a Γ-equivariant self-adjoint Cliffordmodule bundle with D a Γ-equivariant symmetric Dirac-typeoperator on V• quotient V := V/Γ→ M = M/Γ with D descending tosymmetric Dirac-type operator D on V• then Spectral Action:
Tr (f (D/Λ)) =1
#ΓTr(f (D/Λ)
)+ O(Λ−∞)
• from heat kernel and relation between spectral action and heatkernel
Tr(e−tD
2)
=1
#ΓTr(e−tD
2)
+1
#Γ
∑γ∈Γ\{e}
∫Mtr(ρ(γ)(xγ−1)K (t, xγ−1, x)
)dvol(x),
• also version with D2 + φ2 and inflation potential V (φ)Matilde Marcolli The Spectral Action and Cosmic Topology
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Conclusion (for now)
A modified gravity model based on the spectral action candistinguish between the different cosmic topology in terms of theslow-roll parameters (distinguish spherical and flat cases) and theamplitudes of the power spectral (distinguish different sphericalspace forms and different Bieberbach manifolds).
Inflation potential also gets an overall multiplicative factor fromthe number of fermion generations in the model.
Different inflation scenarios in different topologies
Matilde Marcolli The Spectral Action and Cosmic Topology