Vacuum Fluctuations CosmologyICE Vacuum Fluctuations & Cosmology EMILIO ELIZALDE ICE/CSIC & IEEC,...
Transcript of Vacuum Fluctuations CosmologyICE Vacuum Fluctuations & Cosmology EMILIO ELIZALDE ICE/CSIC & IEEC,...
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ICE
Vacuum Fluctuations&
Cosmology
EMILIO ELIZALDE
ICE/CSIC & IEEC, UAB, Barcelona
4th Sakharov Conference, Moscow, May 21, 2009
4th Sakharov Conference, Moscow, May 21, 2009 – p. 1/32
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Outline of this presentation
Einstein’s Cosmological Constant
4th Sakharov Conference, Moscow, May 21, 2009 – p. 2/32
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Outline of this presentation
Einstein’s Cosmological Constant
On the Casimir Effect & the ζ Function Method
4th Sakharov Conference, Moscow, May 21, 2009 – p. 2/32
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Outline of this presentation
Einstein’s Cosmological Constant
On the Casimir Effect & the ζ Function Method
Fulling-Davies Theory (Dynamical CE)
4th Sakharov Conference, Moscow, May 21, 2009 – p. 2/32
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Outline of this presentation
Einstein’s Cosmological Constant
On the Casimir Effect & the ζ Function Method
Fulling-Davies Theory (Dynamical CE)
CE and Accelerated Expansion (Dark Energy)
4th Sakharov Conference, Moscow, May 21, 2009 – p. 2/32
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Outline of this presentation
Einstein’s Cosmological Constant
On the Casimir Effect & the ζ Function Method
Fulling-Davies Theory (Dynamical CE)
CE and Accelerated Expansion (Dark Energy)
Gravity Eqs as Eqs of State
4th Sakharov Conference, Moscow, May 21, 2009 – p. 2/32
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Outline of this presentation
Einstein’s Cosmological Constant
On the Casimir Effect & the ζ Function Method
Fulling-Davies Theory (Dynamical CE)
CE and Accelerated Expansion (Dark Energy)
Gravity Eqs as Eqs of State
With THANKS to:G. Cognola, J. Haro, S.D. Odintsov, P.J. Silva, S.Zerbini, ...
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Einstein’s Cosmological ConstantOur universe seems to be spatially flat and to possess a non-vanishing
cosmological constant
For cosmologists and general relativists: a great mistake (Einstein)
Rµν − 1
2gµνR = −(8πG/c4)Tµν+λgµν
For elementary particle physicists: a great embarrassment
no way to get rid off (Coleman, Weinberg, Polchinski)
The cc Λ is indeed a peculiar quantity
has to do with cosmology Einstein’s eqs., FRW universe
has to do with the local structure of elementary particle physics
stress-energy density µ of the vacuum
Lcc =
∫d4x
√−g µ4 =
1
8πG
∫d4x
√−g λ
In other words: two contributions on the same footing (Zel’dovich, 68)
Λ c2
8πG+
1
Vol~ c
2
∑
i
ωi
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Zero point energy
QFT vacuum to vacuum transition: 〈0|H|0〉
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Zero point energy
QFT vacuum to vacuum transition: 〈0|H|0〉Spectrum, normal ordering (harm oscill):
H =
(n +
1
2
)λn an a†n
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Zero point energy
QFT vacuum to vacuum transition: 〈0|H|0〉Spectrum, normal ordering (harm oscill):
H =
(n +
1
2
)λn an a†n
〈0|H|0〉 =~ c
2
∑
n
λn =1
2tr H =
1
2ζµH(−1)
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Zero point energy
QFT vacuum to vacuum transition: 〈0|H|0〉Spectrum, normal ordering (harm oscill):
H =
(n +
1
2
)λn an a†n
〈0|H|0〉 =~ c
2
∑
n
λn =1
2tr H =
1
2ζµH(−1)
gives ∞ physical meaning?
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Zero point energy
QFT vacuum to vacuum transition: 〈0|H|0〉Spectrum, normal ordering (harm oscill):
H =
(n +
1
2
)λn an a†n
〈0|H|0〉 =~ c
2
∑
n
λn =1
2tr H =
1
2ζµH(−1)
gives ∞ physical meaning?
Regularization + Renormalization ( cut-off, dim, ζ )
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Zero point energy
QFT vacuum to vacuum transition: 〈0|H|0〉Spectrum, normal ordering (harm oscill):
H =
(n +
1
2
)λn an a†n
〈0|H|0〉 =~ c
2
∑
n
λn =1
2tr H =
1
2ζµH(−1)
gives ∞ physical meaning?
Regularization + Renormalization ( cut-off, dim, ζ )
Even then: Has the final value real sense ?
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Existence ofζA for A a ΨDO1. A a positive-definite elliptic ΨDO of positive order m ∈ R+
2. A acts on the space of smooth sections of
3. E, n-dim vector bundle over
4. M closed n-dim manifold
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Existence ofζA for A a ΨDO1. A a positive-definite elliptic ΨDO of positive order m ∈ R+
2. A acts on the space of smooth sections of
3. E, n-dim vector bundle over
4. M closed n-dim manifold
(a) The zeta function is defined as:ζA(s) = tr A−s =
∑j λ
−sj , Re s > n
m := s0
λj ordered spect of A, s0 = dimM/ordA abscissa of converg of ζA(s)
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Existence ofζA for A a ΨDO1. A a positive-definite elliptic ΨDO of positive order m ∈ R+
2. A acts on the space of smooth sections of
3. E, n-dim vector bundle over
4. M closed n-dim manifold
(a) The zeta function is defined as:ζA(s) = tr A−s =
∑j λ
−sj , Re s > n
m := s0
λj ordered spect of A, s0 = dimM/ordA abscissa of converg of ζA(s)
(b) ζA(s) has a meromorphic continuation to the whole complex plane C
(regular at s = 0), provided the principal symbol of A, am(x, ξ), admits aspectral cut: Lθ = λ ∈ C; Argλ = θ, θ1 < θ < θ2, SpecA ∩ Lθ = ∅(the Agmon-Nirenberg condition)
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Existence ofζA for A a ΨDO1. A a positive-definite elliptic ΨDO of positive order m ∈ R+
2. A acts on the space of smooth sections of
3. E, n-dim vector bundle over
4. M closed n-dim manifold
(a) The zeta function is defined as:ζA(s) = tr A−s =
∑j λ
−sj , Re s > n
m := s0
λj ordered spect of A, s0 = dimM/ordA abscissa of converg of ζA(s)
(b) ζA(s) has a meromorphic continuation to the whole complex plane C
(regular at s = 0), provided the principal symbol of A, am(x, ξ), admits aspectral cut: Lθ = λ ∈ C; Argλ = θ, θ1 < θ < θ2, SpecA ∩ Lθ = ∅(the Agmon-Nirenberg condition)
(c) The definition of ζA(s) depends on the position of the cut Lθ
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Existence ofζA for A a ΨDO1. A a positive-definite elliptic ΨDO of positive order m ∈ R+
2. A acts on the space of smooth sections of
3. E, n-dim vector bundle over
4. M closed n-dim manifold
(a) The zeta function is defined as:ζA(s) = tr A−s =
∑j λ
−sj , Re s > n
m := s0
λj ordered spect of A, s0 = dimM/ordA abscissa of converg of ζA(s)
(b) ζA(s) has a meromorphic continuation to the whole complex plane C
(regular at s = 0), provided the principal symbol of A, am(x, ξ), admits aspectral cut: Lθ = λ ∈ C; Argλ = θ, θ1 < θ < θ2, SpecA ∩ Lθ = ∅(the Agmon-Nirenberg condition)
(c) The definition of ζA(s) depends on the position of the cut Lθ
(d) The only possible singularities of ζA(s) are poles atsj = (n− j)/m, j = 0, 1, 2, . . . , n− 1, n+ 1, . . .
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Definition of DeterminantH ΨDO operator ϕi, λi spectral decomposition
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Definition of DeterminantH ΨDO operator ϕi, λi spectral decomposition
∏i∈I λi ?! ln
∏i∈I λi =
∑i∈I lnλi
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Definition of DeterminantH ΨDO operator ϕi, λi spectral decomposition
∏i∈I λi ?! ln
∏i∈I λi =
∑i∈I lnλi
Riemann zeta func: ζ(s) =∑∞
n=1 n−s, Re s > 1 (& analytic cont)
Definition: zeta function of H ζH(s) =∑
i∈I λ−si = trH−s
As Mellin transform: ζH(s) = 1Γ(s)
∫ ∞0 dt ts−1 tr e−tH , Res > s0
Derivative: ζ ′H(0) = −∑i∈I lnλi
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Definition of DeterminantH ΨDO operator ϕi, λi spectral decomposition
∏i∈I λi ?! ln
∏i∈I λi =
∑i∈I lnλi
Riemann zeta func: ζ(s) =∑∞
n=1 n−s, Re s > 1 (& analytic cont)
Definition: zeta function of H ζH(s) =∑
i∈I λ−si = trH−s
As Mellin transform: ζH(s) = 1Γ(s)
∫ ∞0 dt ts−1 tr e−tH , Res > s0
Derivative: ζ ′H(0) = −∑i∈I lnλi
Determinant: Ray & Singer, ’67detζ H = exp [−ζ ′H(0)]
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Definition of DeterminantH ΨDO operator ϕi, λi spectral decomposition
∏i∈I λi ?! ln
∏i∈I λi =
∑i∈I lnλi
Riemann zeta func: ζ(s) =∑∞
n=1 n−s, Re s > 1 (& analytic cont)
Definition: zeta function of H ζH(s) =∑
i∈I λ−si = trH−s
As Mellin transform: ζH(s) = 1Γ(s)
∫ ∞0 dt ts−1 tr e−tH , Res > s0
Derivative: ζ ′H(0) = −∑i∈I lnλi
Determinant: Ray & Singer, ’67detζ H = exp [−ζ ′H(0)]
Weierstrass def: subtract leading behavior of λi in i, as i→ ∞,
until series∑
i∈I lnλi converges =⇒ non-local counterterms !!
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Definition of DeterminantH ΨDO operator ϕi, λi spectral decomposition
∏i∈I λi ?! ln
∏i∈I λi =
∑i∈I lnλi
Riemann zeta func: ζ(s) =∑∞
n=1 n−s, Re s > 1 (& analytic cont)
Definition: zeta function of H ζH(s) =∑
i∈I λ−si = trH−s
As Mellin transform: ζH(s) = 1Γ(s)
∫ ∞0 dt ts−1 tr e−tH , Res > s0
Derivative: ζ ′H(0) = −∑i∈I lnλi
Determinant: Ray & Singer, ’67detζ H = exp [−ζ ′H(0)]
Weierstrass def: subtract leading behavior of λi in i, as i→ ∞,
until series∑
i∈I lnλi converges =⇒ non-local counterterms !!
C. Soulé et al, Lectures on Arakelov Geometry, CUP 1992; A. Voros,...
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PropertiesThe definition of the determinant detζ A only depends on thehomotopy class of the cut
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PropertiesThe definition of the determinant detζ A only depends on thehomotopy class of the cut
A zeta function (and corresponding determinant) with the samemeromorphic structure in the complex s-plane and extending theordinary definition to operators of complex order m ∈ C\Z (they do notadmit spectral cuts), has been obtained [Kontsevich and Vishik]
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PropertiesThe definition of the determinant detζ A only depends on thehomotopy class of the cut
A zeta function (and corresponding determinant) with the samemeromorphic structure in the complex s-plane and extending theordinary definition to operators of complex order m ∈ C\Z (they do notadmit spectral cuts), has been obtained [Kontsevich and Vishik]
Asymptotic expansion for the heat kernel:
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PropertiesThe definition of the determinant detζ A only depends on thehomotopy class of the cut
A zeta function (and corresponding determinant) with the samemeromorphic structure in the complex s-plane and extending theordinary definition to operators of complex order m ∈ C\Z (they do notadmit spectral cuts), has been obtained [Kontsevich and Vishik]
Asymptotic expansion for the heat kernel:
tr e−tA =∑′
λ∈Spec A e−tλ
∼ αn(A) +∑
n6=j≥0 αj(A)t−sj +∑
k≥1 βk(A)tk ln t, t ↓ 0
αn(A) = ζA(0), αj(A) = Γ(sj) Ress=sjζA(s), sj /∈ −N
αj(A) = (−1)k
k! [PP ζA(−k) + ψ(k + 1) Ress=−k ζA(s)] ,
sj = −k, k ∈ N
βk(A) = (−1)k+1
k! Ress=−k ζA(s), k ∈ N\0
PP φ := lims→p
[φ(s) − Ress=p φ(s)
s−p
]
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The Chowla-Selberg Expansion Formula: BasicsJacobi’s identity for the θ−function
θ3(z, τ) := 1 + 2∑∞
n=1 qn2cos(2nz), q := eiπτ , τ ∈ C
θ3(z, τ) = 1√−iτ
ez2/iπτ θ3
(zτ|−1
τ
)equivalently:
∞∑
n=−∞
e−(n+z)2t =
√π
t
∞∑
n=0
e−π2n2
t cos(2πnz), z, t ∈ C, Ret > 0
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The Chowla-Selberg Expansion Formula: BasicsJacobi’s identity for the θ−function
θ3(z, τ) := 1 + 2∑∞
n=1 qn2cos(2nz), q := eiπτ , τ ∈ C
θ3(z, τ) = 1√−iτ
ez2/iπτ θ3
(zτ|−1
τ
)equivalently:
∞∑
n=−∞
e−(n+z)2t =
√π
t
∞∑
n=0
e−π2n2
t cos(2πnz), z, t ∈ C, Ret > 0
Higher dimensions: Poisson summ formula (Riemann)∑
~n∈Zp
f(~n) =∑
~m∈Zp
f(~m)
f Fourier transform[Gelbart + Miller, BAMS ’03, Iwaniec, Morgan, ICM ’06]
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The Chowla-Selberg Expansion Formula: BasicsJacobi’s identity for the θ−function
θ3(z, τ) := 1 + 2∑∞
n=1 qn2cos(2nz), q := eiπτ , τ ∈ C
θ3(z, τ) = 1√−iτ
ez2/iπτ θ3
(zτ|−1
τ
)equivalently:
∞∑
n=−∞
e−(n+z)2t =
√π
t
∞∑
n=0
e−π2n2
t cos(2πnz), z, t ∈ C, Ret > 0
Higher dimensions: Poisson summ formula (Riemann)∑
~n∈Zp
f(~n) =∑
~m∈Zp
f(~m)
f Fourier transform[Gelbart + Miller, BAMS ’03, Iwaniec, Morgan, ICM ’06]
Truncated sums −→ asymptotic series
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Extended CS Formulas (ECS)Consider the zeta function (Res > p/2, A > 0,Req > 0)
ζA,~c,q(s) =∑
~n∈Zp
′[1
2(~n+ ~c)
TA (~n+ ~c) + q
]−s
=∑
~n∈Zp
′[Q (~n+ ~c) + q]
−s
prime: point ~n = ~0 to be excluded from the sum(inescapable condition when c1 = · · · = cp = q = 0)
Q (~n+ ~c) + q = Q(~n) + L(~n) + q
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Extended CS Formulas (ECS)Consider the zeta function (Res > p/2, A > 0,Req > 0)
ζA,~c,q(s) =∑
~n∈Zp
′[1
2(~n+ ~c)
TA (~n+ ~c) + q
]−s
=∑
~n∈Zp
′[Q (~n+ ~c) + q]
−s
prime: point ~n = ~0 to be excluded from the sum(inescapable condition when c1 = · · · = cp = q = 0)
Q (~n+ ~c) + q = Q(~n) + L(~n) + q
Case q 6= 0 (Req > 0)
ζA,~c,q(s) =(2π)p/2qp/2−s
√det A
Γ(s − p/2)
Γ(s)+
2s/2+p/4+2πsq−s/2+p/4
√det A Γ(s)
×∑
~m∈Zp1/2
′ cos(2π~m · ~c)(~mT A−1 ~m
)s/2−p/4Kp/2−s
(2π
√2q ~mT A−1 ~m
)
[ECS1]
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Extended CS Formulas (ECS)Consider the zeta function (Res > p/2, A > 0,Req > 0)
ζA,~c,q(s) =∑
~n∈Zp
′[1
2(~n+ ~c)
TA (~n+ ~c) + q
]−s
=∑
~n∈Zp
′[Q (~n+ ~c) + q]
−s
prime: point ~n = ~0 to be excluded from the sum(inescapable condition when c1 = · · · = cp = q = 0)
Q (~n+ ~c) + q = Q(~n) + L(~n) + q
Case q 6= 0 (Req > 0)
ζA,~c,q(s) =(2π)p/2qp/2−s
√det A
Γ(s − p/2)
Γ(s)+
2s/2+p/4+2πsq−s/2+p/4
√det A Γ(s)
×∑
~m∈Zp1/2
′ cos(2π~m · ~c)(~mT A−1 ~m
)s/2−p/4Kp/2−s
(2π
√2q ~mT A−1 ~m
)
[ECS1]Pole: s = p/2 Residue:
Ress=p/2 ζA,~c,q(s) =(2π)p/2
Γ(p/2)(detA)−1/2
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Gives (analytic cont of) multidimensional zeta function in terms of anexponentially convergent multiseries, valid in the whole complex plane
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Gives (analytic cont of) multidimensional zeta function in terms of anexponentially convergent multiseries, valid in the whole complex plane
Exhibits singularities (simple poles) of the meromorphic continuation—with the corresponding residua— explicitly
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Gives (analytic cont of) multidimensional zeta function in terms of anexponentially convergent multiseries, valid in the whole complex plane
Exhibits singularities (simple poles) of the meromorphic continuation—with the corresponding residua— explicitly
Only condition on matrix A: corresponds to (non negative) quadraticform, Q. Vector ~c arbitrary, while q is (to start) a non-neg constant
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Gives (analytic cont of) multidimensional zeta function in terms of anexponentially convergent multiseries, valid in the whole complex plane
Exhibits singularities (simple poles) of the meromorphic continuation—with the corresponding residua— explicitly
Only condition on matrix A: corresponds to (non negative) quadraticform, Q. Vector ~c arbitrary, while q is (to start) a non-neg constant
Kν modified Bessel function of the second kind and the subindex 1/2in Z
p1/2 means that only half of the vectors ~m ∈ Z
p participate in thesum. E.g., if we take an ~m ∈ Z
p we must then exclude −~m[simple criterion: one may select those vectors in Z
p\~0 whosefirst non-zero component is positive]
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Gives (analytic cont of) multidimensional zeta function in terms of anexponentially convergent multiseries, valid in the whole complex plane
Exhibits singularities (simple poles) of the meromorphic continuation—with the corresponding residua— explicitly
Only condition on matrix A: corresponds to (non negative) quadraticform, Q. Vector ~c arbitrary, while q is (to start) a non-neg constant
Kν modified Bessel function of the second kind and the subindex 1/2in Z
p1/2 means that only half of the vectors ~m ∈ Z
p participate in thesum. E.g., if we take an ~m ∈ Z
p we must then exclude −~m[simple criterion: one may select those vectors in Z
p\~0 whosefirst non-zero component is positive]
Case c1 = · · · = cp = q = 0 [true extens of CS, diag subcase]
ζAp(s) =21+s
Γ(s)
p−1∑
j=0
(det Aj)−1/2
[πj/2a
j/2−sp−j Γ
(s − j
2
)ζR(2s−j) +
4πsaj4− s
2p−j
∞∑
n=1
∑
~mj∈Zj
′nj/2−s(~mt
jA−1j ~mj
)s/2−j/4Kj/2−s
(2πn
√ap−j ~mt
jA−1j ~mj
)]
[ECS3d]
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The Casimir Effect
vacuum
BC
F
Casimir Effect
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The Casimir Effect
vacuum
BC
F
Casimir Effect
BC e.g. periodic
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The Casimir Effect
vacuum
BC
F
Casimir Effect
BC e.g. periodic=⇒ all kind of fields
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The Casimir Effect
vacuum
BC
F
Casimir Effect
BC e.g. periodic=⇒ all kind of fields=⇒ curvature or topology
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The Casimir Effect
vacuum
BC
F
Casimir Effect
BC e.g. periodic=⇒ all kind of fields=⇒ curvature or topology
Universal process:
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The Casimir Effect
vacuum
BC
F
Casimir Effect
BC e.g. periodic=⇒ all kind of fields=⇒ curvature or topology
Universal process:
Sonoluminiscence (Schwinger)
Cond. matter (wetting 3He alc.)
Optical cavities
Direct experim. confirmation
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The Casimir Effect
vacuum
BC
F
Casimir Effect
BC e.g. periodic=⇒ all kind of fields=⇒ curvature or topology
Universal process:
Sonoluminiscence (Schwinger)
Cond. matter (wetting 3He alc.)
Optical cavities
Direct experim. confirmation
Van der Waals, Lifschitz theory
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The Casimir Effect
vacuum
BC
F
Casimir Effect
BC e.g. periodic=⇒ all kind of fields=⇒ curvature or topology
Universal process:
Sonoluminiscence (Schwinger)
Cond. matter (wetting 3He alc.)
Optical cavities
Direct experim. confirmation
Van der Waals, Lifschitz theoryDynamical CE ⇐Lateral CE
Extract energy from vacuum
CE and the cosmological constant ⇐4th Sakharov Conference, Moscow, May 21, 2009 – p. 11/32
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The standard approach
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The standard approach=⇒ Casimir force: calculatedby computing change in zeropoint energy of the em field
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The standard approach=⇒ Casimir force: calculatedby computing change in zeropoint energy of the em field
=⇒ But Casimireffects can be calculatedas S-matrix elements:Feynman diagrs with ext. lines
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The standard approach=⇒ Casimir force: calculatedby computing change in zeropoint energy of the em field
=⇒ But Casimireffects can be calculatedas S-matrix elements:Feynman diagrs with ext. lines
In modern language the Casimir energy can be expressed in terms of thetrace of the Greens function for the fluctuating field in the background ofinterest (conducting plates)
E =~
2πIm
∫dωω Tr
∫d3x [G(x, x, ω + iǫ) − G0(x, x, ω + iǫ)]
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The standard approach=⇒ Casimir force: calculatedby computing change in zeropoint energy of the em field
=⇒ But Casimireffects can be calculatedas S-matrix elements:Feynman diagrs with ext. lines
In modern language the Casimir energy can be expressed in terms of thetrace of the Greens function for the fluctuating field in the background ofinterest (conducting plates)
E =~
2πIm
∫dωω Tr
∫d3x [G(x, x, ω + iǫ) − G0(x, x, ω + iǫ)]
G full Greens function for the fluctuating fieldG0 free Greens function Trace is over spin
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EC = 〈 〉plates− 〈 〉no plates
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EC = 〈 〉plates− 〈 〉no plates
1
πIm
∫[G(x, x, ω + iǫ) − G0(x, x, ω + iǫ)] =
d∆N
dω
change in the density of states due to the background
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EC = 〈 〉plates− 〈 〉no plates
1
πIm
∫[G(x, x, ω + iǫ) − G0(x, x, ω + iǫ)] =
d∆N
dω
change in the density of states due to the background
=⇒ A restatement of the Casimir sum over shifts in zero-point energies
~
2
∑(ω − ω0)
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EC = 〈 〉plates− 〈 〉no plates
1
πIm
∫[G(x, x, ω + iǫ) − G0(x, x, ω + iǫ)] =
d∆N
dω
change in the density of states due to the background
=⇒ A restatement of the Casimir sum over shifts in zero-point energies
~
2
∑(ω − ω0)
=⇒ Lippman-Schwinger eq. allows full Greens f, G, be expanded as aseries in free Green’s f, G0, and the coupling to the external field
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EC = 〈 〉plates− 〈 〉no plates
1
πIm
∫[G(x, x, ω + iǫ) − G0(x, x, ω + iǫ)] =
d∆N
dω
change in the density of states due to the background
=⇒ A restatement of the Casimir sum over shifts in zero-point energies
~
2
∑(ω − ω0)
=⇒ Lippman-Schwinger eq. allows full Greens f, G, be expanded as aseries in free Green’s f, G0, and the coupling to the external field
=⇒ “Experimental confirmation of the Casimir effect does not establish thereality of zero point fluctuations” [R. Jaffe et. al.]
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The Dynamical Casimir EffectS.A. Fulling & P.C.W. Davies, Proc Roy Soc A348 (1976)
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The Dynamical Casimir EffectS.A. Fulling & P.C.W. Davies, Proc Roy Soc A348 (1976)
Moving mirrors modify structure of quantum vacuum
Creation and annihilation of photons; once mirrors return to rest,some produced photons may still remain: flux of radiated particles
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The Dynamical Casimir EffectS.A. Fulling & P.C.W. Davies, Proc Roy Soc A348 (1976)
Moving mirrors modify structure of quantum vacuum
Creation and annihilation of photons; once mirrors return to rest,some produced photons may still remain: flux of radiated particles
For a single, perfectly reflecting mirror:# photons & energy diverge while mirror moves
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The Dynamical Casimir EffectS.A. Fulling & P.C.W. Davies, Proc Roy Soc A348 (1976)
Moving mirrors modify structure of quantum vacuum
Creation and annihilation of photons; once mirrors return to rest,some produced photons may still remain: flux of radiated particles
For a single, perfectly reflecting mirror:# photons & energy diverge while mirror moves
Several renormalization prescriptions have been usedin order to obtain a well-defined energy
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The Dynamical Casimir EffectS.A. Fulling & P.C.W. Davies, Proc Roy Soc A348 (1976)
Moving mirrors modify structure of quantum vacuum
Creation and annihilation of photons; once mirrors return to rest,some produced photons may still remain: flux of radiated particles
For a single, perfectly reflecting mirror:# photons & energy diverge while mirror moves
Several renormalization prescriptions have been usedin order to obtain a well-defined energy
Problem: for some trajectories this finite energy is not a positivequantity and cannot be identified with the energy of the photons
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The Dynamical Casimir EffectS.A. Fulling & P.C.W. Davies, Proc Roy Soc A348 (1976)
Moving mirrors modify structure of quantum vacuum
Creation and annihilation of photons; once mirrors return to rest,some produced photons may still remain: flux of radiated particles
For a single, perfectly reflecting mirror:# photons & energy diverge while mirror moves
Several renormalization prescriptions have been usedin order to obtain a well-defined energy
Problem: for some trajectories this finite energy is not a positivequantity and cannot be identified with the energy of the photons
Moore; Razavy, Terning; Johnston, Sarkar; Dodonov et al;Plunien et al; Barton, Eberlein, Calogeracos; Ford, Vilenkin;Jaeckel, Reynaud, Lambrecht; Brevik, Milton et al;Dalvit, Maia-Neto et al; Law; Parentani, ...
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A CONSISTENT APPROACH:J. Haro & E.E., PRL 97 (2006); arXiv:0705.0597
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A CONSISTENT APPROACH:J. Haro & E.E., PRL 97 (2006); arXiv:0705.0597
Partially transmitting mirrors, which become transparent tovery high frequencies (analytic matrix)
Proper use of a Hamiltonian method & corresponding renormalization
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A CONSISTENT APPROACH:J. Haro & E.E., PRL 97 (2006); arXiv:0705.0597
Partially transmitting mirrors, which become transparent tovery high frequencies (analytic matrix)
Proper use of a Hamiltonian method & corresponding renormalization
Proved both: # of created particles is finite & their energy is alwayspositive, for the whole trajectory during the mirrors’ displacement
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A CONSISTENT APPROACH:J. Haro & E.E., PRL 97 (2006); arXiv:0705.0597
Partially transmitting mirrors, which become transparent tovery high frequencies (analytic matrix)
Proper use of a Hamiltonian method & corresponding renormalization
Proved both: # of created particles is finite & their energy is alwayspositive, for the whole trajectory during the mirrors’ displacement
The radiation-reaction force acting on the mirrors owing to emission-absorption of particles is related with the field’s energy through theenergy conservation law: energy of the field at any t equals (withopposite sign) the work performed by the reaction force up to time t
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A CONSISTENT APPROACH:J. Haro & E.E., PRL 97 (2006); arXiv:0705.0597
Partially transmitting mirrors, which become transparent tovery high frequencies (analytic matrix)
Proper use of a Hamiltonian method & corresponding renormalization
Proved both: # of created particles is finite & their energy is alwayspositive, for the whole trajectory during the mirrors’ displacement
The radiation-reaction force acting on the mirrors owing to emission-absorption of particles is related with the field’s energy through theenergy conservation law: energy of the field at any t equals (withopposite sign) the work performed by the reaction force up to time t
Such force is split into two parts: a dissipative forcewhose work equals minus the energy of the particles that remain& a reactive force vanishing when the mirrors return to rest
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A CONSISTENT APPROACH:J. Haro & E.E., PRL 97 (2006); arXiv:0705.0597
Partially transmitting mirrors, which become transparent tovery high frequencies (analytic matrix)
Proper use of a Hamiltonian method & corresponding renormalization
Proved both: # of created particles is finite & their energy is alwayspositive, for the whole trajectory during the mirrors’ displacement
The radiation-reaction force acting on the mirrors owing to emission-absorption of particles is related with the field’s energy through theenergy conservation law: energy of the field at any t equals (withopposite sign) the work performed by the reaction force up to time t
Such force is split into two parts: a dissipative forcewhose work equals minus the energy of the particles that remain& a reactive force vanishing when the mirrors return to rest
The dissipative part we obtain agrees with the other methods.But those have problems with the reactive part, which in generalyields a non-positive energy =⇒ EXPERIMENT
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SOME DETAILS OF THE METHOD
Hamiltonian method for neutral Klein-Gordon field in a cavity Ωt, withboundaries moving at a certain speed v << c, ǫ = v/c
(of order 10−8 in Kim, Brownell, Onofrio, PRL 96 (2006) 200402)
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SOME DETAILS OF THE METHOD
Hamiltonian method for neutral Klein-Gordon field in a cavity Ωt, withboundaries moving at a certain speed v << c, ǫ = v/c
(of order 10−8 in Kim, Brownell, Onofrio, PRL 96 (2006) 200402)
Assume boundary at rest for time t ≤ 0 and returns to its initialposition at time T
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SOME DETAILS OF THE METHOD
Hamiltonian method for neutral Klein-Gordon field in a cavity Ωt, withboundaries moving at a certain speed v << c, ǫ = v/c
(of order 10−8 in Kim, Brownell, Onofrio, PRL 96 (2006) 200402)
Assume boundary at rest for time t ≤ 0 and returns to its initialposition at time T
Hamiltonian density conveniently obtained using the method inJohnston, Sarkar, JPA 29 (1996) 1741
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SOME DETAILS OF THE METHOD
Hamiltonian method for neutral Klein-Gordon field in a cavity Ωt, withboundaries moving at a certain speed v << c, ǫ = v/c
(of order 10−8 in Kim, Brownell, Onofrio, PRL 96 (2006) 200402)
Assume boundary at rest for time t ≤ 0 and returns to its initialposition at time T
Hamiltonian density conveniently obtained using the method inJohnston, Sarkar, JPA 29 (1996) 1741
Lagrangian density of the field
L(t,x) =1
2
[(∂tφ)2 − |∇xφ|2
], ∀x ∈ Ωt ⊂ R
n, ∀t ∈ R
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SOME DETAILS OF THE METHOD
Hamiltonian method for neutral Klein-Gordon field in a cavity Ωt, withboundaries moving at a certain speed v << c, ǫ = v/c
(of order 10−8 in Kim, Brownell, Onofrio, PRL 96 (2006) 200402)
Assume boundary at rest for time t ≤ 0 and returns to its initialposition at time T
Hamiltonian density conveniently obtained using the method inJohnston, Sarkar, JPA 29 (1996) 1741
Lagrangian density of the field
L(t,x) =1
2
[(∂tφ)2 − |∇xφ|2
], ∀x ∈ Ωt ⊂ R
n, ∀t ∈ R
Hamiltonian. Transform moving boundary into fixed one by(non-conformal) change of coordinates
R : (t,y) → (t(t,y),x(t,y)) = (t,R(t,y))
transform Ωt into a fixed domain Ω
Ω: (t(t,y),x(t,y)) = R(t,y) = (t,R(t,y))
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CASE OF A SINGLE, PARTIALLY TRANSMITTING MIRROR
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CASE OF A SINGLE, PARTIALLY TRANSMITTING MIRROR
Seminal Davis-Fulling model [PRSL A348 (1976) 393]renormalized energy negative while the mirror moves:cannot be considered as the energy of the produced particles at time t[cf. paragraph after Eq. (4.5)]
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CASE OF A SINGLE, PARTIALLY TRANSMITTING MIRROR
Seminal Davis-Fulling model [PRSL A348 (1976) 393]renormalized energy negative while the mirror moves:cannot be considered as the energy of the produced particles at time t[cf. paragraph after Eq. (4.5)]Our interpretation: a perfectly reflecting mirror is non-physical.Consider, instead, a partially transmitting mirror, transparent to highfrequencies (math. implementation of a physical plate).
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CASE OF A SINGLE, PARTIALLY TRANSMITTING MIRROR
Seminal Davis-Fulling model [PRSL A348 (1976) 393]renormalized energy negative while the mirror moves:cannot be considered as the energy of the produced particles at time t[cf. paragraph after Eq. (4.5)]Our interpretation: a perfectly reflecting mirror is non-physical.Consider, instead, a partially transmitting mirror, transparent to highfrequencies (math. implementation of a physical plate).Trajectory (t, ǫg(t)). When mirror at rest, scattering described by matrix
S(ω) =
s(ω) r(ω) e−2iωL
r(ω) e2iωL s(ω)
=⇒ S matrix is taken to be: (x = L position of the mirror)
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CASE OF A SINGLE, PARTIALLY TRANSMITTING MIRROR
Seminal Davis-Fulling model [PRSL A348 (1976) 393]renormalized energy negative while the mirror moves:cannot be considered as the energy of the produced particles at time t[cf. paragraph after Eq. (4.5)]Our interpretation: a perfectly reflecting mirror is non-physical.Consider, instead, a partially transmitting mirror, transparent to highfrequencies (math. implementation of a physical plate).Trajectory (t, ǫg(t)). When mirror at rest, scattering described by matrix
S(ω) =
s(ω) r(ω) e−2iωL
r(ω) e2iωL s(ω)
=⇒ S matrix is taken to be: (x = L position of the mirror)
→ Real in the temporal domain: S(−ω) = S∗(ω)
→ Causal: S(ω) is analytic for Im (ω) > 0
→ Unitary: S(ω)S†(ω) = Id→ The identity at high frequencies: S(ω) → Id, when |ω| → ∞
s(ω) and r(ω) meromorphic (cut-off) functions(material’s permitivity and resistivity)
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RESULTS ARE REWARDING:
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RESULTS ARE REWARDING:
In our Hamiltonian approach
〈FHa(t)〉 = − ǫ
2π2
∫ ∞
0
∫ ∞
0
dωdω′ωω′
ω + ω′Re
[e−i(ω+ω′)t gθt(ω + ω′)
]
×[|r(ω) + r∗(ω′)|2 + |s(ω) − s∗(ω′)|2] + O(ǫ2)
Note this integral diverges for a perfect mirror (r ≡ −1, s ≡ 0,ideal case), but nicely converges for our partially transmitting(physical) one where r(ω) → 0, s(ω) → 1, as ω → ∞
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RESULTS ARE REWARDING:
In our Hamiltonian approach
〈FHa(t)〉 = − ǫ
2π2
∫ ∞
0
∫ ∞
0
dωdω′ωω′
ω + ω′Re
[e−i(ω+ω′)t gθt(ω + ω′)
]
×[|r(ω) + r∗(ω′)|2 + |s(ω) − s∗(ω′)|2] + O(ǫ2)
Note this integral diverges for a perfect mirror (r ≡ −1, s ≡ 0,ideal case), but nicely converges for our partially transmitting(physical) one where r(ω) → 0, s(ω) → 1, as ω → ∞
Energy conservation is fulfilled: the dynamical energy at anytime t equals, with the opposite sign, the work performed bythe reaction force up to that time t
〈E(t)〉 = −ǫ
∫ t
0
〈FHa(τ)〉g(τ)dτ
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RESULTS ARE REWARDING:
In our Hamiltonian approach
〈FHa(t)〉 = − ǫ
2π2
∫ ∞
0
∫ ∞
0
dωdω′ωω′
ω + ω′Re
[e−i(ω+ω′)t gθt(ω + ω′)
]
×[|r(ω) + r∗(ω′)|2 + |s(ω) − s∗(ω′)|2] + O(ǫ2)
Note this integral diverges for a perfect mirror (r ≡ −1, s ≡ 0,ideal case), but nicely converges for our partially transmitting(physical) one where r(ω) → 0, s(ω) → 1, as ω → ∞
Energy conservation is fulfilled: the dynamical energy at anytime t equals, with the opposite sign, the work performed bythe reaction force up to that time t
〈E(t)〉 = −ǫ
∫ t
0
〈FHa(τ)〉g(τ)dτ
=⇒ Two mirrors; higher dimensions; fields of any kind
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Quantum Vacuum Fluct’s & the CCThe main issue: S.A. Fulling et. al., hep-th/070209v2
energy ALWAYS gravitates, therefore the energy density of thevacuum, more precisely, the vacuum expectation value of thestress-energy tensor 〈Tµν〉 ≡ −Egµν
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Quantum Vacuum Fluct’s & the CCThe main issue: S.A. Fulling et. al., hep-th/070209v2
energy ALWAYS gravitates, therefore the energy density of thevacuum, more precisely, the vacuum expectation value of thestress-energy tensor 〈Tµν〉 ≡ −Egµν
Appears on the rhs of Einstein’s equations:
Rµν − 1
2gµνR = −8πG(Tµν − Egµν)
It affects cosmology: Tµν excitations above the vacuum
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Quantum Vacuum Fluct’s & the CCThe main issue: S.A. Fulling et. al., hep-th/070209v2
energy ALWAYS gravitates, therefore the energy density of thevacuum, more precisely, the vacuum expectation value of thestress-energy tensor 〈Tµν〉 ≡ −Egµν
Appears on the rhs of Einstein’s equations:
Rµν − 1
2gµνR = −8πG(Tµν − Egµν)
It affects cosmology: Tµν excitations above the vacuum
Equivalent to a cosmological constant Λ = 8πGE
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Quantum Vacuum Fluct’s & the CCThe main issue: S.A. Fulling et. al., hep-th/070209v2
energy ALWAYS gravitates, therefore the energy density of thevacuum, more precisely, the vacuum expectation value of thestress-energy tensor 〈Tµν〉 ≡ −Egµν
Appears on the rhs of Einstein’s equations:
Rµν − 1
2gµνR = −8πG(Tµν − Egµν)
It affects cosmology: Tµν excitations above the vacuum
Equivalent to a cosmological constant Λ = 8πGE
Recent observations: M. Tegmark et al. [SDSS Collab.] PRD 2004
Λ = (2.14 ± 0.13 × 10−3 eV)4 ∼ 4.32 × 10−9 erg/cm3
4th Sakharov Conference, Moscow, May 21, 2009 – p. 19/32
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Quantum Vacuum Fluct’s & the CCThe main issue: S.A. Fulling et. al., hep-th/070209v2
energy ALWAYS gravitates, therefore the energy density of thevacuum, more precisely, the vacuum expectation value of thestress-energy tensor 〈Tµν〉 ≡ −Egµν
Appears on the rhs of Einstein’s equations:
Rµν − 1
2gµνR = −8πG(Tµν − Egµν)
It affects cosmology: Tµν excitations above the vacuum
Equivalent to a cosmological constant Λ = 8πGE
Recent observations: M. Tegmark et al. [SDSS Collab.] PRD 2004
Λ = (2.14 ± 0.13 × 10−3 eV)4 ∼ 4.32 × 10−9 erg/cm3
Idea: zero point fluctuations can contribute to thecosmological constant Ya.B. Zeldovich ’68
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CC PROBLEM
Relativistic field: collection of harmonic oscill’s (scalar field)
E0 =~ c
2
∑
n
ωn, ω = k2 +m2/~2, k = 2π/λ
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CC PROBLEM
Relativistic field: collection of harmonic oscill’s (scalar field)
E0 =~ c
2
∑
n
ωn, ω = k2 +m2/~2, k = 2π/λ
Evaluating in a box and putting a cut-off at maximum kmax corresp’ngto QFT physics (e.g., Planck energy)
ρ ∼ ~ k4Planck
16π2∼ 10123ρobs
kind of a modern (and thick!) aether R. Caldwell, S. Carroll, ...
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CC PROBLEM
Relativistic field: collection of harmonic oscill’s (scalar field)
E0 =~ c
2
∑
n
ωn, ω = k2 +m2/~2, k = 2π/λ
Evaluating in a box and putting a cut-off at maximum kmax corresp’ngto QFT physics (e.g., Planck energy)
ρ ∼ ~ k4Planck
16π2∼ 10123ρobs
kind of a modern (and thick!) aether R. Caldwell, S. Carroll, ...
Observational tests see nothing (or very little) of it:=⇒ (new) cosmological constant problem
4th Sakharov Conference, Moscow, May 21, 2009 – p. 20/32
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CC PROBLEM
Relativistic field: collection of harmonic oscill’s (scalar field)
E0 =~ c
2
∑
n
ωn, ω = k2 +m2/~2, k = 2π/λ
Evaluating in a box and putting a cut-off at maximum kmax corresp’ngto QFT physics (e.g., Planck energy)
ρ ∼ ~ k4Planck
16π2∼ 10123ρobs
kind of a modern (and thick!) aether R. Caldwell, S. Carroll, ...
Observational tests see nothing (or very little) of it:=⇒ (new) cosmological constant problem
Very difficult to solve and we do not address this question directly[Baum, Hawking, Coleman, Polchinsky, Weinberg,...]
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CC PROBLEM
Relativistic field: collection of harmonic oscill’s (scalar field)
E0 =~ c
2
∑
n
ωn, ω = k2 +m2/~2, k = 2π/λ
Evaluating in a box and putting a cut-off at maximum kmax corresp’ngto QFT physics (e.g., Planck energy)
ρ ∼ ~ k4Planck
16π2∼ 10123ρobs
kind of a modern (and thick!) aether R. Caldwell, S. Carroll, ...
Observational tests see nothing (or very little) of it:=⇒ (new) cosmological constant problem
Very difficult to solve and we do not address this question directly[Baum, Hawking, Coleman, Polchinsky, Weinberg,...]
What we do consider —with relative success in some differentapproaches— is the additional contribution to the cc coming from thenon-trivial topology of space or from specific boundary conditionsimposed on braneworld models:
=⇒ kind of cosmological Casimir effect
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Cosmolog Imprint of the Casimir Eff’t?Assuming one will be able to prove (in the future) that the groundvalue of the cc is zero (as many had suspected until recently), we willbe left with this incremental value coming from the topology or BCs
* L. Parker & A. Raval, VCDM, vacuum energy density* C.P. Burgess et al., hep-th/0606020 & 0510123: Susy Large ExtraDims (SLED), two 10−2mm dims, bulk vs brane Susy breaking scales* T. Padmanabhan, gr-qc/0606061: Holographic Perspective, CC is anintg const, no response of gravity to changes in bulk vac energy dens
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Cosmolog Imprint of the Casimir Eff’t?Assuming one will be able to prove (in the future) that the groundvalue of the cc is zero (as many had suspected until recently), we willbe left with this incremental value coming from the topology or BCs
* L. Parker & A. Raval, VCDM, vacuum energy density* C.P. Burgess et al., hep-th/0606020 & 0510123: Susy Large ExtraDims (SLED), two 10−2mm dims, bulk vs brane Susy breaking scales* T. Padmanabhan, gr-qc/0606061: Holographic Perspective, CC is anintg const, no response of gravity to changes in bulk vac energy dens
We show (with different examples) that this value acquiresthe correct order of magnitude —corresponding to the onecoming from the observed acceleration in the expansion ofour universe— in some reasonable models involving:
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Cosmolog Imprint of the Casimir Eff’t?Assuming one will be able to prove (in the future) that the groundvalue of the cc is zero (as many had suspected until recently), we willbe left with this incremental value coming from the topology or BCs
* L. Parker & A. Raval, VCDM, vacuum energy density* C.P. Burgess et al., hep-th/0606020 & 0510123: Susy Large ExtraDims (SLED), two 10−2mm dims, bulk vs brane Susy breaking scales* T. Padmanabhan, gr-qc/0606061: Holographic Perspective, CC is anintg const, no response of gravity to changes in bulk vac energy dens
We show (with different examples) that this value acquiresthe correct order of magnitude —corresponding to the onecoming from the observed acceleration in the expansion ofour universe— in some reasonable models involving:
(a) small and large compactified scales
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Cosmolog Imprint of the Casimir Eff’t?Assuming one will be able to prove (in the future) that the groundvalue of the cc is zero (as many had suspected until recently), we willbe left with this incremental value coming from the topology or BCs
* L. Parker & A. Raval, VCDM, vacuum energy density* C.P. Burgess et al., hep-th/0606020 & 0510123: Susy Large ExtraDims (SLED), two 10−2mm dims, bulk vs brane Susy breaking scales* T. Padmanabhan, gr-qc/0606061: Holographic Perspective, CC is anintg const, no response of gravity to changes in bulk vac energy dens
We show (with different examples) that this value acquiresthe correct order of magnitude —corresponding to the onecoming from the observed acceleration in the expansion ofour universe— in some reasonable models involving:
(a) small and large compactified scales
(b) dS & AdS worldbranes
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Cosmolog Imprint of the Casimir Eff’t?Assuming one will be able to prove (in the future) that the groundvalue of the cc is zero (as many had suspected until recently), we willbe left with this incremental value coming from the topology or BCs
* L. Parker & A. Raval, VCDM, vacuum energy density* C.P. Burgess et al., hep-th/0606020 & 0510123: Susy Large ExtraDims (SLED), two 10−2mm dims, bulk vs brane Susy breaking scales* T. Padmanabhan, gr-qc/0606061: Holographic Perspective, CC is anintg const, no response of gravity to changes in bulk vac energy dens
We show (with different examples) that this value acquiresthe correct order of magnitude —corresponding to the onecoming from the observed acceleration in the expansion ofour universe— in some reasonable models involving:
(a) small and large compactified scales
(b) dS & AdS worldbranes
(c) supergraviton theories (discret dims, deconstr)
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The Braneworld Case1. Braneworld may help to solve:
the hierarchy problem
the cosmological constant problem
2. Presumably, the bulk Casimir effect will play a role in the construction (radion
stabilization) of braneworlds
Bulk Casimir effect (effective potential) for a conformal or massive scalar field
Bulk is a 5-dim AdS or dS space with 2/1 4-dim dS brane (our universe)
Consistent with observational data even for relatively large extra dimension
Previous work: −→ flat space brane−→ bulk conformal scalar field
−→ conclusion: no CE
We used zeta regularization at full power, with positive results!
EE, S Nojiri, SD Odintsov, S Ogushi, Phys Rev D67 (2003) 063515 Casimir effect in
de Sitter and Anti-de Sitter braneworlds EE, SD Odintsov, AA Saharian 0902.0717
Repulsive Casimir effect from extra dimensions and Robin BC: from branes to pistons
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Casimir eff in brworl’s w large extra dimCasimir energy for massive scalar field with an arbitrary curvature coupling,
obeying Robin BCs on two codim-1 parallel plates embedded in backgroundspacetime R(D1−1,1) × Σ, Σ compact internal space
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Casimir eff in brworl’s w large extra dimCasimir energy for massive scalar field with an arbitrary curvature coupling,
obeying Robin BCs on two codim-1 parallel plates embedded in backgroundspacetime R(D1−1,1) × Σ, Σ compact internal space
Most general case: constants in the BCs different for the two plates
It is shown that Robin BCs with different coefficients are necessaryto obtain repulsive Casimir forces
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Casimir eff in brworl’s w large extra dimCasimir energy for massive scalar field with an arbitrary curvature coupling,
obeying Robin BCs on two codim-1 parallel plates embedded in backgroundspacetime R(D1−1,1) × Σ, Σ compact internal space
Most general case: constants in the BCs different for the two plates
It is shown that Robin BCs with different coefficients are necessaryto obtain repulsive Casimir forces
Robin type BCs are an extension of Dirichlet and Neumann’s
−→ most suitable to describe physically realistic situations
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Casimir eff in brworl’s w large extra dimCasimir energy for massive scalar field with an arbitrary curvature coupling,
obeying Robin BCs on two codim-1 parallel plates embedded in backgroundspacetime R(D1−1,1) × Σ, Σ compact internal space
Most general case: constants in the BCs different for the two plates
It is shown that Robin BCs with different coefficients are necessaryto obtain repulsive Casimir forces
Robin type BCs are an extension of Dirichlet and Neumann’s
−→ most suitable to describe physically realistic situations
Genuinely appear in: vacuum effects for a confined charged scalar field in
external fields [Ambjørn ea 83], spinor and gauge field theories, quantumgravity and supergravity [Luckock ea 91] Can be made conformally invariant,
while purely-Neumann conditions cannot
−→ needed for conformally invariant theories with boundaries, to preservethis invariance
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Casimir eff in brworl’s w large extra dimCasimir energy for massive scalar field with an arbitrary curvature coupling,
obeying Robin BCs on two codim-1 parallel plates embedded in backgroundspacetime R(D1−1,1) × Σ, Σ compact internal space
Most general case: constants in the BCs different for the two plates
It is shown that Robin BCs with different coefficients are necessaryto obtain repulsive Casimir forces
Robin type BCs are an extension of Dirichlet and Neumann’s
−→ most suitable to describe physically realistic situations
Genuinely appear in: vacuum effects for a confined charged scalar field in
external fields [Ambjørn ea 83], spinor and gauge field theories, quantumgravity and supergravity [Luckock ea 91] Can be made conformally invariant,
while purely-Neumann conditions cannot
−→ needed for conformally invariant theories with boundaries, to preservethis invariance
Quantum scalar field with Robin BCs on boundary of cavity violates
Bekenstein’s entropy-to-energy bound near certain points in the space of theparameter defining the boundary condition [Solodukhin 01]
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Robin BCs can model the finite penetration of the field through the boundary:
the ‘skin-depth’ param related to Robin coefficient [Mostep ea 85,Lebedev 01]Casimir forces between the boundary planes of films [Schmidt ea 08]
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Robin BCs can model the finite penetration of the field through the boundary:
the ‘skin-depth’ param related to Robin coefficient [Mostep ea 85,Lebedev 01]Casimir forces between the boundary planes of films [Schmidt ea 08]
Naturally arise for scalar and fermion bulk fields in the Randall-Sundrum model
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Robin BCs can model the finite penetration of the field through the boundary:
the ‘skin-depth’ param related to Robin coefficient [Mostep ea 85,Lebedev 01]Casimir forces between the boundary planes of films [Schmidt ea 08]
Naturally arise for scalar and fermion bulk fields in the Randall-Sundrum model
For arbitrary internal space, interaction part of the Casimir energy given by
∆E[a1,a2] =(4π)−D1/2
Γ(D1/2)
∑
β
∫ ∞
mβ
dxx(x2 −m2β) D1/2−1
× ln
[1 − (β1x+ 1)(β2x+ 1)
(β1x− 1)(β2x− 1)e−2ax
](∗)
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Robin BCs can model the finite penetration of the field through the boundary:
the ‘skin-depth’ param related to Robin coefficient [Mostep ea 85,Lebedev 01]Casimir forces between the boundary planes of films [Schmidt ea 08]
Naturally arise for scalar and fermion bulk fields in the Randall-Sundrum model
For arbitrary internal space, interaction part of the Casimir energy given by
∆E[a1,a2] =(4π)−D1/2
Γ(D1/2)
∑
β
∫ ∞
mβ
dxx(x2 −m2β) D1/2−1
× ln
[1 − (β1x+ 1)(β2x+ 1)
(β1x− 1)(β2x− 1)e−2ax
](∗)
For Dirichlet and Neumann BCs on both plates this leads to
∆E(J,J)[a1,a2]
= − 2a−D1
(8π)(D1+1)/2
∑
β
∞∑
n=1
f(D1+1)/2(2namβ)
nD1+1
with fν(z) = zνKν(z) −→ energy always negative
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For Dirichlet BC on one plate and Neumann on the other, the interaction
component of the vacuum energy is
∆E(D,N)[a1,a2] =
(4π)−D1/2a
Γ(D1/2 + 1)
∑
β
∫∞
mβ
dx(x2 − m2
β) D1/2
e2ax + 1
= − 2a−D1
(8π)(D1+1)/2
∑
β
∞∑
n=1
f(D1+1)/2(2namβ)
(−1)nnD1+1
positive for all values of the inter-plate distance
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For Dirichlet BC on one plate and Neumann on the other, the interaction
component of the vacuum energy is
∆E(D,N)[a1,a2] =
(4π)−D1/2a
Γ(D1/2 + 1)
∑
β
∫∞
mβ
dx(x2 − m2
β) D1/2
e2ax + 1
= − 2a−D1
(8π)(D1+1)/2
∑
β
∞∑
n=1
f(D1+1)/2(2namβ)
(−1)nnD1+1
positive for all values of the inter-plate distance
In the case of a conformally coupled massless field on the background of a
spacetime conformally related to the one described by the line element
ds2 = gMNdxMdxN = ηµνdxµdxν − γildXidXl
ηµν = diag(1,−1, . . . ,−1) metric of (D1 + 1)-dim Minkowski st and Xi
coordinates of Σ, with the conformal factor Ω2(xD1). Interaction part of Casimir
energy is given (*), with coeffs βj related to coeffs of the Robin BCs
(1 + βjnM∇M )ϕ(x) = [1 + (−1)j−1Ω−1
j βj∂D1]ϕ(x) = 0, Ωj = Ω(xD1
j )
& conformal factor βj =[Ωj + (−1)j D−1
2ΩjβjΩ
′
j
]−1
βj , Ω′
j = Ω′
j(xD1
j )
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In Randall-Sundrum 2-brane model with compact internal space, the Robin
coefficients are β−1
j = (−1)jcj/2 − 2Dζ/rD, c1, c2 mass parameters in thesurface action of the scalar field for the left and right branes, respectively
The vacuum energy can have a minimum, for the stable equilibrium pointCan be used in braneworld models for the stabilization of the radion field
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In Randall-Sundrum 2-brane model with compact internal space, the Robin
coefficients are β−1
j = (−1)jcj/2 − 2Dζ/rD, c1, c2 mass parameters in thesurface action of the scalar field for the left and right branes, respectively
The vacuum energy can have a minimum, for the stable equilibrium pointCan be used in braneworld models for the stabilization of the radion field
We have considered a piston-like geometry, introducing a third plate (then thisplate is sent to infinity) Casimir force
P = − 2(4π)−D1/2
VΣΓ(D1/2)aD1+1
∑
β
∫∞
amβ
dxx2(x2 − a2m2
β) D1/2−1
(b1x−1)(b2x−1)(b1x+1)(b2x+1)
e2x − 1
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In Randall-Sundrum 2-brane model with compact internal space, the Robin
coefficients are β−1
j = (−1)jcj/2 − 2Dζ/rD, c1, c2 mass parameters in thesurface action of the scalar field for the left and right branes, respectively
The vacuum energy can have a minimum, for the stable equilibrium pointCan be used in braneworld models for the stabilization of the radion field
We have considered a piston-like geometry, introducing a third plate (then thisplate is sent to infinity) Casimir force
P = − 2(4π)−D1/2
VΣΓ(D1/2)aD1+1
∑
β
∫∞
amβ
dxx2(x2 − a2m2
β) D1/2−1
(b1x−1)(b2x−1)(b1x+1)(b2x+1)
e2x − 1
With independence of the geometry of the internal space, the force is attractive forDirichlet or Neumann boundary conditions on both plates
P (J,J) = −2(4π)−D1/2
VΣΓ(D1/2)
∑
β
∫∞
mβ
dxx2 (x2 − m2β) D1/2−1
e2ax − 1
=2a−D1−1
(8π)(D1+1)/2VΣ
∑
β
∞∑
n=1
1
nD1+1
[f(D1+1)/2(2namβ) − f(D1+3)/2(2namβ)
]
J = D,N, and repulsive for Dirichlet BC on one plate and Neumann on the other,a monotonic function of the distance
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For general Robin BCs the Casimir force can be either attractive (negative P ) or
repulsive (positive P ), depending on the Robin coefficients and distance betweenplates
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For general Robin BCs the Casimir force can be either attractive (negative P ) or
repulsive (positive P ), depending on the Robin coefficients and distance betweenplates
For small values of the size of internal space, in models with zero modes along theinternal space, main contribution to Casimir force comes from the zero modes:
contributions of non-zero modes are exponentially suppressed
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For general Robin BCs the Casimir force can be either attractive (negative P ) or
repulsive (positive P ), depending on the Robin coefficients and distance betweenplates
For small values of the size of internal space, in models with zero modes along theinternal space, main contribution to Casimir force comes from the zero modes:
contributions of non-zero modes are exponentially suppressed
In this limit, to leading order we recover the standard result for the Casimir force
between two plates in (D1 + 1) Minkowski spacetime
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For general Robin BCs the Casimir force can be either attractive (negative P ) or
repulsive (positive P ), depending on the Robin coefficients and distance betweenplates
For small values of the size of internal space, in models with zero modes along theinternal space, main contribution to Casimir force comes from the zero modes:
contributions of non-zero modes are exponentially suppressed
In this limit, to leading order we recover the standard result for the Casimir force
between two plates in (D1 + 1) Minkowski spacetime
In absence of zero modes (case of twisted boundary conditions along
compactified dimensions), Casimir forces are exponentially suppressed in the limitof small size of the internal space. For small values of the inter-plate distance the
Casimir forces are attractive, independently of the values of the Robin coefficients,except for the case of Dirichlet boundary conditions on one plate and non-Dirichlet
boundary conditions on the otherIn this latter case, the Casimir force is repulsive at small distances
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For general Robin BCs the Casimir force can be either attractive (negative P ) or
repulsive (positive P ), depending on the Robin coefficients and distance betweenplates
For small values of the size of internal space, in models with zero modes along theinternal space, main contribution to Casimir force comes from the zero modes:
contributions of non-zero modes are exponentially suppressed
In this limit, to leading order we recover the standard result for the Casimir force
between two plates in (D1 + 1) Minkowski spacetime
In absence of zero modes (case of twisted boundary conditions along
compactified dimensions), Casimir forces are exponentially suppressed in the limitof small size of the internal space. For small values of the inter-plate distance the
Casimir forces are attractive, independently of the values of the Robin coefficients,except for the case of Dirichlet boundary conditions on one plate and non-Dirichlet
boundary conditions on the otherIn this latter case, the Casimir force is repulsive at small distances
Interesting remark: this property could be used in the proposal of a Casimirexperiment with the purpose to carry out an explicit detailed observation of
‘large’ extra dimensions as allowed by some models of particle physics
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Gravity Eqs as Eqs of State: f(R) CaseThe cosmological constant as an “integration constant”
T. Padmanabhan; D. Blas, J. Garriga, E. Alvarez ...
Unimodular Gravity
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Gravity Eqs as Eqs of State: f(R) CaseThe cosmological constant as an “integration constant”
T. Padmanabhan; D. Blas, J. Garriga, E. Alvarez ...
Unimodular Gravity
Ted Jacobson [PRL1995] obtained Einstein’s equations from
local thermodynamics arguments only
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Gravity Eqs as Eqs of State: f(R) CaseThe cosmological constant as an “integration constant”
T. Padmanabhan; D. Blas, J. Garriga, E. Alvarez ...
Unimodular Gravity
Ted Jacobson [PRL1995] obtained Einstein’s equations from
local thermodynamics arguments only
By way of generalizing black hole thermodynamics to
space-time thermodynamics as seen by a local observer
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Gravity Eqs as Eqs of State: f(R) CaseThe cosmological constant as an “integration constant”
T. Padmanabhan; D. Blas, J. Garriga, E. Alvarez ...
Unimodular Gravity
Ted Jacobson [PRL1995] obtained Einstein’s equations from
local thermodynamics arguments only
By way of generalizing black hole thermodynamics to
space-time thermodynamics as seen by a local observer
This strongly suggests, in a fundamental context:
Einstein’s Eqs are to be viewed as EoS
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Gravity Eqs as Eqs of State: f(R) CaseThe cosmological constant as an “integration constant”
T. Padmanabhan; D. Blas, J. Garriga, E. Alvarez ...
Unimodular Gravity
Ted Jacobson [PRL1995] obtained Einstein’s equations from
local thermodynamics arguments only
By way of generalizing black hole thermodynamics to
space-time thermodynamics as seen by a local observer
This strongly suggests, in a fundamental context:
Einstein’s Eqs are to be viewed as EoS
Should, probably, not be taken as basic for quantizing gravity
4th Sakharov Conference, Moscow, May 21, 2009 – p. 28/32
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Gravity Eqs as Eqs of State: f(R) CaseThe cosmological constant as an “integration constant”
T. Padmanabhan; D. Blas, J. Garriga, E. Alvarez ...
Unimodular Gravity
Ted Jacobson [PRL1995] obtained Einstein’s equations from
local thermodynamics arguments only
By way of generalizing black hole thermodynamics to
space-time thermodynamics as seen by a local observer
This strongly suggests, in a fundamental context:
Einstein’s Eqs are to be viewed as EoS
Should, probably, not be taken as basic for quantizing gravity
C. Eling, R. Guedens, T. Jacobson [PRL2006]: extension to
polynomial f(R) gravity but as non-equilibrium thermodyn.
Also Erik Verlinde (private discussions)4th Sakharov Conference, Moscow, May 21, 2009 – p. 28/32
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Jacobson’s argument: basic thermodynamic relation
δQ = TδS
– entropy proport to variation of the horizon area: δS = η δA– local temperature T defined as Unruh temp: T = ~k/2π
– functional dependence of S wrt energy and size of system
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Jacobson’s argument: basic thermodynamic relation
δQ = TδS
– entropy proport to variation of the horizon area: δS = η δA– local temperature T defined as Unruh temp: T = ~k/2π
– functional dependence of S wrt energy and size of system
Key point in our generalization: the definition of the local
entropy (Iyer+Wald 93: local boost inv, Noether charge)
S = −2π
∫
ΣEpqrs
R ǫpqǫrs, δS = δ (ηeA)
ηe is a function of the metric and its deriv’s to a given order
ηe = ηe
(gab, Rcdef ,∇(l)Rpqrs
)
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Jacobson’s argument: basic thermodynamic relation
δQ = TδS
– entropy proport to variation of the horizon area: δS = η δA– local temperature T defined as Unruh temp: T = ~k/2π
– functional dependence of S wrt energy and size of system
Key point in our generalization: the definition of the local
entropy (Iyer+Wald 93: local boost inv, Noether charge)
S = −2π
∫
ΣEpqrs
R ǫpqǫrs, δS = δ (ηeA)
ηe is a function of the metric and its deriv’s to a given order
ηe = ηe
(gab, Rcdef ,∇(l)Rpqrs
)
Case of f(R) gravities: L = f(R,∇nR)
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Also the concept of an effective Newton constant for graviton
exchange (effective propagator)
1
8πGeff= Epqrs
R ǫpqǫrs =∂f
∂R(gprgqs − gqrgps)ǫpqǫrs
=∂f
∂R=ηe
2π, S =
A
4Geff
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Also the concept of an effective Newton constant for graviton
exchange (effective propagator)
1
8πGeff= Epqrs
R ǫpqǫrs =∂f
∂R(gprgqs − gqrgps)ǫpqǫrs
=∂f
∂R=ηe
2π, S =
A
4Geff
For these theories, the different polarizations of the gravitons
only enter in the definition of the effective Newton constant
through the metric itself
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Also the concept of an effective Newton constant for graviton
exchange (effective propagator)
1
8πGeff= Epqrs
R ǫpqǫrs =∂f
∂R(gprgqs − gqrgps)ǫpqǫrs
=∂f
∂R=ηe
2π, S =
A
4Geff
For these theories, the different polarizations of the gravitons
only enter in the definition of the effective Newton constant
through the metric itself
Final result, for f(R) gravities:
the local field equations can be thought of as an equation of
state of equilibrium thermodynamics (as in the GR case)
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Jacobson’s argum non-trivially extended to f(R) gravity field eqsas EoS of local space-time thermodynamicsEE, P. Silva, Phys Rev D78, 061501(R) (2008), arXiv:0804.3721v2
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Jacobson’s argum non-trivially extended to f(R) gravity field eqsas EoS of local space-time thermodynamicsEE, P. Silva, Phys Rev D78, 061501(R) (2008), arXiv:0804.3721v2
By means of a more general definition of local entropy, using Wald’sdefinition of dynamic BH entropyRM Wald PRD1993; V Iyer, RM Wald PRD1994
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Jacobson’s argum non-trivially extended to f(R) gravity field eqsas EoS of local space-time thermodynamicsEE, P. Silva, Phys Rev D78, 061501(R) (2008), arXiv:0804.3721v2
By means of a more general definition of local entropy, using Wald’sdefinition of dynamic BH entropyRM Wald PRD1993; V Iyer, RM Wald PRD1994
And also the concept of an effective Newton constant for gravitonexchange (effective propagator)R. Brustein, D. Gorbonos, M. Hadad, arXiv:0712.3206
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Jacobson’s argum non-trivially extended to f(R) gravity field eqsas EoS of local space-time thermodynamicsEE, P. Silva, Phys Rev D78, 061501(R) (2008), arXiv:0804.3721v2
By means of a more general definition of local entropy, using Wald’sdefinition of dynamic BH entropyRM Wald PRD1993; V Iyer, RM Wald PRD1994
And also the concept of an effective Newton constant for gravitonexchange (effective propagator)R. Brustein, D. Gorbonos, M. Hadad, arXiv:0712.3206
S-F Wu, G-H Yang, P-M Zhang, arXiv:0805.4044, direct extensionof our results to Brans-Dicke and scalar-tensor gravitiesT Zhu, Ji-R Ren and S-F Mo, arXiv:0805.1162 [gr-qc];C Eling, arXiv:0806.3165 [hep-th]; R-G Cai, L-M Cao and Y-P Hu,arXiv:0807.1232 [hep-th] & arXiv:0809.1554 [hep-th]
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Perspectives:Shear viscosity to entropy density ratio: η/s ≥ 1/4π
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Perspectives:Shear viscosity to entropy density ratio: η/s ≥ 1/4π
AdS/CFT corresp −→ N=4 SUSY Y-M [DT Son, AO Starinets, ...]QCD non-conf, but at very hight T approx conf (deconfining phase)
4th Sakharov Conference, Moscow, May 21, 2009 – p. 32/32
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Perspectives:Shear viscosity to entropy density ratio: η/s ≥ 1/4π
AdS/CFT corresp −→ N=4 SUSY Y-M [DT Son, AO Starinets, ...]QCD non-conf, but at very hight T approx conf (deconfining phase)
Bound saturated for N=4 SUSY Y-M at large ’t Hooft coupl &large N lim, and first corrections are positive!
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Perspectives:Shear viscosity to entropy density ratio: η/s ≥ 1/4π
AdS/CFT corresp −→ N=4 SUSY Y-M [DT Son, AO Starinets, ...]QCD non-conf, but at very hight T approx conf (deconfining phase)
Bound saturated for N=4 SUSY Y-M at large ’t Hooft coupl &large N lim, and first corrections are positive!
Hydrodyn corresp. Heavy ion experiments: corresp Navier-Stokescoeffs determined from measurement. And for BH physics.
4th Sakharov Conference, Moscow, May 21, 2009 – p. 32/32
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Perspectives:Shear viscosity to entropy density ratio: η/s ≥ 1/4π
AdS/CFT corresp −→ N=4 SUSY Y-M [DT Son, AO Starinets, ...]QCD non-conf, but at very hight T approx conf (deconfining phase)
Bound saturated for N=4 SUSY Y-M at large ’t Hooft coupl &large N lim, and first corrections are positive!
Hydrodyn corresp. Heavy ion experiments: corresp Navier-Stokescoeffs determined from measurement. And for BH physics.
Lower bound ∼ E-t uncert relat (Heis), using quasi-particle picture
4th Sakharov Conference, Moscow, May 21, 2009 – p. 32/32
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Perspectives:Shear viscosity to entropy density ratio: η/s ≥ 1/4π
AdS/CFT corresp −→ N=4 SUSY Y-M [DT Son, AO Starinets, ...]QCD non-conf, but at very hight T approx conf (deconfining phase)
Bound saturated for N=4 SUSY Y-M at large ’t Hooft coupl &large N lim, and first corrections are positive!
Hydrodyn corresp. Heavy ion experiments: corresp Navier-Stokescoeffs determined from measurement. And for BH physics.
Lower bound ∼ E-t uncert relat (Heis), using quasi-particle picture
Counterexamp to bound: (in gener grav case? R Brustein, C Eling)(i) # particles very large; (ii) # excit of a particle v.l.
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Perspectives:Shear viscosity to entropy density ratio: η/s ≥ 1/4π
AdS/CFT corresp −→ N=4 SUSY Y-M [DT Son, AO Starinets, ...]QCD non-conf, but at very hight T approx conf (deconfining phase)
Bound saturated for N=4 SUSY Y-M at large ’t Hooft coupl &large N lim, and first corrections are positive!
Hydrodyn corresp. Heavy ion experiments: corresp Navier-Stokescoeffs determined from measurement. And for BH physics.
Lower bound ∼ E-t uncert relat (Heis), using quasi-particle picture
Counterexamp to bound: (in gener grav case? R Brustein, C Eling)(i) # particles very large; (ii) # excit of a particle v.l.
Good candidates to violate bound: strong continuum spectrum[A Jakovac, D Nogradi 0810.4181] lattice calc 0.056 vs 0.0796
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Perspectives:Shear viscosity to entropy density ratio: η/s ≥ 1/4π
AdS/CFT corresp −→ N=4 SUSY Y-M [DT Son, AO Starinets, ...]QCD non-conf, but at very hight T approx conf (deconfining phase)
Bound saturated for N=4 SUSY Y-M at large ’t Hooft coupl &large N lim, and first corrections are positive!
Hydrodyn corresp. Heavy ion experiments: corresp Navier-Stokescoeffs determined from measurement. And for BH physics.
Lower bound ∼ E-t uncert relat (Heis), using quasi-particle picture
Counterexamp to bound: (in gener grav case? R Brustein, C Eling)(i) # particles very large; (ii) # excit of a particle v.l.
Good candidates to violate bound: strong continuum spectrum[A Jakovac, D Nogradi 0810.4181] lattice calc 0.056 vs 0.0796
Thanks for your attention4th Sakharov Conference, Moscow, May 21, 2009 – p. 32/32