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Published for SISSA by Springer

Received: February 23, 2016

Accepted: April 18, 2016

Published: April 26, 2016

Quantum gravity and the holographic dark energy

cosmology

Horatiu Nastase

Instituto de F́ısica Teórica, UNESP-Universidade Estadual Paulista,

R. Dr. Bento T. Ferraz 271, Bl. II, Sao Paulo 01140-070, SP, Brazil

E-mail: nastase@ift.unesp.br

Abstract: The holographic dark energy model is obtained from a cosmological constant

generated by generic quantum gravity effects giving a minimum length. By contrast, the

usual bound for the energy density to be limited by the formation of a black hole simply

gives the Friedmann equation. The scale of the current cosmological constant relative

to the inflationary scale is an arbitrary parameter characterizing initial conditions, which

however can be fixed by introducing a physical principle during inflation, as a function of

the number of e-folds and the inflationary scale.

Keywords: Cosmology of Theories beyond the SM, Models of Quantum Gravity, Non-

perturbative Effects

ArXiv ePrint: 1602.03708

Open Access, c© The Authors.

Article funded by SCOAP3.
doi:10.1007/JHEP04(2016)149

mailto:nastase@ift.unesp.br
http://arxiv.org/abs/1602.03708
http://dx.doi.org/10.1007/JHEP04(2016)149


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Contents

1 Introduction 1

2 Cosmological constant 2

3 Holographic dark energy cosmology 4

4 Conclusions 9

1 Introduction

The cosmological constant problem is one of the most important problems in theoretical

physics (see, e.g. [1] for a review). On the one hand, we know that in quantum field theory

there should be a vacuum energy coming from bubble Feynman diagrams, or equivalently

by summing over zero-point energies of the mode oscillators,
∑

n ~ωn/2. The value of the

resulting cosmological constant energy density ρΛ should be of the order of M4, where M

is the maximum cut-off of the theory. In a generic theory including quantum gravity, this

would be at the Planck scale, M4
Pl. Since a fermionic degree of freedom gives minus the

above result for a bosonic one, supersymmetry (in the absence of gravity) would imply a

zero cosmological constant, but a theory with broken supersymmetry like the real world

would give ρΛ ∼ M4
SSB, where MSSB is the scale of supersymmetry breaking, and more-

over in supergravity even a supersymmetric vacuum would have a (negative) cosmological

constant. On the other hand, cosmologically it was experimentally found that we have a

“dark energy” component in the make-up of the Universe (see the reviews [2–4]), which is

described to a large degree of accuracy by a cosmological constant composing more than

2/3 of the total energy. According to the recent Planck data, we have a flat Universe

(Ωtotal ' 1), with ΩΛ = 0.6911± 0.0062 and an equation of state wΛ = −1.006± 0.045 (as-

suming w is constant) [5]. This possible cosmological constant however would be about 122

orders of magnitude smaller than its natural Planck scale value, ρΛ ∼ 10−122M4
Pl, which

means either an incredible fine-tuning, which most physicists would dismiss, or the effect

of some unknown mechanism. Note that since the Friedmann equation can be written in

the form

ρtotal = 3M2
PlH

2 , (1.1)

where MPl is the reduced Planck mass MPl = (8πG)−1/2, the cosmological constant energy

density is of the order ρΛ ∼M2
Pl/(H

−1)2.

A possible way out of this problem was suggested by the observation in [6] that impos-

ing that the total energy of vacuum fluctuations in a size L is smaller than the one required

to create black hole of radius L severely restricts the energy on cosmological scales, giv-

ing ρΛL
3 . LM2

Pl. We will come back to discuss in more detail this bound later. Then,

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in [7] an attempt was made to derive a consistent cosmology assuming that L is given by

the horizon size H−1, which however contradicts experiment. A consistent cosmology was

developed in [8], assuming that the correct scale L to be considered is the future event hori-

zon Rh = a
∫∞
t dt/a (after discarding as a possibility the particle horizon RH = a

∫ t
0 dt/a),

which was named “holographic dark energy” cosmology (for recent developments in holo-

graphic dark energy cosmology, see [9–11]. The model was later refined to introduce an

interaction with dark matter in [12, 13]. In this letter I will argue that the “holographic

dark energy” type of cosmological constant can naturally arise from a generic quantum

gravity theory, assuming only the existence of a minimum length. I will then also expand

on the model in [8], presenting more details about the time evolution in the context of an

inflationary cosmology, and show that the addition of a simple physical principle can fix

the ratio of the cosmological constant today to the one during inflation in terms of the

number of e-folds of inflation.

2 Cosmological constant

In a theory without gravity, the vacuum energy
∑

n ~ωn/2 presents an observable effect

only in its modification due to the variation of the geometry of space, like in the well-known

Casimir effect (see, e.g. [14, 15] for a review). Boundary conditions on an electromagnetic

field, given by the presence of a conductor of a given geometry (e.g., infinite parallel

plates, or sphere, etc.), can be varied, and the difference in the vacuum energy for different

boundary conditions is an experimentally measurable effect. So if effect, what we measure

is
∑

n(~ωn − ~ωn,0)/2, with ~ωn/2 the vacuum energy in the presence of the boundary

conditions and ~ωn,0/2 the vacuum energy for free space. This is in fact part of a more

general technique to determine quantum corrections to the energy of a state. One considers

the (regularized and renormalized) difference in vacuum energy in the presence of the state,

for instance a soliton, with respect to the vacuum. This method for solitons is described

for instance in the textbook [16]. In the case of two-dimensional solitons, it was started

by the classic work of [17–19], but since then, the calculation had a long history, because

of the fact that there are many subtleties related to regularization and renormalization

(some of the issues were fixed in [20], but others still occupy current research). The energy

of the vacuum however (the potentially infinite additive constant subtracted above) is

considered in both of these (related) cases (Casimir effect and quantum corrections to the

mass of solitons) to not be unobservable, since it is an absolute constant that does affect

physical processes.

As soon as we consider the coupling to (classical) gravity however, the constant would

gravitate and have observable effects, so we have to wonder why is it that we observe the

differences in vacuum energy (Casimir effect and quantum corrections to the mass of soli-

tons), but not the additive constant. We might however take it as a physical principle that

we cannot observe any absolute additive constant, but only changes due to the geometry of

space or of the field configuration. But what if we consider quantum gravity to be part of the

theory as well (not simply classical general relativity)? That will also change the “geometry

of space” or the “field configuration” from the one with a fixed gravitational background.

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It is known for a long time now that generically, in the presence of any type of quantum

gravity theory, we can describe some of its effects on spacetime through a modification of

the quantum uncertainty relation ∆x∆p ≥ ~/2 to something that admits a minimum

length, usually expressed as

∆x∆p ≥ 1

2

(
~ +

α

M2
Pl

∆p2

)
, (2.1)

called generalized uncertainty relation, though other forms are also possible. Note that we

have put explicitly ~ to emphase the quantum nature of the relation. I will not review the

long history of these ideas, since it is very well described in the review [21], to which I refer

the interested reader. A natural value for α would be 1 in a pure quantum gravity theory,

since if we replace the quantum uncertainty ∆x with a length scale x and the uncertainty

∆p with a matching momentum scale p, we would obtain

x ∼ 1

2

(
~
p

+
α

M2
Pl

p

)
, (2.2)

which has a minimum for pm = MPl

√
~/α, giving a minimal length

xmin =

√
~α

MPl
. (2.3)

Thus in a pure quantum gravity theory, α = 1 would be the natural choice. In string theory,

one finds that strings at trans-Planckian energies tend to spread out over a large distance,

an effect that can be understood in terms of of a minimum length and a modified uncertainty

relation as above. One of the early papers describing this is [22] (after the original papers

on trans-Planckian scattering in string theory by Gross and Mende [23, 24]), and we can

see that then the natural scale appearing in the uncertainty relation is the string scale,

α/M2
Pl = α′ ≡ 1/M2

s . Since the string scale is usually smaller than the Planck scale by

factors depending on the couplings (and maybe the volume of compactification, depending

on models), in string theory we would naturally have α < 1. Note that it has been argued

by Yoneya that the uncertainty relation in string theory is modified differently than in the

above [25] due to some non-perturbative effects, but we will nevertheless keep using it in

this form.

In light of this generalized uncertainty relation, we model the effect of the change due

to quantum gravity on the “geometry of space” or “field configuration” by replacing regular

length scales

L ≡ 2x0 =
~
p

(2.4)

with length scales admiting a minimum,

L̃ ≡ 2x =
~
p

+
α

M2
Pl

p = L+
α~
M2

PlL
. (2.5)

We will revert to putting ~ = 1 from now on.

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We now want to apply this to the problem of the cosmological constant. According

to our physical principle, we can only observe changes due to the modification of the

“geometry of space” or “field configuration”, which in the case of quantum gravity we have

argued that correspond to replacing length scales L with length scales L̃. Consider then the

vacuum energy density due to quantum gravity for a cubic system of size L, with momenta

kni = ni/L in the 3 spatial directions, i = 1, 2, 3. The graviton zero point energies (with 2

physical polarizations for each degree of freedom) is

E = 2
∑

n1,n2,n3

~ωni

2
= ~

∑
n1,n2,n3

√
n2

1 + n2
2 + n2

3

L2
. (2.6)

But we consider the sum over modes such that the maximum total momentum is kmax =

MPl, i.e. that the maximum n =
√
n2

1 + n2
2 + n2

3 is nmax = LMPl. The sum over ni’s can

be approximated by an integral, since it is dominated by the upper range, where it is a

very good approximation, so we have (putting ~ = 1)

E ' 1

L

∫ LMPl

0
d3nn =

Ω2

L

(LMPl)
4

4
= πL3M4

Pl. (2.7)

The observable part of this should be the energy in terms of L̃ minus the energy in terms

of L (in the absence of modifications to the geometry of space or field configuration), and

the energy density will be obtained by dividing with the volume of the cube, L3, giving

ρΛ =
∆E

L3
=
πM4

Pl

L3

[(
L+

α

M2
PlL

)3

− L3

]
=

3απM2
Pl

L2
. (2.8)

3 Holographic dark energy cosmology

In the context of cosmology, we are interested in an expanding sphere of radius L, so to

compare with the above we consider a sphere of the same volume as the cube, thus replacing

L→ L(4π/3)1/3 and renaming ρΛ by ρde (dark energy), so that

ρΛ → ρde =
3απ

(4π/3)2/3

M2
Pl

L2
' 3α · (1.209)

M2
Pl

L2
≡ 3c2M

2
Pl

L2
, (3.1)

where we have defined a constant c that naturally takes a value close to 1. I will asume

c ' 1 in the following, and drop it. In a real (as opposed to this effective one) quantum

gravitational approach, it is likely that it should be fixed to one, as this is the value that

gives the cosmology most consistent with observations, as noted in [8]. It remains to decide

who is the radius L in the cosmological context. As explained in [8], the choice that works

is the future event horizon (the metric is ds2 = −dt2 + a2dx2)

Rh = a(x(∞)− x(t)) = a

∫ ∞
t

dt

a
= a

∫ ∞
a

da

Ha2
, (3.2)

the boundary of a volume a fixed observer may come to observe. It is the one that gives

the right cosmology, but also in the context of the calculation presented here, it is a natural

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one to assume for the virtual fluctuations that make up the vacuum energy, as they will

give self-consistently the future evolution of the Universe. Another obvious choice, the

particle horizon,

RH = a

∫ a

0

da

Ha2
, (3.3)

does not give the right cosmology.

We should also come back to the original observation of the maximum energy density

that can be in a system of size L, so that it doesn’t collapse to form a black hole. Given a

sphere of radius L, the energy E inside it would be bounded by

E = ρ
4πL3

3
≤ L

2GN
, (3.4)

resulting in

ρ ≤ 3

8πGNL2
=

3M2
Pl

L2
. (3.5)

In [7, 8], this was taken to mean that the cosmological constant ρΛ can be only a factor c2

times the maximum value, ρΛ = 3c2M2
Pl/L

2, meaning that the vacuum energy reaches its

maximum allowable value (up to a factor c2, later taken to be 1), but with an L = Rh. I

think however that given the nature of the bound, it is more logical to consider the total

energy density in the sphere of size L to be bounded as above by the energy that gives

a Schwarzschild radius and collapses into a black hole, ρ = ρm + ρde, and to be given by

exactly the maximum value at the bound, i.e.

ρtotal = ρm + ρde =
3M2

Pl

L2
. (3.6)

Here ρm is the matter density at the current epoch, but in general contains all other forms

of energy in the Universe. But given the Friedmann equation (1.1), we see that we must

have L = H−1, i.e. the length L cannot be anything other than the (instantaneous) horizon

size. Reversing the logic, for the total energy to be at the limit to create a black hole, the

size to be considered must be the instantaneous horizon size, since to collapse or not is a

decision that is taken at a given moment, and then we derive the Friedmann equation.

The two independent equations (1.1) and (3.1) with L = Rh determine the cosmology

self-consistently, if we moreover consider an appropriate scaling for ρm. At the current,

matter+Λ-dominated epoch, we have ρm = ρ0a
−3. The cosmology is determined self-

consistently, since in (3.1) we have Rh, which depends on the future evolution, including

(as we will see, rather dominantly) on the existence of a cosmological constant (3.1). But

then the issue is where does the initial value, determining the current ρΛ, come from? As

we will see, it comes from the inflationary time, so we must consider the full evolution of

the Universe to determine it. The exact evolution during the current, matter+Λ, domi-

nated epoch was found in [8], but we will not consider it here, since we are interested in

approximative methods that can be used for the whole evolution of the Universe.

In order to estimate Rh during the various epochs, we assume that we can approxi-

mate the evolution by clean transitions between the various regimes: inflation, radiation

dominated, matter dominated, Λ dominated.

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During the Λ dominated epoch starting about now, a ' a0e
eH0(t−t0), so

RΛD
h = a

∫ ∞
t

dt

a
' a0e

eH0(t−t0)

∫ ∞
t

dt

a0eH0(t−t0)
' 1

H0
. (3.7)

In this epoch,

ρde ' const(t) (3.8)

is really like a cosmological constant.

During the matter dominated (MD) epoch, with the time of the (sharp) transition

to Λ dominated t0, we have a ' a0(t/t0)2/3, whereas as before, during the ΛD epoch,

a ' a0e
H0(t−t0), so

RMD
h = a

∫ ∞
t
' a

[∫ t0

t

dt

a0(t/t0)2/3
+

∫ ∞
t0

dt

a0eH0(t−t0)

]
'
(
t

t0

)2/3 [
3t0

(
1− (t/t0)1/3

)
+

1

H0

]
'
(
t

t0

)2/3 [
3t0 +

1

H0

]
. (3.9)

Note first that t0 ∼ 1/H0, so the two terms are equally important, and second that, since

during matter domination H = 2/(3t), we have Rh � 3t/2 = H−1. In this epoch,

ρde ∝
1

R2
h

∝ 1

t4/3
∝ 1

a2
(3.10)

is not a constant, but decreases slower than matter, and moreover

(
ρm
ρde

)
MD

= R2
hH

2 =

(
2Rh

3t

)2

'

[
2

(
t

t0

)2/3( t0
t

+
1

H0t

)]2

� 1 , (3.11)

but is ∝ t−4/3, so the ratio is decreasing.

During the radiation dominated (RD) epoch, with the time of the (sharp) transition

to matter dominated t1, we have a ' a1(t/t1)1/2, so we now obtain

RRD
h ' a

[∫ t1

t

dt

a1(t/t1)1/2
+

∫ t0

t1

dt

a0(t/t0)2/3
+

∫ ∞
t0

dt

a0eH0(t−t0)

]
'
(
t

t1

)1/2
{

2t1

(
1− (t/t1)1/2

)
+

(
t1
t0

)2/3 [
3t0

(
1− (t1/t0)1/3

)
+

1

H0

]}

'
(
t

t1

)1/2
[

2t1 +

(
t1
t0

)2/3(
3t0 +

1

H0

)]
. (3.12)

We first note that again, the comparable terms with 3t0 and 1/H0 dominate, and that Rh �
2t = H−1 (during the radiation dominated epoch H = 1/(2t)). Also during this epoch

ρde ∝
1

R2
h

∝ 1

t
∝ 1

a2
(3.13)

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is again not a constant, but decreases slower than radiation and slower than matter, since(
ρrad

ρde

)
RD

= R2
hH

2 =

(
Rh

2t

)2

� 1. (3.14)

Finally, we consider the inflationary epoch, during which there is an exponential ex-

pansion due to an approximate cosmological constant (approximately constant potential

for the inflaton) with Hubble scale

Hi =

√
ρΛi

3M2
Pl

. (3.15)

Then similarly, with the time te when inflation ends and radiation domination begins (we

assume the transition is very quick, as for the other epochs)

Rinfl
h = a

[∫ te

t

dt

a
+

∫ t1

te

dt

a
+

∫ t0

t1

dt

a
+

∫ ∞
t0

dt

a

]
' aee

Hi(t−te)

[∫ te

t

dt

aeeHi(t−te)
+

∫ t1

te

dt

a1(t/t1)1/2

+

∫ t0

t1

dt

a0(t/t0)2/3
+

∫ ∞
t0

dt

a0eH0(t−t0)

]
' 1

Hi
+ eHi(t−te)

(
te
t1

)1/2
[

2t1 +

(
t1
t0

)2/3(
3t0 +

1

H0

)]
. (3.16)

We have assumed that at least a few e-folds of inflation have already happened, so that

the first term is approximately 1/Hi (without exponential corrections). We now note that

the factor eHi(t−te) is very small, so it could in principle dampen the terms it multiplies,

so that Rinfl
h ' 1/Hi.

To see which of the two is bigger, we estimate the term with 3t0 (the term with

1/H0 is of the same order, but we are only interested in orders of magnitude), which is

= 3t
1/2
e t

1/6
1 t

1/3
0 . Even if the 1/Hi term dominates at the beginning, at the end Rinfl

h starts

to increase dramatically due to the eHi(t−te) becoming close to 1 in the second term, so

that at the end of inflation and beginning of radiation domination,

ρΛ,e = ρde =
3M2

Pl

R2
h

∼
M4

Pl

3(MPlte)(MPlt1)1/3(MPlt0)2/3
. (3.17)

With t0 close to the current time, t0 ∼ 1010yrs ∼ 4× 1018s, t1 ∼ 6× 1010s, and

te ∼
(

Ti
1014GeV

)−2

× 10−34s , (3.18)

with Ti the inflation temperature, we obtain

ρΛ,e

M4
Pl

∼ 10−68

(
Ti

1014GeV

)2(1010yrs

t0

)2/3

∼ (e−78)2

(
Ti

1014GeV

)2(1010yrs

t0

)2/3

. (3.19)

Considering also that

1

Hi
= M−1

Pl

(
MPl

Ti

)2

∼ e18M−1
Pl

(
Ti

1014GeV

)−2

, (3.20)

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we can write

Rinfl
h ∼ e18

(
Ti

1014GeV

)−2

+ e−Hi(t−te)e78

(
Ti

1014GeV

)−1( t0
1010yrs

)1/3

, (3.21)

so we need at least

Ne,min = 60 + ln

[
Ti

1014GeV

(
t0

1010yrs

)1/3
]

(3.22)

e-folds of inflation for the second term to start inflation smaller than the first, and only

afterwards grow to be larger. Note that we have explicitly allowed t0 to be different than

the current time of ∼ 1010yrs, since t0 ∼ 1/H0 is related to the cosmological constant scale,

which we will want to fix later.

We see then the self-consistency of the evolution: the magnitude of the second term

is determined by 1/H0 ∼ t0, which determines the evolution, and thus the eventual size of

ρΛ,0 (our current cosmological constant). This initial condition determining ρΛ,0, and thus

the ratio of ρΛ,0 to ρΛ,i (the energy density during inflation), can be described as giving the

time when the second term in Rh starts to dominate over the first, given a fixed number

of e-folds of inflation.

But note that the first term in Rh, 1/Hi, gives exactly the energy density (due to

the inflaton) during inflation, ρΛ,i = 3H2
iM

2
Pl, so in fact the same calculation of the cos-

mological constant also gives the inflationary cosmological constant! Yet we would need

the inflationary cosmological constant to be constant during the whole inflationary period,

including the last Ne,min e-folds, when the second term in Rh dominates, so ρde decreases

drastically. That means that, for a consistent picture, almost as soon as inflation starts, the

second term needs to start to increase, and that the real inflationary cosmological constant

simply comes from an independent potential for the inflaton. The two ρde’s would be equal

or at least comparable at the initial point, and one can understand them as having the same

origin, i.e. the initial inflationary cosmological constant would have a large component due

to the fluctuations on scale Rh, but immediately afterwards ρde = 3M2
Pl/R

2
h would start

decreasing drastically, and be a subleading component, to be relevant again only in the

current epoch, while the rest of the energy components would behave as usual.

Therefore, we are led to a physical principle, that the second term in Rh needs to

start to increase immediately after the beginning of inflation for consistency of the physical

picture, which leads to fixing of the ratio of cosmological constants during inflation and now,

ρΛ,e/ρΛ,0, in terms of the number of e-folds, by imposing Ne = Ne,min, with Ne,min in (3.22).

As we see, that fixes the physical scale H0 ∼ 1/t0. Reversely, knowing experimentally H0

and ρΛ,0 allows us to fix the number of e-folds of inflation to Ne = Ne,min in (3.22).

Note that we moreover obtain an absolute maximum for the number of e-folds of inflation.

Certainly we need Ti ≤ TPl = 1019GeV, leading to

Ne ≤ 71.5 , (3.23)

though for reasonable models the bound is even tighter.

Note that [8] also mentioned the possibility of fixing the ratio of scales in terms of the

number of e-folds of inflation, but there was no clear physical picture behind the proposal.

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Finally, we note that it was shown in [8] that a the exact solution for the evolution of

the coupled system matter plus Λ leads to an equation of state with

w = −0.903 + 0.104z , (3.24)

since during pure Λ domination, ρΛ is truly constant (corresponding to w = −1), whereas

during matter domination, ρΛ ∝ 1/a2, corresponding to w = −1/3 (in general, we have

ρ ∝ a−3(1+w)). Note that this seems to be in agreement with the 2015 Planck data [26]

(figure 7). The model can be improved by considering interaction with dark matter, etc.

(e.g. as in [12, 13]).

4 Conclusions

In conclusion, generic quantum gravity effects, described effectively by a modified uncer-

tainty relatin with a minimum length, coupled with the physical principle that the only

observable cosmological constant is the one due to changes in the geometry of space or

field configuration, allow us to obtain a result close to experimental observations. As in

the holographic dark energy model, we consider the scale L in ρde to be the future event

horizon Rh, leading to a self-consistent cosmological evolution. The scale of ρΛ,0 today

relative to ρΛ,e during inflation is set by the initial conditions for Rh. For a consistent

picture of inflation, we are led to a physical principle, that the second term in Rinfl
h starts

to dominate just at the beginning of inflation. This fixes ρΛ,0/ρΛ,e in terms of the number

of e-folds Ne and the scale of inflation Ti.

Acknowledgments

I would like to thank Rogerio Rosenfeld for useful comments on the manuscript.

My research is supported in part by CNPq grant 301709/2013-0 and FAPESP

grant 2014/18634-9.

Open Access. This article is distributed under the terms of the Creative Commons

Attribution License (CC-BY 4.0), which permits any use, distribution and reproduction in

any medium, provided the original author(s) and source are credited.

References

[1] T. Padmanabhan, Cosmological constant: the weight of the vacuum, Phys. Rept. 380 (2003)

235 [hep-th/0212290] [INSPIRE].

[2] J. Frieman, M. Turner and D. Huterer, Dark energy and the accelerating universe, Ann. Rev.

Astron. Astrophys. 46 (2008) 385 [arXiv:0803.0982].

[3] R.R. Caldwell and M. Kamionkowski, The physics of cosmic acceleration, Ann. Rev. Nucl.

Part. Sci. 59 (2009) 397 [arXiv:0903.0866] [INSPIRE].

[4] M. Li, X.-D. Li, S. Wang and Y. Wang, Dark energy, Commun. Theor. Phys. 56 (2011) 525

[arXiv:1103.5870] [INSPIRE].

– 9 –

http://creativecommons.org/licenses/by/4.0/
http://dx.doi.org/10.1016/S0370-1573(03)00120-0
http://dx.doi.org/10.1016/S0370-1573(03)00120-0
http://arxiv.org/abs/hep-th/0212290
http://inspirehep.net/search?p=find+EPRINT+hep-th/0212290
http://dx.doi.org/10.1146/annurev.astro.46.060407.145243
http://dx.doi.org/10.1146/annurev.astro.46.060407.145243
http://arxiv.org/abs/0803.0982
http://dx.doi.org/10.1146/annurev-nucl-010709-151330
http://dx.doi.org/10.1146/annurev-nucl-010709-151330
http://arxiv.org/abs/0903.0866
http://inspirehep.net/search?p=find+EPRINT+arXiv:0903.0866
http://dx.doi.org/10.1088/0253-6102/56/3/24
http://arxiv.org/abs/1103.5870
http://inspirehep.net/search?p=find+EPRINT+arXiv:1103.5870


J
H
E
P
0
4
(
2
0
1
6
)
1
4
9

[5] Planck collaboration, P.A.R. Ade et al., Planck 2015 results. XIII. Cosmological

parameters, arXiv:1502.01589 [INSPIRE].

[6] A.G. Cohen, D.B. Kaplan and A.E. Nelson, Effective field theory, black holes and the

cosmological constant, Phys. Rev. Lett. 82 (1999) 4971 [hep-th/9803132] [INSPIRE].

[7] S.D.H. Hsu, Entropy bounds and dark energy, Phys. Lett. B 594 (2004) 13 [hep-th/0403052]

[INSPIRE].

[8] M. Li, A model of holographic dark energy, Phys. Lett. B 603 (2004) 1 [hep-th/0403127]

[INSPIRE].

[9] M. Li, X.-D. Li, S. Wang and X. Zhang, Holographic dark energy models: a comparison from

the latest observational data, JCAP 06 (2009) 036 [arXiv:0904.0928] [INSPIRE].

[10] M. Li, X.-D. Li, S. Wang, Y. Wang and X. Zhang, Probing interaction and spatial curvature

in the holographic dark energy model, JCAP 12 (2009) 014 [arXiv:0910.3855] [INSPIRE].

[11] Y.-H. Li, S. Wang, X.-D. Li and X. Zhang, Holographic dark energy in a Universe with

spatial curvature and massive neutrinos: a full Markov Chain Monte Carlo exploration,

JCAP 02 (2013) 033 [arXiv:1207.6679] [INSPIRE].

[12] D. Pavon and W. Zimdahl, Holographic dark energy and cosmic coincidence, Phys. Lett. B

628 (2005) 206 [gr-qc/0505020] [INSPIRE].

[13] B. Wang, Y.-g. Gong and E. Abdalla, Transition of the dark energy equation of state in an

interacting holographic dark energy model, Phys. Lett. B 624 (2005) 141 [hep-th/0506069]

[INSPIRE].

[14] G. Plunien, B. Müller and W. Greiner, The Casimir effect, Phys. Rept. 134 (1986) 87

[INSPIRE].

[15] M. Bordag, U. Mohideen and V.M. Mostepanenko, New developments in the Casimir effect,

Phys. Rept. 353 (2001) 1 [quant-ph/0106045] [INSPIRE].

[16] R. Rajaraman, Solitons and instantons. An introduction to solitons and instantons in

quantum field theory, North-Holland, Amsterdam (1982).

[17] R.F. Dashen, B. Hasslacher and A. Neveu, Nonperturbative methods and extended hadron

models in field theory. 1. Semiclassical functional methods, Phys. Rev. D 10 (1974) 4114

[INSPIRE].

[18] R.F. Dashen, B. Hasslacher and A. Neveu, Nonperturbative methods and extended hadron

models in field theory. 2. Two-dimensional models and extended hadrons, Phys. Rev. D 10

(1974) 4130 [INSPIRE].

[19] R.F. Dashen, B. Hasslacher and A. Neveu, Semiclassical bound states in an asymptotically

free theory, Phys. Rev. D 12 (1975) 2443 [INSPIRE].

[20] H. Nastase, M.A. Stephanov, P. van Nieuwenhuizen and A. Rebhan, Topological boundary

conditions, the BPS bound and elimination of ambiguities in the quantum mass of solitons,

Nucl. Phys. B 542 (1999) 471 [hep-th/9802074] [INSPIRE].

[21] S. Hossenfelder, Minimal length scale scenarios for quantum gravity, Living Rev. Rel. 16

(2013) 2 [arXiv:1203.6191] [INSPIRE].

[22] D. Amati, M. Ciafaloni and G. Veneziano, Can space-time be probed below the string size?,

Phys. Lett. B 216 (1989) 41 [INSPIRE].

– 10 –

http://arxiv.org/abs/1502.01589
http://inspirehep.net/search?p=find+EPRINT+arXiv:1502.01589
http://dx.doi.org/10.1103/PhysRevLett.82.4971
http://arxiv.org/abs/hep-th/9803132
http://inspirehep.net/search?p=find+EPRINT+hep-th/9803132
http://dx.doi.org/10.1016/j.physletb.2004.05.020
http://arxiv.org/abs/hep-th/0403052
http://inspirehep.net/search?p=find+EPRINT+hep-th/0403052
http://dx.doi.org/10.1016/j.physletb.2004.10.014
http://arxiv.org/abs/hep-th/0403127
http://inspirehep.net/search?p=find+EPRINT+hep-th/0403127
http://dx.doi.org/10.1088/1475-7516/2009/06/036
http://arxiv.org/abs/0904.0928
http://inspirehep.net/search?p=find+EPRINT+arXiv:0904.0928
http://dx.doi.org/10.1088/1475-7516/2009/12/014
http://arxiv.org/abs/0910.3855
http://inspirehep.net/search?p=find+EPRINT+arXiv:0910.3855
http://dx.doi.org/10.1088/1475-7516/2013/02/033
http://arxiv.org/abs/1207.6679
http://inspirehep.net/search?p=find+EPRINT+arXiv:1207.6679
http://dx.doi.org/10.1016/j.physletb.2005.08.134
http://dx.doi.org/10.1016/j.physletb.2005.08.134
http://arxiv.org/abs/gr-qc/0505020
http://inspirehep.net/search?p=find+EPRINT+gr-qc/0505020
http://dx.doi.org/10.1016/j.physletb.2005.08.008
http://arxiv.org/abs/hep-th/0506069
http://inspirehep.net/search?p=find+EPRINT+hep-th/0506069
http://dx.doi.org/10.1016/0370-1573(86)90020-7
http://inspirehep.net/search?p=find+J+"Phys.Rept.,134,87"
http://dx.doi.org/10.1016/S0370-1573(01)00015-1
http://arxiv.org/abs/quant-ph/0106045
http://inspirehep.net/search?p=find+EPRINT+quant-ph/0106045
http://dx.doi.org/10.1103/PhysRevD.10.4114
http://inspirehep.net/search?p=find+J+"Phys.Rev.,D10,4114"
http://dx.doi.org/10.1103/PhysRevD.10.4130
http://dx.doi.org/10.1103/PhysRevD.10.4130
http://inspirehep.net/search?p=find+J+"Phys.Rev.,D10,4130"
http://dx.doi.org/10.1103/PhysRevD.12.2443
http://inspirehep.net/search?p=find+J+"Phys.Rev.,D12,2443"
http://dx.doi.org/10.1016/S0550-3213(98)00773-1
http://arxiv.org/abs/hep-th/9802074
http://inspirehep.net/search?p=find+EPRINT+hep-th/9802074
http://dx.doi.org/10.12942/lrr-2013-2
http://dx.doi.org/10.12942/lrr-2013-2
http://arxiv.org/abs/1203.6191
http://inspirehep.net/search?p=find+EPRINT+arXiv:1203.6191
http://dx.doi.org/10.1016/0370-2693(89)91366-X
http://inspirehep.net/search?p=find+J+"Phys.Lett.,B216,41"


J
H
E
P
0
4
(
2
0
1
6
)
1
4
9

[23] D.J. Gross and P.F. Mende, The high-energy behavior of string scattering amplitudes, Phys.

Lett. B 197 (1987) 129 [INSPIRE].

[24] D.J. Gross and P.F. Mende, String theory beyond the Planck scale, Nucl. Phys. B 303 (1988)

407 [INSPIRE].

[25] T. Yoneya, String theory and space-time uncertainty principle, Prog. Theor. Phys. 103

(2000) 1081 [hep-th/0004074] [INSPIRE].

[26] Planck collaboration, P.A.R. Ade et al., Planck 2015 results. XIV. Dark energy and

modified gravity, arXiv:1502.01590 [INSPIRE].

– 11 –

http://dx.doi.org/10.1016/0370-2693(87)90355-8
http://dx.doi.org/10.1016/0370-2693(87)90355-8
http://inspirehep.net/search?p=find+J+"Phys.Lett.,B197,129"
http://dx.doi.org/10.1016/0550-3213(88)90390-2
http://dx.doi.org/10.1016/0550-3213(88)90390-2
http://inspirehep.net/search?p=find+J+"Nucl.Phys.,B303,407"
http://dx.doi.org/10.1143/PTP.103.1081
http://dx.doi.org/10.1143/PTP.103.1081
http://arxiv.org/abs/hep-th/0004074
http://inspirehep.net/search?p=find+EPRINT+hep-th/0004074
http://arxiv.org/abs/1502.01590
http://inspirehep.net/search?p=find+EPRINT+arXiv:1502.01590

	Introduction
	Cosmological constant
	Holographic dark energy cosmology
	Conclusions