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Published for SISSA by Springer

Received: April 11, 2014

Accepted: June 1, 2014

Published: June 26, 2014

Conformal inflation from the Higgs

Renato Costa and 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: renato.costa87@gmail.com, nastase@ift.unesp.br

Abstract: We modify the conformal inflation set-up of [1], with a local Weyl invariance,

a dynamical Planck scale and an SO(1, 1) invariance at high energies, in order to be able

to identify the physical scalar with the physical Higgs at low energies, similar to the cyclic

Higgs models of [2]. We obtain a general class of exponentially-corrected potentials that

gives a generalized Starobinsky model with an infinite series of Rp corrections, tracing a

line in the (r, ns) plane for CMB fluctuations, with an r that can be made to agree with

the recent BICEP2 measurement. Introducing a coupling different from the conformal

value, thus breaking the local Weyl symmetry, leads nevertheless to a very strong attractor

motion towards the generalized Starobinsky line.

Keywords: Cosmology of Theories beyond the SM, Higgs Physics, Classical Theories of

Gravity

ArXiv ePrint: 1403.7157

Open Access, c© The Authors.

Article funded by SCOAP3.
doi:10.1007/JHEP06(2014)145

mailto:renato.costa87@gmail.com
mailto:nastase@ift.unesp.br
http://arxiv.org/abs/1403.7157
http://dx.doi.org/10.1007/JHEP06(2014)145


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Contents

1 Introduction 1

2 Starobinsky models and a general class of potentials 3

3 Class of models with Weyl invariance and approximate SO(1, 1) invari-

ance, reducing to Higgs 7

4 Inflation in these models 10

5 General coupling ξ and attractors 12

6 Conclusions 14

1 Introduction

With the latest results from the Planck experiment [3] and the recent BICEP2 measure-

ment of r [4], cosmology and in particular inflation has finally started to become a testable

field, since now we can rule out more and more models. Planck showed a preference to-

wards inflation models with a plateau, as opposed to λnφ
n potentials, and in particular

the Starobinsky model is close to the center of its allowed region in the (r, ns) plane. But

the BICEP2 experiment favors instead large values of r, in the 0.15-0.25 range, seeming to

exclude the simple Starobinsky model, with typically r ∼ 0.01. The Starobinsky model is

understood as inflation due to the presence of an R2 term in the action, but it is equivalent

to a usual Einstein plus scalar model with a potential that is an exponentially-corrected

plateau. We will review this mechanism and generalize it to more complicated f(R) ac-

tions, in the next section, in particular obtaining a generalization that allows for large r

compatible with BICEP2, tracing a line in the (r, ns) plane.

But given that we want a plateau at large scalar field displacement values, where infla-

tion happens, it is relevant to ask whether there is a symmetry at high energies that forces

the model to have a plateau, in which case inflation would arise naturally, avoiding some

non-naturalness arguments raised by [5] (see [6] for counter-arguments to those criticisms).

If we are looking for such a symmetry, one possible answer that comes to mind is local Weyl

symmetry (symmetry under rescaling the metric and the scalar fields by a local conformal

factor), which in the Standard Model with masses given by VEVs of the Higgs seems to

be broken at the fundamental level (not considering VEVs) only by the Planck mass MPl.

That can be remedied however by considering that MPl is also an effective coupling coming

from the VEVs of scalars, leading to a theory with no a priori mass scales. To avoid issues

with the experiments on the time variation of the Planck scale, one is led to models with 2

scalar fields and the local Weyl symmetry, as in [1, 7] (following earlier work by [8–13]; note

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that for [8, 12, 13] the initial motivation was superconformal symmetry, whereas for [9–11]

the initial motivation was from 2-time physics models. The two are however related since

for both we have an SO(4, 2) symmetry, conformal in 3+1 dimensions vs. Lorentz in 4+2).

If we impose also an SO(1, 1) symmetry (can be thought of as a remnant of breaking of

SO(4, 2) → SO(3, 1) × SO(1, 1)) between the 2 scalars at large field value (equivalent of

high energies in terms of the evolution of the Universe), and simply deform away from it,

we are led to a theory with a plateau, giving naturally inflation. Moreover, one obtains the

Starobinsky model predictions, basically because the scalars are related to the canonical

scalar in an exponential way φi ∼ ecϕ at large ϕ, and the SO(1, 1) symmetry cancels the

leading contribution in the potential, as we will argue in detail in the current paper. The

local Weyl invariance allows us to remove one of the scalars by fixing a gauge, and be left

with a single physical scalar. Naturally one obtains the original Starobinsky model, so it is

important to look for generalizations that allow us to go to the Starobinsky line described

above.

On the other hand, in [2, 14], a similar model was considered, again with local Weyl

invariance and two scalars, and the Planck mass coming from the same scalar VEVs, but

without the SO(1, 1) symmetry between the scalars (except in the kinetic term, where it is

essential!), where the motivation was different. We know of only one observed scalar so far,

the recently discovered Higgs boson [15, 16], so the natural question to be asked is whether

we can identify the physical scalar with the Higgs. Indeed one can, and it was shown that if

we want to keep only some terms natural for the Higgs in the potential, one obtains a cyclic

cosmology. Basically, the reason is the same exponential relation to the canonical scalar

φi ∼ ecϕ, but now because the lack of SO(1, 1) symmetry avoids the cancellation of the

leading term and leaves us with a positive exponential potential V ∼ eaϕ, which is one of the

natural class of potentials for cyclic cosmology. Thus paradoxically, a similar set-up with

or without SO(1, 1) at large energies leads to natural inflation or natural cyclic cosmology.

In this paper we mix the two approaches by taking the best out of each one, noticing

loopholes left by the two constructions, as well as generalizing the Starobinsky model by

completing it to an infinite series summing to an f(R), giving a line in the (ns, r) plane for

CMB fluctuations. We note that allowing for SO(1, 1) at large field value and deforming

away from it allows for a more general set-up than the one considered in [1, 7], in particular

allowing us to naturally get the Higgs potential at low energies. Reversely, in [2, 14] one

considered a quartic Higgs potential, but one can consider that the potential is modified at

large field values to reach asymptotically the SO(1, 1) invariant form that can hold at high

energies. We will see that in this case we obtain again a model giving predictions similar to

the Starobinsky one in the (r, ns) plane, as in [1, 7], but now the model is more general, and

more importantly we can also obtain the generalized Starobinsky line, allowing us to agree

with the ns value of Planck but also the r value of BICEP2. Note that the idea of Higgs

inflation is far from new, being in fact quite popular recently. Moreover, there is in fact a

model that can be thought of as a particular case of the general set-up with a Higgs coupled

to the Einstein action, otherwise with only a Higgs potential, the Bezrukov-Shaposhnikov

model [17]. It was shown in [14] that it admits a Weyl-symmetric formulation.

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The paper is organized as follows. In section 2 we review the Starobinsky model,

generalized to f(R) actions, in particular showing that we can obtain an arbitrary value of

r through an f(R) that goes over to R2 in the inflating large R region. Then we show that a

class of exponentially-corrected potentials give rise to the same predictions (this observation

was made in [18], and in the context of supergravity models in [19–21]; we learned about

these references after the paper was posted on the arXiv, from the referee; also [22] made

this prediction), also generalized to a line in the (r, ns) plane. In section 3 we present the

class of models we will be considering, with local Weyl invariance, SO(1, 1) invariance and

reducing to the Higgs potential at low energies. In section 4 we discuss various particular

cases and the inflationary models arising from them. In section 5 we show that with a

modification of the scalar-Einstein coupling ξ away from the conformal value of −1/6 leads

nevertheless to a strong attraction to the same Starobinsky line. In section 6 we conclude.

2 Starobinsky models and a general class of potentials

The Starobinsky model is obtained by adding an R2 correction term to the Einstein-Hilbert

action, and it is equivalent to adding a scalar with a potential that is an exponentially

corrected plateau. We will explain this mechanism by generalizing to an Rp correction,

where p is an arbitrary positive real number. We start with the action

S =
M2

Pl

2

∫

d4x
√−g(R+ βp+1R

p+1). (2.1)

It can be rewritten by introducing an auxiliary scalar field α as

S =
M2

Pl

2

∫

d4x
√−g

[

R(1 + (p+ 1)βp+1α)− pβp+1α
p+1

p

]

. (2.2)

Defining the Einstein frame metric

gEµν = [1 + (p+ 1)βp+1α]gµν ≡ Ω−2gµν , (2.3)

and using the general formula for a Weyl rescaling in d dimensions

R[gµν ]=Ω−2
[

R[gEµν ]−2(d−1)gµνE ∇E
µ∇E

ν lnΩ−(d−2)(d−1)gµνE (∇E
µ lnΩ)∇E

ν lnΩ
]

, (2.4)

we obtain the Einstein plus scalar action

S =
M2

Pl

2

∫

d4x
√−gE

[

R[gE ]−
3(p+ 1)2β2

p+1

2
gµνE

∇E
µα∇E

ν α

[1 + βp+1(p+ 1)α]2
− V (α)

]

, (2.5)

where

V (α) =
pβp+1α

p+1

p

[1 + (p+ 1)βp+1α]
2 . (2.6)

Note that the auxiliary scalar has become dynamical, having a kinetic term. Defining the

canonical scalar by

dφ =

√

3

2

(p+ 1)βp+1dα

1 + βp+1(p+ 1)α
⇒ φ =

√

3

2
ln[1 + βp+1(p+ 1)α] , (2.7)

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the potential is

V (φ) = pβp+1





e

√

2

3

φ
MPl − 1

βp+1(p+ 1)





p+1

p

e
−2

√

2

3

φ
MPl . (2.8)

The potential is real and positive definite for φ ≥ 0, but in order for it to continue to be

also for φ < 0, we must have p = 1/(2k + 1), with k an integer. Then at large field value

φ → ∞, we obtain

V ≃ pβp+1

[(p+ 1)βp+1]
p+1

p

e
1−p
p

√

2

3

φ
MPl

[

1− p+ 1

p
e
−
√

2

3

φ
MPl + . . .

]

, (2.9)

which means that we get an exponentially-corrected plateau only for p = 1, otherwise there

is a dominant overall exponential.

This method can be used for a general f(R) action, but we will use it to reproduce a

more general expansion at φ → ∞. We see that for the Starobinsky model p = 1, k = 0,

as well as for the generalized Starobinsky model with general integer k, the power in the

exponential correcting the plateau is
√

2
3 .

The above model suggests considering the more general expansion at φ → ∞,1

V ≃ A

[

1− ce
−a φ

MPl

]

. (2.10)

For this model, the inflationary slow-roll parameters are

ǫ ≡ M2
Pl

2

(

V ′(φ)

V (φ)

)2

=
a2c2

2
e
−2a φ

MPl ≪ |η|

η = M2
Pl

V ′′(φ)

V (φ)
= −a2ce

−a φ
MPl . (2.11)

Then the parameters (ns, r) of the spectrum of CMB fluctuations are given by

ns − 1 = −6ǫ+ 2η ≃ 2η = −2a2ce
−a φ

MPl

r = 16ǫ = 8a2c2e
−2a φ

MPl =
2

a2
(ns − 1)2. (2.12)

To fix the value of e
−a φ

MPl , we consider the number of e-foldings, Ne. Note that the value of

φ is the value at horizon crossing (crossing outside the horizon, to return inside it now) for

the scale of the CMB fluctuations. Inflation happens at large φ, decreasing as the Universe

expands, so the start of inflation can correspond to a φ0 which can be greater than φ, but

for simplicity we will consider them equal. Then

Ne = −
∫ φf/MPl

φ0/MPl

dφ/MPl√
2ǫ

= − 1

ac

∫ φf/MPl

φ0/MPl

e
a φ
MPl ≃ 1

a2c
e
a φ
MPl

1This more general model and its predictions were considered also in [18] in a general setting. In [19–21],

this model and its predictions were analyzed in the context of supergravity models, in particular arising

from a certain Kähler potential. We thank the referee for pointing out these references to us. See also [22]

for a recent treatment of the same model. Our interest in this general potential is in obtaining it from the

model for conformal inflation from the Higgs, in the following sections.

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=
1

−η
=

2

1− ns
, (2.13)

where we have used the fact that eaφf/MPl ∼ 1 in order for inflation to end, so we have

neglected this term in Ne.

In conclusion, we obtain the constraints

1− ns =
2

Ne

r =
2

a2
(ns − 1)2

=
8

a2Ne
. (2.14)

Then, for instance with 50 e-folds, Ne = 50, ns is fixed to be ns ≃ 0.9600, which is

in the middle of the allowed region by the Planck experiment [3], while 60 e-folds gives

ns ≃ 0.9667, again compatible with the data (for instance, Planck + WMAP gives 0.9603±
0.0073). For concreteness, we will take Ne = 50 from now on. With a =

√

2/3 as for the

Starobinsky model (even in the case generalized to Rp+1), r = 3(ns−1)2, so ns−1 ≃ −1/25

gives r ≃ 0.005, too small for the measurement of BICEP2 (which excludes such a virtually

zero r at at least 5σ).

But within the context of this more general model, we can fit even the central value

of r of the BICEP2 experiment, of r = 0.20 at ns − 1 ≃ −1/25, by r ≃ 2/(25a)2 ∼ 0.20 for

a ∼ 1/8.

To complete the analysis of (2.10), we consider the running of ns,

dns

d ln k
= −16ǫη + 24ǫ2 + 2ξ2 , (2.15)

where

ξ2 ≡ M4
Pl

V ′V ′′′

V 2
. (2.16)

Then for (2.10) we have

ξ2 ≃ c2a4e
−2a φ

MPl , (2.17)

and ξ2 ∼ O(e
−2a φ

MPl ) ≫ ǫη, ǫ2, so

dns

d ln k
≃ 2ξ2 ≃ 2c2a4e

−2a φ
MPl ≃ (ns − 1)2

2
. (2.18)

Finally, the CMB normalization gives [23]

H2
inf

8π2ǫM2
Pl

≃ 2.4× 10−9 , (2.19)

where H2
inf = Vinf/3M

2
Pl. In our case, this is A/3M2

Pl, so that the constraint is

A/M4
Pl

24π2ǫ
≃ 2.4× 10−9. (2.20)

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Replacing ǫ by r/16, we get

A

M4
Pl

≃ 3π2

2
r × 2.4× 10−9. (2.21)

With the central value of r ≃ 0.2 of BICEP2, we get

A

M4
Pl

≃ 7.1× 10−9 ⇒ A1/4 ≃ 10−2MPl. (2.22)

For the potential of the Starobinsky model in (2.8) with p = 1, this gives the somewhat

unnatural

β2 ≈ 1.4× 108M−2
Pl ≃ (10−4MPl)

−2. (2.23)

We now return to the question of how to obtain an f(R) model, generalizing the

Starobinsky model, that still allows for an a as small as ∼ 1/8. It was essential that we

had the canonical scalar related to the scalar α by (2.7) in order to obtain a =
√

2
3 .

Consider MPl = 1 for the moment, in order not to clutter formulas. We want to

generalize (2.7) to

1 + α = e

√

2

3

φ
b ⇒ dφ =

√

3

2
b

dα

1 + α
, (2.24)

which gives a =
√

2
3
1
b . We see that then the kinetic term must come in the Jordan frame

from a factor R[1 + α]b. Since moreover we want the potential to be (β is a constant)

V = β
(α)2b

[1 + α]2b
= β

[

1− e
−
√

2

3

φ
b

]2b

≃ β

[

1− 2be
−
√

2

3

φ
b

]

, (2.25)

we obtain the action in Jordan frame

S =
1

2

∫

d4x
√−g

[

R(1 + α)b − βα2b
]

, (2.26)

and we want (−)2b to be real and positive, so we need b = k + 1 to be an integer.

To eliminate the auxiliary scalar α, we solve for its equation of motion, obtaining

R = 2β
α2b−1

(1 + α)b−1
, (2.27)

which we cannot invert for general b, but we see that by replacing α in the action we get

an action of the type f(R),

S =
1

2

∫

d4x
√−gf(R). (2.28)

At small curvature R → 0, α → 0 (which means φ → 0 for the physical scalar, i.e. the end

of inflation region V ≃ 0), α = (R/2β)
1

2b−1 , giving

f(R) ≃ R

[

1 +

(

b− 1

2

)

(2β)−
1

2b−1R
1

2b−1 + . . .

]

, (2.29)

so we see that with b = k + 1, we obtain the same first term in the expansion as in the

generalized Starobinsky model above, but now the potential has a true plateau. At large

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curvature R → ∞, α → ∞ (which means large physical scalar φ, i.e. the inflating region),

α = (R/2β)
1

b , giving

f(R) ≃ R2

4β
, (2.30)

as in the Starobinsky model.

In conclusion, just by allowing for a completion of the Starobinsky model via a partic-

ular infinite series that sums to the above f(R), we can obtain any value for a, thus any

value for r needed.

3 Class of models with Weyl invariance and approximate SO(1, 1) in-

variance, reducing to Higgs

We start with a model with both local Weyl symmetry and SO(1, 1) invariance, where

the Planck scale appears when choosing a gauge, and otherwise there is no dimensionful

parameter,

S =
1

2

∫

d4x
√−g

[

∂µχ∂
µχ− ∂µφ∂

µφ+
χ2 − φ2

6
R− λ

18
(φ2 − χ2)2

]

. (3.1)

The coupling of 1/6 of the scalar to the Einstein term was chosen such as to have the

conformal value, and the potential was chosen to be quartic, all in all giving the local Weyl

symmetry under

gµν → e−2σ(x)gµν ; χ → eσ(x)χ, φ → eσ(x)φ. (3.2)

Since
√−g → e−4σ(x)√−g, the potential needs to have scaling dimension 4 in the scalar

fields. Moreover, imposing the SO(1, 1) symmetry of χ2 − φ2, which is a Lorentz type

symmetry (in fact, in [9–11] the motivation for this model was 2-time physics, written

covariantly in (4, 2) Minkowski dimensions, and the SO(1, 1) is a remnant of the SO(4, 2)

Lorentz invariance), we are forced to take also the potential (φ2−χ2). The SO(1, 1) can also

be obtained from a model with conformal invariance, again SO(4, 2), the initial motivation

of [8, 12, 13].

It would seem like χ is a ghost, but because we have a local Weyl symmetry, we can

put one scalar degree of freedom to zero, such as to get rid of the ghost. Choosing a gauge

for the local scaling invariance will also necessarily introduce a scale, the Planck scale (it is

obvious that in order to fix the scaling transformation we must choose a scale). Of course,

since we have only one scale, physics is independent of this scale as it should be, since the

scale is a gauge choice (calling MPl to be 1m or 1019GeV or something else is meaningless

unless there is an independent definition of what is 1m or 1GeV or some other scale).

One simple gauge choice is the Einstein gauge (E-gauge) χ2 − φ2 = 6M2
Pl, which is

solved in terms of the canonically normalized field ϕ by

χ =
√
6MPl cosh

ϕ√
6MPl

; φ =
√
6MPl sinh

ϕ√
6MPl

. (3.3)

In terms of it, the action is the Einstein action, with a canonical scalar and a cosmological

constant,

S =

∫

d4x
√−g

[

M2
Pl

2
R− 1

2
∂µϕ∂

µϕ− λM4
Pl

]

. (3.4)

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Another simple gauge choice is the physical Jordan gauge or c-gauge, χ(x) =
√
6MPl. In

terms of it, the action is

S =

∫

d4x
√−g

[

M2
Pl

2
R

(

1− φ2

6M2
Pl

)

− 1

2
∂µφ∂µφ− λ

36
(φ2 − 6M2

Pl)
2

]

. (3.5)

We can go to the Einstein metric by gEµν = (1−φ2/6M2
Pl)g

J
µν and then define the canonically

normalized field ϕ by dϕ/dφ = (1 − φ2/6M2
Pl)

−1, and reobtain (3.4). But one thing one

can note now is that the potential for the field φ with the conformal coupling to R looks

like the Higgs potential, just with scalar VEV v2 = 6M2
Pl, instead of the experimentally

known v ≃ 246GeV .

Otherwise one could identify φ with a physical Higgs field, but the Higgs VEV of
√
6MPl

was the result of the SO(1, 1) symmetry, and in the Einstein frame it led to an exactly

flat potential (cosmological constant). If we completely discard the SO(1, 1) symmetry as

in [2, 14] and insist instead on having the Higgs potential from low energies, λ(H†H−v2)2,

appear in the physical Jordan gauge, we are led to λ(φ2 − ω2χ2)2, generalized with the

addition of a term λ′χ4 (in order to have the most general quartic potential for φ and χ)

that reduces to a cosmological constant. Note however that for the kinetic terms and R-

coupling terms we must insist on the same SO(1, 1) symmetric form, if we want to remain

with only the physical Higgs and the scalar VEV after gauge fixing, which seems contrived

if we completely abandon the symmetry in the potential.

The attraction of this construction is that now in the Lagrangean for the Standard

Model coupled to gravity there are no explicit mass scales, and the fundamental theory is lo-

cal Weyl-invariant. Masses in the Standard Model come from coupling to the Higgs, and the

Higgs VEV and Planck mass now come from choosing a gauge in a Weyl-invariant theory.

However, the absence of the SO(1, 1) symmetry means that we are naturally led towards

a cyclic cosmology. Indeed, in the Einstein gauge for the local Weyl symmetry defined

by (3.3), the potential is now

V ∼λM4
Pl

(

sinh2
ϕ√
6MPl

−ω2 cosh2
ϕ√
6MPl

)2

−λ′M4
Pl cosh

4 ϕ√
6MPl

≈CM4
Pl exp

4ϕ√
6MPl

,

(3.6)

i.e. an exponential of the canonical scalar at large field value. This generically leads to

cyclic cosmology, and we see that the origin of this is the non-cancellation of the leading

exponentials. In the SO(1, 1) symmetric form, there was no λ′χ4 term and ω = 1 at high

field values, leading to a cancellation of the leading exponentials in cosh2− sinh2, giving in

fact a constant.

Besides the fact that requiring SO(1, 1) symmetric kinetic terms but no remnant of the

symmetry in the potential is unnatural, we also have the issue that general cyclic cosmolo-

gies are incompatible with a large value of the tensor to scalar ratio of CMB fluctuations,

r [5, 24], and the BICEP2 experiment finds a value close to r ∼ 0.2 [4]. So it would be ideal

to find a model that gives inflation at high energies, and a natural way for that is to have

an approximate SO(1, 1) at high energies, which we take to translate into large field values.

So we ask what is the most general potential depending on φ and χ with the desired

properties: local Weyl symmetry, to reduce at large field values (large energies) to the

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SO(1, 1) symmetric form, and at small field values (small energies) to the Higgs form.

From just local Weyl symmetry, the most general form is f(φ/χ)φ4, since
√−gφ4 and φ/χ

are both local Weyl invariant. But we want also to reduce to the SO(1, 1) invariant form

(φ2 − χ2)2 at large field values, so we must have

V = λ
[

f̃(φ/χ)φ2 − g̃(φ/χ)χ2
]2

, (3.7)

or in another parametrization

V = λf(φ/χ)
[

φ2 − g(φ/χ)χ2
]2

. (3.8)

Since in the Einstein gauge φ/χ = tanhϕ/
√
6MPl which goes to 1 at large ϕ, we must

require g(1) = 1 for SO(1, 1) symmetry at large field values. In [1, 7] it was considered

only g(x) ≡ 1, hence the possible connection with the Higgs was not considered.

Now the condition that we obtain the Higgs potential at low field values (low energies)

is that g(0) ≃ ω2, where ω = 246GeV/
√
6MPl. Moreover, the function g(x) must give at

small energies subleading corrections to the Higgs potential. For the simplest function, a

polynomial plus a constant, we can take

g(x) = ω2 + (1− ω2)xn , (3.9)

and we must impose n > 2. Indeed, if n = 1 (and f(x) = 1) we get at small field values

a potential ∝ [φ2 − (ω2 + (1 − ω2)φ/χ)χ2]2 and in the Einstein gauge at small field the

leading terms in the potential become

V ≃ λ
[

(1− ω2)(ϕ2 −
√
6ϕMPl)

2 − 6ω2M2
Pl

]2
, (3.10)

so the linear term will dominate over the quadratic term in the square bracket. In the

n = 2 case we can check that actually the good φ2 term cancels in the square bracket and

the potential is simply V ≃ 36λω4M4
Pl, so again is not good. For n > 2 instead, at small

field the higher order corrections are suppressed by MPl, i.e. we get approximately

V ≃ λ

[

ϕ2 − 6ω2M2
Pl − 6M2

Pl

(

ϕ√
6MPl

)n]2

≃
[

ϕ2 − 6ω2M2
Pl

]2
, (3.11)

where we have used that ω2 ≪ 1, and we have dropped all terms coming from higher orders

in the expansion of cosh(ϕ/
√
6MPl) and sinh(ϕ/

√
6MPl).

Finally now, we can have an overall function f(φ/χ), but if we want to have the Higgs

potential at low energies, we need again to restrict its form. We write it as f(x) = 1+F (x),

and a simple possible form for F (x) would be a polynomial, F (x) = cnx
n, but by the same

logic as above, we need to have n > 2, if not we modify the Higgs potential at small field

values. In the next section we will study the resulting inflation from these models, and we

will see other possible relevant examples for F (x).

We have not addressed the issue of how can these models arise from a fundamental

theory? The potentials described need to be only effective potentials, i.e. including quantum

corrections. As we saw, the scale for the corrections to the Higgs potential is the Planck

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scale, so naturally these are quantum gravity corrections, which could in principle come,

for example, from string theory. The quantum theory is supposed to be valid at large field

values, which is generically the case for scalars arising from string models. Moreover, the

energy density at large field values is very large, which again implies that we are in the

quantum gravity region. At these high energies, we have as usual the local Weyl symmetry,

but also the SO(1, 1) symmetry which gets deformed, so it would be natural to assume that

ϕ → ∞ is a special point that has the full symmetry, but the symmetry is not protected

away from it. However, the understanding of this is left for future work.

Finally, instead of the scalar φ we have the Higgs, which is a doublet, whereas χ would

be a singlet under SU(2), and then φ from the above discussion, the field relevant for

inflation, would be its norm φ =
√
H†H. The action is then

S =
1

2

∫

d4x
√−g

[

∂µχ∂
µχ− ∂µH

†∂µH +
χ2 −H†H

6
R

− λ

18

(

1 + F (
√
H†H/χ)

)(

H†H − g(
√
H†H/χ)χ2

)2
+ L′

SM

]

, (3.12)

where L′
SM is the Standard Model Lagrangean other than the Higgs kinetic and potential

term.

4 Inflation in these models

We next turn to inflation in these models. We start with models with F (x) = 0 (f(x) = 1).

For the simple g(x) in (3.9), we obtain for the potential at ϕ → ∞, using that ω2 ≪ 1,

V ≃ 9(n− 2)2λM4
Pl

[

1− 2ne
− 2ϕ

√

6MPl

]

, (4.1)

which means, in the parametrization of section 2, that a =
√

2/3 as in the Starobinsky

model, and c = 2n. That gives

ǫ ≃ 4n2

3
e
− 4ϕ

√

6MPl

η ≃ −4n

3
e
− 2ϕ

√

6MPl , (4.2)

and then ns − 1 ≃ 2η, r ≃ 16ǫ, but more relevantly we get

1− ns ≃ 2

Ne

r ≃ 3(ns − 1)2 ≃ 12

Ne
, (4.3)

exactly as in the Starobinsky model. As we saw for the parametrization in section 2,

we also have dns/d ln k ≃ (ns − 1)2/2 and A1/4 ≃ 10−2MPl, which translates now into

λ1/4
√

3(n− 2) ∼ 10−2.

A two-parameter generalization with

g(x) = ω2(1− xm) + xn , (4.4)

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reducing to the previous case for m = n, gives however still (4.1) at ϕ → ∞, so obtains

nothing new.

Another simple case with F (x) = 0 and

g(x) = ω2 + (1− ω2) sin
(π

2
xn
)

, (4.5)

that still satisfies the condition to interpolate between the Higgs potential and the infla-

tionary potential, gives for the potential at ϕ → ∞

V ≃ 36λ

(

1− n2π2

4
e
− 2φ

√

6MPl

)

. (4.6)

Then we have again a =
√

2/3 as in the Starobinsky model, but now c = n2π2/4. We get

therefore again the same Starobinsky model predictions r ≃ 3(1−ns)
2, 1−ns ≃ 2/Ne and

dns/d ln k ≃ (1− ns)
2/2. Again A1/4 ≃ 10−2MPl translates into

√
6λ1/4 ∼ 10−2.

Finally, consider an F (x) = cpx
p with p > 2 and g(x) in (3.9). Then the potential at

ϕ → ∞ is

V ≃ λM4
Pl9(n− 2)2(1 + cp)

[

1− 2

(

n+
p

1 + cp

)

e
− 2φ

√

6MPl

]

, (4.7)

so once again we obtain the predictions of the Starobinsky model.

We see that the predictions of these models are robust and generically give the same

as the Starobinsky model. The reason is that we have functions of φ/χ = tanh(ϕ/
√
6MPl)

which is ≃ 1 − 2e
− 2ϕ

√

6MPl at ϕ → ∞, so any well-defined Taylor expansion in φ/χ would

give the same a =
√

2/3.

In order to obtain a different a we need functions which have a somewhat singular

behaviour at φ/χ → 1. One obvious, yet somewhat unnatural example for the function

F (x) that would give a general a and preserves the Higgs potential at small ϕ would be

F (x) = cp

{

tanh

[

a

√

3

2
tanh−1(x)

]}p

, (4.8)

that gives at ϕ → ∞
F ≃ cp

[

1− 2pe
−a ϕ

MPl

]

. (4.9)

Note however that in the context of supergravity models, the resulting potential for ϕ can

easily appear (see e.g. [20], eq. 5.1). A more plausible example made up of only logs and

powers is

F (x) = cγ,p

[

ln

(

2

1 + xp

)]γ

. (4.10)

At ϕ → ∞ it gives

F ≃ cγ,pp
γe

−
√

2

3

γφ
MPl , (4.11)

which implies a general a = γ
√

2/3. Moreover, at ϕ → 0, we get

F ≃ cγ,p(ln 2)
γ

[

1− γ

ln 2

(

ϕ√
6MPl

)p]

, (4.12)

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so with p > 2 we don’t perturb the Higgs potential, and we just rescale the coupling

λ → λ[1 + cγ,p(ln 2)
γ ].

The general conditions on F (x) can be described as F (1 − x) ∝ xα1 and F (x) ≃
c1 + c2x

p, p > 2, for x → 0.

We note that with these F (x)’s, any normal g(x) like the ones given above would do

the job, since at ϕ, we need experimentally a ∼ 1/8, so the corrections coming from F (x)

would be leading with respect to the corrections coming from g(x), which have a =
√

2/3.

In conclusion, with not too singular functions g(x) and F (x) we obtain the predictions

of the Starobinsky model, but with ones with a more singular behaviour at x = 1 like for

instance (4.10) we can obtain the generalized Starobinsky model of section 2, with arbitrary

a, being able to fit the BICEP2 data with a ∼ 1/8.

Note that in this section we have been interested in models appearing naturally in the

conformal inflation from the Higgs, though from the point of view of general supergravity

models, one can obtain the generalized potential in section 2 from a Kähler potential for a

coset construction [19–21].

5 General coupling ξ and attractors

The exact SO(1, 1) symmetric model in the physical Jordan gauge is (3.5), and now consider

the deformation of the potential with the parametrization in terms of f̃ , g̃ in (3.7). The

action in physical Jordan gauge then becomes

S =

∫

d4x
√−g

[

M2
Pl

2
R

(

1− φ2

6M2
Pl

)

− 1

2
∂µφ∂

µφ−

−
(

f̃

(

φ√
6MPl

)

φ2 − g̃

(

φ√
6MPl

)

6M2
Pl

)2
]

. (5.1)

But we want to study the case of a general coupling ξ < 0 of the scalars to gravity ξφ2R,

away from the conformal coupling ξ = −1/6. For consistency we replace −φ2/(6M2
Pl) with

ξφ2/M2
Pl everywhere, to obtain

S =

∫

d4x
√−g

[

M2
Pl

2
R

(

1 + ξ
φ2

M2
Pl

)

− 1

2
∂µφ∂

µφ−

−36

(

f̃

(

√

|ξ|φ
MPl

)

ξφ2 + g̃

(

√

|ξ|φ
MPl

)

M2
Pl

)2


 . (5.2)

We can go to the Einstein frame gEµν = (1 + ξφ2)gµν and obtain

S =

∫

d4x
√−gE

[

M2
Pl

2
R[gE ]−

1

2

[

1 + ξφ2/M2
Pl + 6ξ2φ2/M2

Pl

(1 + ξφ2/M2
Pl)

2

]

gµνE ∇E
µ φ∇E

ν φ−

− 36(1 + ξφ2/M2
Pl)

2

(

f̃

(

√

|ξ|φ
MPl

)

ξφ2 + g̃

(

√

|ξ|φ
MPl

)

M2
Pl

)2


 ; (5.3)

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and define a canonical scalar field ϕ by

dϕ

dφ
=

√

1 + ξφ2/M2
Pl + 6ξ2φ2/M2

Pl

1 + ξφ2/M2
Pl

, (5.4)

to finally obtain the action

S =

∫

d4x
√−gE

[

M2
Pl

2
R[gE ]−

1

2
gµνE ∇E

µϕ∇E
ν ϕ−

− 36

(

f̃

(

√

|ξ|φ(ϕ)
MPl

)

ξφ2 + g̃

(

√

|ξ|φ(ϕ)
MPl

)

M2
Pl

)2


 . (5.5)

The potential is a function of

√
|ξ|φ(ϕ)

MPl
as in [1, 7], but of a form restricted by our conditions.

The analysis then follows in a similar way. If ξ is not extremely small such as to be able

to ignore the non-minimal coupling of the scalar to gravity, then inflation will occur at

ϕ → ∞, like in the ξ = −1/6 case, because of a plateau behaviour. From (5.4), this is seen

to be where 1 + ξφ2/M2
Pl ≪ 1, and in that region we obtain

dϕ

dφ
≃

√
6|ξ|φ/MPl

1 + ξφ2/M2
Pl

, (5.6)

solved by

φ2 =
M2

Pl

|ξ|

(

1− e
−
√

2

3

ϕ
MPl

)

. (5.7)

We see that this is again the same asymptotic functional form (except for the overall

constant) as in the conformal case ξ = −1/6, which as we explained in the last section

was the reason why we generically obtained the Starobinsky potential with a =
√

2/3, for

functions f(x) and g(x) that are not too singular at x = 1.

Therefore by the same arguments as in the previous sections we will obtain the

Starobinsky point also for this non-conformal ξ < 0. The only remaining issue is to define

the small value of ξ at which we can consider chaotic inflation. The argument in [1, 7]

can be carried over with little modifications. For a smooth potential function at φ = 0 we

can Taylor expand and thus consider only a quadratic potential V ≃ m2φ2/2 and chaotic

inflation for that, for which the number of e-folds is Ne = φ2/4M2
Pl, so for 60 e-folds we

obtain φ60 ≃ 15MPl. Then the condition to be able to ignore the non-minimal coupling

to gravity is if |ξ|φ2
60/M

2
Pl ≪ 1, so as to never need to reach the region (5.6). That gives

|ξ| ≪ 4 × 10−3. If however |ξ| ≫ 4 × 10−3, we are basically at the Starobinsky point.

Therefore the Starobinsky point is a strong attractor in terms of a nonzero ξ, with even a

small ξ driving us away from the chaotic inflation point towards the Starobinsky point.

In the case of functions f(x) and g(x) that are sufficiently singular at x = 1 to give

a potential with a general a, the same analysis follows. For |ξ| ≪ 4× 10−3 we can Taylor

expand the potential at φ = 0 and obtain chaotic inflation, but for |ξ| ≫ 4 × 10−3 we

obtain (5.7). Combined with the condition F (1− x) ∝ xα1 , we get in the inflation region

F

( |ξ|φ2

M2
Pl

)

∝ e
−
√

2

3

α1ϕ

MPl , (5.8)

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as before. So in the generalized Starobinsky case we also get a strong attractor behaviour

towards the generalized Starobinsky line, exactly as in the case of the Starobinsky point.

6 Conclusions

In this paper we have studied the possibility to have the Higgs field as the inflaton in a model

with local Weyl symmetry, where the Planck mass appears by fixing a gauge, and with

SO(1, 1) invariance at large field values (in the inflationary region). We have shown that in

these models, defined by two functions f(x) and g(x), generically we obtain the predictions

of the original Starobinsky model, but we can find functions that give a generalized version

of the Starobinsky model, for which we can obtain any value of the tensor to scalar ratio

of CMB fluctuations r, including the value of ∼ 0.2 preferred by BICEP2. The potential

is approximated in the inflationary region by a general exponentially-corrected plateau,

which can be obtained from a generalized form of the Starobinsky model, with an infinite

series of Rp corrections that sum to a function f(R).

The functions f(x) and g(x) were analyzed from the point of view of needing to in-

terpolate between the inflationary region and the Higgs potential, and in the inflationary

region should arise in a consistent quantum gravity theory. Of course, specific functions

would arise in the case of specific models, that would describe in particular how does the

SO(1, 1) invariance get broken at low energies, but we did not attempt here to construct

such models. That is left for future work. If we modify the non-minimal coupling ξ of the

scalar to gravity away from the conformal point, the Starobinsky line is a strong attractor,

as in the original Starobinsky point, so it seems that the local Weyl invariance is not really

essential to the inflationary predictions.

Note. While this paper was being written, the paper [25] appeared, which also discusses

the possibility of deforming the SO(1, 1) symmetry in a more general way. We would like to

thank the referee for pointing out to us references [18], where the general potential (2.10)

was analyzed, and [19–21], where it was obtained in the context of supergravity models.

We have been instead focusing on getting this potential from the conformal inflation from

the Higgs.

Acknowledgments

We would like to thank Rogerio Rosenfeld for many enlightning discussions and useful

comments on the manuscript. We would also like to thank Eduardo Pontón for discussions.

The work of HN is supported in part by CNPq grant 301219/2010-9 and FAPESP grant

2013/14152-7, and RC is supported by CAPES.

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.

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	Introduction
	Starobinsky models and a general class of potentials
	Class of models with Weyl invariance and approximate SO(1,1) invariance, reducing to Higgs
	Inflation in these models
	General coupling xi and attractors
	Conclusions