Higgs Scalaron Mixed Inflation

We discuss the inflationary dynamics of a system with a non-minimal coupling between the Higgs and the Ricci scalar as well as a Ricci scalar squared term. There are two scalar modes in this system, i.e. the Higgs and the spin-zero mode of the graviton, or the scalaron. We study the two-field dynamics of the Higgs and the scalaron during inflation, and clarify the condition where inflation is dominated by the Higgs/scalaron. We also find that the cut-off scale at around the vacuum is as large as the Planck scale, and hence there is no unitarity issue, although there is a constraint on the couplings from the perturbativity of the theory at around the vacuum.


I. INTRODUCTION
After the observation of the cosmic microwave background (CMB) anisotropy, inflation plays a central role in the modern cosmology. It is usually assumed that inflation is caused by potential energy of a scalar field, or the inflaton, but there is no candidate within the standard model (SM). Hence we need to go beyond the SM to cause inflation. Among a variety of such inflation models, the Higgs-inflation [1][2][3] and the R 2 -inflation [4][5][6][7] models are intriguing because of their minimality as well as consistency with the CMB observation. In the Higgs-inflation model, the SM Higgs boson plays the role of the inflaton thanks to a large non-minimal coupling to the Ricci scalar. In the R 2 -inflation model, a spin-zero component of the metric (or the scaralon) obtains a kinetic term and plays the role of the inflaton once we introduce a Ricci scalar squared term in the action. It is known that both models predict a similar value of the spectral index which is in good agreement with the Planck observation [8]. It is also attractive that both models predict the tensor-to-scalar ratio that may be detectable in the future CMB experiment (CMB-S4) [9].
In the actual analysis of these models, it is sometimes assumed that the Higgs or the scalaron is the only scalar degree of freedom during inflation. In reality, however, the Higgs must always be there even if we consider the R 2 -inflation model. In addition, if we consider the Higgs-inflation model, the large non-minimal coupling of the Higgs to the Ricci scalar may radiatively induce a large Ricci scalar squared term [10,11] that makes the scalaron dynamical as well. Hence it is more realistic to consider the dynamics of both the Higgs and the scalaron simultaneously. ♠1 In this paper we will thus study the Higgs-scalaron two-field inflationary dynamics, ♠2 and derive the parameter dependence of the inflationary predictions in our system. We will clarify the quantitative condition where inflation is dominated by the Higgs or the scalaron. In addition, we will address the unitarity structure of our system, which is much different from that of the ♠1 A similar study with an additional scalar field instead of the scalaron with a non-minimal coupling to the Ricci scalar has been performed in literature. See, e.g. Refs. [12][13][14][15][16][17][18][19][20][21] and references therein. ♠2 An analysis in this direction is also performed in Ref. [10,22] although some aspects we discuss in this paper such as the unitarity/perturbativity and the implication of the electroweak vacuum metastability are not addressed there. See also Refs. [23][24][25][26][27][28] as other treatments.
Higgs-inflation. The organization of this paper is as follows. In Sec. II, we discuss the inflationary dynamics of the Higgs-scalaron twofield system. We first study the dynamics analytically, and later confirm it by numerical calculation. In Sec. III, we study the unitarity structure of this system. We find that the cut-off scale of our system is as large as the Planck scale, which is similar to the case of the R 2 -inflation rather than the Higgsinflation. In Sec. IV, we concentrate on the dynamics of the Higgs when the electroweak (EW) vacuum is metastable. The last section V is devoted to the summary and discussions.

II. INFLATIONARY DYNAMICS
In this section, we study the two-field dynamics of the Higgs and the scalaron during inflation.

A. Action in Jordan/Einstein frame
We start from the following action in the Jordan frame: where g Jµν is the metric (with the "almost-plus" convention), g J is the determinant of the metric, R J is the Ricci scalar, M P is the reduced Planck mass and h is the Higgs in the unitary gauge. We add the subscript J for the quantities in the Jordan frame. We consider only the case In particular, we concentrate on the case ξ s > 0 since otherwise there is a tachyonic mode. On the other hand, we do not specify the signs of ξ h and λ h . Concerning the sign of λ h , the current measurement of the top and Higgs masses indicates that it becomes negative at a high energy region, resulting in the metastable EW vacuum [29][30][31][32][33][34][35][36][37][38][39][40][41][42], although the stable EW vacuum is also still allowed. In view of this, we consider both λ h > 0 and λ h < 0 in this paper.
By introducing an auxiliary field s, the action (1) is rewritten as [6,43] Note that the variation with respect to s gives and we restore the original action (1) after substituting it to Eq. (3). The field s corresponds to a spin-zero mode of the graviton that is dynamical due to the presence of the Ricci scalar squared term. We call it a "scalaron" in this paper. First we perform the Weyl transformation to obtain the action in the Einstein frame. We define the metric in the Einstein frame as The Ricci scalar is transformed as where R and are the Ricci scalar and the d'Alembert operator constructed from g µν , respectively. The action now reads where the potential in the Einstein frame is given by We define a new field φ as It corresponds to the inflaton degree of freedom in our system. By eliminating s in terms of φ , we finally obtain where the potential now reads and we have defined This is the master action in our system. Note that so far we have not used any approximation. In the following, we study the inflationary dynamics of this action in the Einstein frame.

B. Two-field dynamics
Now we study the inflationary dynamics of the action (10). An analysis for a similar system is performed in Ref. [13], and we follow that procedure here. The action (10) contains the kinetic mixing term between φ and h, and hence we define the following field τ to solve the mixing: Note that τ = 0 corresponds to the pure Higgs-inflation, while τ = ∞ corresponds to the pure R 2 -inflation. The kinetic terms now read Since we are interested in the inflationary dynamics, we concentrate on the case in this section. Then, the kinetic terms are approximated as Note that τ satisfies when the condition (15) is satisfied, and hence the kinetic term of τ has a correct sign. In the following we assume which is true for h M P . ♠4 Then after defining the canonically normalized field τ c as the kinetic mixing term between φ and τ c is suppressed by 1/ ξ h + ξ s τ. Therefore, to the leading order in it, we can approximate the kinetic term as There is no kinetic mixing between φ and τ to the zero-th order in 1/ ξ h + ξ s τ. Armed with these diagonalized fields, we now study the structure of the potential, which is expressed as To the leading order in Eq. (15), its derivative gives Note that we take the derivative with respect to τ c , not τ.
Hence the extrema are where we have defined In particular, τ = 0 is not an extremum of the potential. It means that the pure Higgs-inflation is never realized in our system, although the pure R 2 -inflation is possible. Nevertheless, there is some parameter region where inflation is caused mostly by the Higgs as we will see below.
In order to be the inflationary trajectory, these extrema must be minima of the potential. The second derivative at each extremum is given by Note again that we take the derivative with respect to τ c , not τ.

H i g g s -i n f l a t i o n l i k e n o n -p e r t u r b a t i v e
Schematic picture of the parameter region in the case (a). The inflaton is dominated by the scalaron for ξ 2 h /λ h ξ s (the red region), while it is dominated by the Higgs for ξ 2 h /λ h ξ s (the blue region). The yellow band corresponds to the parameter region consistent with the CMB observation. If ξ 2 h /ξ s 4π (the black region), the UV theory is non-perturbative so that we might not obtain the standard model effective theory even below the energy scale of the inflaton mass. For more details on this point, see Sec. III.
is the minimum for ξ h ξ s > 0. Also, the potential at the minimum must be positive to cause inflation. The potential at each extremum is given by The former is always positive in the case of our interest, while the latter together with Eq. (18) gives a non-trivial constraint on the parameters. In fact, Eq. (18) in particular means and hence we obtain the condition by combining the requirement that Eq. (28) is positive. Thus, the trajectory with τ = τ min causes inflation only if ξ h > 0 and λ h > 0. Note that we consider only the case ξ s > 0. ♠5 In summary, there are three cases that are relevant for inflation: (a) ξ h > 0, ξ s > 0 and λ h > 0, (b) ξ h < 0, ξ s > 0 and λ h > 0, and (c) ξ h < 0, ξ s > 0 and λ h < 0. From now we mainly concentrate on the case (a) since τ = τ min is the minimum only in this case. We briefly comment on the case (b) in the end of this subsection. The case (c) is also interesting since it corresponds to the metastable EW vacuum. Hence we discuss the case (c) in detail in Sec. IV. In this case, the potential minimum for τ is given by and hence the inflaton φ is a mixture of the Higgs and the scalaron. We first assume that τ sits at this minimum during inflation. Later we will see that this assumption is actually valid. Recalling that τ = s/h 2 , for ξ h ξ s τ min , the inflaton is dominated by the Higgs, while in the other limit, it is mostly composed of the scalaron. Thus, the situation is as follows: ♠6 λ h ξ s ξ 2 h : Higgs-inflation like, It is also seen from the potential. The potential for τ = τ min is given by and hence it is the same as the Higgs-inflation for λ h ξ s ξ 2 h , while the same as the R 2 -inflation for λ h ξ s ξ 2 h . In the intermediate case, the inflaton is a mixture of the Higgs and the scalaron, which we call a "Higgs scalaron mixed inflation." In order to reproduce the normalization of the CMB anisotropy, the parameters should satisfy [8] It is well-known that this type of model is in good agreement with the spectral index observed by the CMB experiments. In Fig. 1, we show the schematic picture of the parameter region in the case (a). Now we investigate the assumption that τ sits at the minimum of its potential during inflation. It is valid if the mass squared of τ c at around the minimum ∼ ξ h M 2 P /ξ s (see Eq. (26)) is much larger than the Hubble parameter squared during inflation H 2 inf . The ratio is estimated as Thus, τ sits at the minimum of its potential during inflation as long as ξ h 1 is satisfied, which is the case of our interest, and hence we have verified our assumption. It means that the inflationary dynamics effectively reduces to a single field case, whose potential is given by Eq. (33). ♠6 A similar condition is obtained for a scale invariant model with an additional dilaton field in Ref. [46]. It may be reasonable because the theory is almost scale invariant in our case as long as we consider the inflationary dynamics. It is also consistent with the rough estimation in Ref. [47].
In this case, the potential minimum for τ is and hence inflation is caused solely by the scalaron. Actually, the potential is given by which is nothing but the potential of the R 2 -inflation model. It is consistent with the CMB for ξ s 2 × 10 9 [8].

C. Numerical confirmation
In this subsection, we perform numerical calculation to confirm the analysis in the previous subsection. In particular, we numerically study the case (a), or the Higgs scalaron mixed inflation case. While some approximations are used in the previous subsection, we emphasize that we use no approximation in this subsection. More explicitly, we directly solve the background equations of motion derived from the action (10), which read where the potential is Here we take the background metric in the Einstein frame to be the Friedmann-Lemaître-Robertson-Walker (FLRW) one without spatial curvature, H is the Hubble parameter and the dots denote the derivatives with respect to the time. For the convenience of readers, we write down the explicit forms of the derivatives of the potential: Actually, these equations of motion are redundant, and hence we have used the last one (41) to check the consistency of Here φ ini and h ini are the initial field values of the inflaton and Higgs, respectively. We take the initial velocities of the fields as zero. τ starts to oscillate when ξ h M 2 P t 2 /ξ s ∼ 1. After hundreds or thousands of oscillations τ eventually settles down to its potential minimum τ min . Note that it happens within a few e-foldings because of the inequality (35), and hence τ has almost no effect on the inflationary dynamics. our numerical calculation. We have numerically solved the first three equations of motion, and checked that Eq. (41) is satisfied at least better than 10 −5 level.
In Fig. 2, we show the time evolution of τ. The blue line corresponds to our numerical calculation, while the red dashed line is τ min given in Eq. (24). The top panel corresponds to the Higgs-inflation like case, while the bottom one does to the R 2 -inflation like case. See the caption for more details on the parameters and the initial conditions. As we can see from the figures, after hundreds or thousands of oscillations τ eventually settles down to its potential minimum. It happens within a few e-foldings, and hence τ has almost no effect on the inflationary dynamics at all. This result confirms our analysis in the previous subsection. In Fig. 3, we also show the inflationary dynamics in the Higgs-scalaron field space. The blue line again corresponds to our numerical calculation, while the red dashed line is the φ direction that is orthogonal to the τ direction. We can see that the fields os- The x-axis is the Higgs squared h 2 , and the y-axis is the scalaron s calculated from φ and h. We take M P = 1 in this plot. The blue line is our numerical calculation, while the red dashed line is the direction of φ that is orthogonal to τ. We take the parameters as follows. Top: ξ s = 5×10 8 , ξ 2 h = 2×10 7 , λ h = 0.01, φ ini = 6 M P , and h ini = 10 −2 M P (Higgs-inflation like). Bottom: ξ s = 2 × 10 9 , ξ 2 h = 5 × 10 6 , λ h = 0.01, φ ini = 6 M P , and h ini = 0.05 M P (R 2 -inflation like). Here φ ini and h ini are the initial field values of the inflaton and Higgs, respectively. We have taken the initial velocities of the fields as zero. We have followed the inflationary dynamics until M P t = 2 × 10 7 . The two fields oscillate very frequently in the τ direction at first, but soon τ settles down to its potential minimum τ min , and the two field dynamics follows the trajectory of φ , which is expressed by the red line. For the time evolution of τ, see Fig. 2. cillate in the τ direction at first, but after τ settles down to its potential minimum, the system follows the trajectory of φ . Thus, it is again consistent with our analytical treatment in the previous subsection. In summary, we have verified that our analysis in the previous subsection well describes the actual inflationary dynamics of the present system.

III. CUT-OFF SCALE AND PERTURBATIVITY
In this section, we discuss the cut-off scale and the perturbativity of our model at around the vacuum. Note that the discussion in this section holds for all the cases (a), (b) and (c). We start our discussion with the exact action in the Einstein frame (10). The minimum of the potential (11) is at (φ , h) = (0, 0), so we expand the action around that point: where we have defined the Higgs quartic coupling in the original ultraviolet (UV) theory and the inflaton mass squared as ♠7 Neglected terms are suppressed by higher powers of M P . Thus, recalling that χ = 2/3 φ /M P , we can see that the cut-off scale of our model is as high as the Planck scale. It is in contrast to the case of the Higgs-inflation, where a power counting argument ♠8 suggests that the cut-off scale Λ cut;h at around the vacuum is of O(M P /ξ h ) [52][53][54][55][56]. ♠9 Rather, our model is similar to the case of the R 2 -inflation. In the R 2 -model, the cut-off scale is the Planck scale because the scalaron is just an auxiliary field in the Jordan frame, and hence it can absorb the large non-minimal coupling with the curvature [55,56]. Similarly in our case, the scalaron absorbs the large non-minimal couplings ξ s and ξ h so that it can avoid the unitarity issue. An interesting point of our model is that, Higgs can be the dominant component of the inflaton while keeping the cut-off to be the Planck scale.
Still, there is a constraint on the parameters if we require the theory to be perturbative. In order to see this, let us keep only ♠7 Although λ UV is shifted due to the mixing between φ and h, it does not help to stabilize the EW vacuum for λ h < 0. This is because the CMB observation fixes m φ ∼ 10 13 GeV, which is much higher than the instability scale of the Higgs potential [48,49]. Note that inflation is dominated by the scalaron for λ h < 0, and hence m φ is fixed. ♠8 Analysis beyond the power counting might change the situation [50,51]. ♠9 It does not necessarily mean an inconsistency of the Higgs-inflation during inflation [57] although the unitarity can be broken during the inflaton oscillation epoch [58]. See, e.g. Refs. [47,59,60] for construction of a UV completed model and also Refs. [61,62] for the discussion of UV effects on the Higgs-inflation. the renormalizable terms in the action at around the vacuum: The Higgs quartic coupling in our system is λ UV , and hence it should be smaller than ∼ 4π for the theory to be perturbative. Thus, we may require the following condition: ♠10 otherwise it is unreasonable to use the tree-level potential such as Eq. (48). It means that the theory with non-zero ξ s is qualitatively different from that with ξ s = 0 even if we take the limit ξ s → 0 because of the presence of the scalaron. Once we have the scalaron degree of freedom, we need Eq. (49) to keep the theory perturbative at around the vacuum, while there is no such a constraint if ξ s = 0 from the beginning. It might be interesting to see that Eq. (49) requires the inflaton mass as where the right-hand-side is the cut-off scale of the Higgs inflation model at around the vacuum. Since we consider the case |ξ h | 1, the inflaton-Higgs quartic coupling is always in the perturbative region once Eq. (49) is satisfied. We should note that the perturbativity of our system is important to safely obtain the SM at the energy scale below m φ . In order to see this point, we now derive the infrared (IR) theory from our system (or the UV theory) below the energy scale of m φ . We may define the IR theory as Then, λ IR may be determined by matching, e.g. the scattering process hh → hh in the IR and UV theories. ♠11 If the UV and IR theories are perturbative, we may obtain λ IR = λ h by comparing the tree level processes in the IR and UV theories. For more details on this point, see App. B. Thus, the IR theory is nothing but the SM with the Higgs quartic coupling given by λ h . If the UV theory is strongly coupled, however, the tree-level matching does not make sense. We need to sum an infinite numbers of diagrams to calculate the scattering, which is a complicated task. Moreover, it is even non-trivial whether the Higgs remains as an asymptotic state, and the IR theory might be totally different from the one described by Eq. (51). Therefore it is at least secure to consider only the parameter region ξ 2 h /ξ s 4π.
♠ 10 We implicitly assume |λ h | O(0.1). ♠11 We consider only the degrees of freedom of h and φ for simplicity.
We now study the dynamics of the Higgs during and after inflation. During inflation, the potential minimum for τ is and hence it corresponds to the usual R 2 -inflation. In this case, as long as |ξ h | 1, the Higgs stays at h = 0 during inflation since τ is heavy enough (see Eq. (25)). It is nothing but the stabilization mechanism discussed, e.g. in Refs. [35,[63][64][65][66]. It is well-known that the EW vacuum metastability has some tension with high-scale inflation models including the R 2 -inflation if there is no coupling between the inflaton and the Higgs sectors [35,65,[67][68][69][70][71][72]. However, once we introduce couplings between the inflaton and/or the Ricci scalar and the Higgs, the EW vacuum is stabilized during inflation since they induce an effective mass of the Higgs. Here we have explicitly shown that such a stabilization mechanism does work for the R 2 -inflation model.
After inflation, however, resonant Higgs production typically occurs due to the inflaton oscillation, and hence the EW vacuum may be destabilized during the preheating epoch [73][74][75][76][77]. Here we consider the dynamics of the Higgs after inflation in our system. Soon after inflation ends, the φ 3 and φ 4 terms as well as the Planck suppressed terms become negligible due to the cosmic expansion. In the same way, the Higgs-inflaton quartic coupling becomes less important than the Higgs-inflaton trilinear coupling. Therefore we may approximate the action as There are two cases depending on the sign of λ UV . If λ UV is negative, or ξ 2 h < |λ h |ξ s , this system is studied in Ref. [76,77]. ♠12 In this case, the so-called tachyonic preheating occurs since the effective mass squared of the Higgs oscillates between positive and negative values [78]. As a result, the EW vacuum is destabilized during the preheating epoch if the trilinear coupling satisfies [76,77] ♠12 Actually in that study they also include the positive Higgs-inflaton quartic coupling, but the trilinear coupling eventually becomes more important than the quartic coupling, so we can safely apply their result to our system.
In order to prevent such a catastrophe, ξ h must satisfy Note that the Higgs-inflaton quartic coupling makes things even worse in our case since it contributes negatively to the effective mass squared of the Higgs for ξ h < 0. If λ UV is positive, or ξ 2 h > |λ h |ξ s , the situation is more complicated. The direction φ = 0 considered in Refs. [73][74][75][76][77] is absolutely stable in this case. Nevertheless, the potential has an unstable direction φ = ξ h h 2 /M P (or more precisely e χ − 1 = ξ h h 2 /M P ) since λ h is negative. Fluctuations in this direction might be enhanced since the inflaton inevitably couples to this direction. Hence it might be possible that the EW vacuum is destabilized even in this case for large enough |ξ h |, although we leave a detailed study as a future work.

V. SUMMARY AND DISCUSSIONS
In this paper, we have considered the inflationary dynamics of a system with the non-minimal coupling between the Higgs and the Ricci scalar ξ h h 2 R as well as the Ricci scalar squared term ξ s R 2 . In such a system, there are two scalar degrees of freedom, i.e. the Higgs and the scalar part of the metric, or the scalaron. We have shown that inflation successfully occurs in the following three cases: (a) ξ h > 0, ξ s > 0 and λ h > 0, (b) ξ h < 0, ξ s > 0 and λ h > 0, and (c) ξ h < 0, ξ s > 0 and λ h < 0, where λ h is the Higgs quartic coupling in the Jordan frame. We have seen that in every case the inflationary dynamics effectively reduces to a single field one since the direction orthogonal to the inflaton is heavy enough for |ξ h | 1. In particular, in the case (a), the inflaton is a mixture of the Higgs and the scalaron, which we call a Higgs scalaron mixed inflation. The inflaton potential in this case is given by where φ is the inflaton and M P is the reduced Planck mass, and hence it is consistent well with the CMB observation as long as ξ 2 h /λ h + ξ s 2 × 10 9 . We have also addressed the unitarity structure of our system at around the vacuum, and found that the cut-off scale is as large as the Planck scale. This is in contrast to the Higgs-inflation where the cut-off scale at around the vacuum is M P /ξ h M P . Rather, it is similar to the R 2 -inflation. Still, the parameters must satisfy ξ 2 h /ξ s 4π if we require the perturbativity of our system, and hence the inflaton mass should be less than ∼ M P /ξ h .
Finally we have briefly discussed the implications of the metastable EW vacuum to the R 2 -inflation. We have explicitly shown that if |ξ h | 1, the EW vacuum is not destabilized during inflation albeit it is metastable. Still, however, it is possible that the EW vacuum is destabilized during the inflaton oscillation epoch due to a resonant enhancement of the Higgs quanta. In order to avoid such a catastrophe, we might require |ξ h | O(10), although the situation is unclear when |ξ h | is large enough so that ξ 2 h |λ h |ξ s . It may be interesting to study further on this respect.
We have several remarks. First of all, although we have mainly concentrated on the inflationary dynamics in this paper, the (p)reheating dynamics after inflation is also important. The inflationary predictions of our system depend on the reheating temperature thorough the number of e-foldings. Actually, it is the dynamics after inflation that makes the differences of the inflationary predictions between the Higgs-and R 2 -inflation [79]. We leave a detailed study of the reheating dynamics as a future work.
Related to the reheating dynamics, we point out the difference of our system to the Higgs inflation during the inflaton oscillation epoch. In general, if there is a large non-minimal coupling between the inflaton and the Ricci scalar (without a scalaron) as in the Higgs-inflation, the inflaton dynamics shows a peculiar behavior called a "spike"-like feature during the inflaton oscillation epoch [58,[80][81][82], which was not taken into account in the previous studies [83,84]. ♠13 In the Jordan frame, this is because the kinetic term of the inflaton (or the Higgs) suddenly changes when the inflaton passes the points |φ | ∼ M P /ξ h , which has some influence even in the Einstein frame. In particular, if the inflaton is gauge-charged such as the Higgs, longitudinal gauge bosons with extremely high-momentum ∼ λ h M P are efficiently produced at the first oscillation so that the unitarity may be violated [58].
Here it is essential to note that the longitudinal gauge boson mass is different from the transverse gauge boson one if the symmetry breaking field (the Higgs in our case) is timedependent [58,85,86]. In our case with the scalaron, however, such a violent phenomena does not occur thanks to the presence of the scalaron. Thus, we can trust our system from inflation until the present universe.
It is also valuable to note that some Higgs condensation is unavoidably produced in the Higgs scalaron mixed inflation case even if the Higgs is sub-dominant. The amplitude of the Higgs condensation at the beginning of the inflaton oscillation is estimated for the Higgs sub-dominant case as follows. During inflation, the ratio s/h 2 is fixed to be λ h /ξ h , and hence The left-hand-side is of order unity at the beginning of the inflaton oscillation, and thus the amplitude of the Higgs condensation at that time is estimated as where we substitute ξ s 2 × 10 9 from the CMB observation in the last similarity. Although the dynamics of the Higgs ♠13 Actually there is a comment on the energy scale ∼ λ h M P related to this spike-like feature in Sec. 3.4 in Ref. [83]. Nevertheless, possible effects on the preheating dynamics are underestimated there.
condensation after inflation is non-trivial due to the couplings to the inflaton, it might have some phenomenological consequences such as the spontaneous leptogenesis [87] and the gravitational wave [88,89]. Note that in our case the Higgs has no isocurvature perturbation as opposed to the case considered in Refs [90][91][92][93] since τ is massive during inflation.
Note Added: While finalizing this paper, another paper [94] was submitted to the arXiv that calculated the curvature perturbation in the same system.

ACKNOWLEDGMENTS
YE thanks Kazunori Nakayama for useful discussions. YE also acknowledges Oleg Lebedev and the members of the theoretical high energy physics group in the University of Helsinki for their hospitality, where some part of this work was done. This work was supported by the JSPS Research Fellowships for Young Scientists and the Program for Leading Graduate Schools, MEXT, Japan.

Appendix A: Redundancy of dual description
In this appendix, we comment on redundancy of dual description of Eq. (1). Instead of Eq. (3), we may consider the following action: where the parameters ξ h , ξ s , ξ s and λ h are in general different from ξ h , ξ s and λ h . As long as they satisfy the action (A1) reproduces Eq. (1) after integrating out the scalaron s, and hence they are actually redundant. This redundancy corresponds to the shift and the rescaling of the scalaron s, and the physics does not depend on this ambiguity of the dual description. We can also see this in the Einstein frame. By following the same procedure we obtained Eq. (10), we can show that the Einstein frame action obtained from Eq. (A1) is exactly Eq. (10) thanks to Eq. (A2). In the main text, we have chosen the parameters as which of course satisfy Eq. (A2).

Appendix B: Matching
In this appendix, we explain how to obtain the relation λ IR = λ h . In order to express the coupling in the IR theory in terms of those in the UV theory, we may compare the treelevel scattering amplitude of the process hh → hh. The corresponding diagrams in the IR and UV theories are shown in Fig. 4. In the IR theory, the tree-level amplitude is given by where the numerical factor comes from the permutation of the external Higgs particles. In the UV theory, it is given by where the second term comes from the inflaton-Higgs trilinear coupling with s,t and u being the Mandelstam variables. In the last line, we have taken only leading order terms in O(k 2 /m 2 φ ) with k being the typical momentum of the scattering. Thus, by matching the scattering amplitude, we obtain Note that this procedure is reasonable only when the IR and UV theories are perturbative.