Abstract
Using a completely covariant approach, we discuss the role of boundary conditions (BCs) and the corresponding Gibbons–Hawking–York (GHY) terms in \( f ( R ) \)-gravity in arbitrary dimensions. Following the Ostrogradsky approach, we can introduce a scalar field in the framework of Brans–Dicke formalism to the system to have consistent BCs by considering appropriate GHY terms. In addition to the Dirichlet BC, the GHY terms for both Neumann and two types of mixed BCs are derived. We show the remarkable result that the \(f( R )\)-gravity is itself compatible with one type of mixed BCs, in D dimension, i.e. it doesn’t require any GHY term. For each BC, we rewrite the GHY term in terms of Arnowit–Deser–Misner (ADM) variables.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
1 Introduction
Since the theory of general relativity (GR) is a classical field theory of gravitation, the choice of BCs is of great importance. The role of surface integrals in GR has been investigated first in Dewitt and Dirac’s papers [1, 2] and then was covered deeply in the works of York [3] and Regge and Teitelboim [4]. Trying to quantize GR in path integral formalism, Gibbons and Hawking [5] showed that, a boundary term should be added to the Einstein–Hilbert (EH) action, in order to have a well-defined variational principle with Dirichlet BC, i.e. \( \delta g_{ab}|_{\textit{ Boundary}}=0 \). Such terms, added to the EH action, or the action of generalized theories of gravity [6,7,8,9,10,11,12], are called GHY terms which are used for for finite volume spaces. For non-compact spaces like asymptotically Minkowski or Ads, the variational problem needs extra boundary terms in addition to the GHY term since it depends on the specific asymptotic form of the space-time [13].
The theory of GR is described by a degenerate Lagrangian, i.e. it can be written as the sum of a quadratic part in the first derivatives of metric and a total derivative term. There are two approaches to deal with GR. The first one is the well-known ADM formalism which uses the Gauss–Codazzi equation to get rid of the second derivative terms of the Lagrangian [5, 7, 8, 14]. The second one, which is more covariant, manifests the quadratic Lagrangian by subtracting a suitable boundary term which can be removed by adding a GHY term [15, 16].
For modified gravity models such as \(f( R )\)-gravity, which is non-degenerate, one needs to use the so-called Ostrogradsky approach [17], by introducing enough number of fields to the theory such that the whole Lagrangian includes at most the first derivatives of the fields. In this way one is able to go through a canonical approach and at the same time introduce consistent BCs. For \(f( R )\)-gravity without considering additional fields, one needs to consider the extrinsic curvature variation \(\delta K_{ij}\), as well as \(\delta g_{ij}\) to vanish on the boundary, which is inconsistent since extrinsic curvature \( K_{ij}\), includes derivatives of the metric. However, by adding the famous GHY term \( - 2\int _{\partial {\mathcal {M}}}d^{D-1}y\epsilon \sqrt{h} f'(R)\delta K \) [h and K are the trace of induced metric and the extrinsic curvature respectively, \( \epsilon =\pm 1 \) depending on the timelike or spacelike nature of the boundary \( \partial {\mathcal {M}} \) and \( f'(R)=\frac{\partial f}{\partial R} \)] to the action, the BCs reduce to vanish \(\delta R\) on the boundary simultaneously with the Dirichlet BC. But calculating \(\delta R\) (see Appendix C) shows that the main problem is not resolved since R is not an independent field and its variation includes again variations of the derivatives of the metric.
In this paper we try in Sect. 2 to change f(R) Lagrangian into a degenerate one by Ostrogradsky approach. To do so, we write the \( f( R ) \)-gravity in the Jordan frame of the Brans–Dicke action [18,19,20]. We find that the action of the theory is degenerate. Hence, by adding appropriate GHY terms, Dirichlet or other BCs can be achieved. Writing the boundary terms of the action in terms of fields and momentum fields, in a foliation independent approach, enables us to introduce the consistent GHY term for Dirichlet, Neumann and two types of mixed BCs in arbitrary dimensions. For one type of mixed BC, the GHY term vanishes. This may be interpreted that the \(f( R )\)-gravity is more consistent with this mixed type of BC in D dimension.
In this paper the Latin indices are used to show the space-time coordinates and the Greek ones are used to denote the space coordinates. The calculations are done in arbitrary dimensions of space-time and the signature of metric is (\(-,+,+,+\)).
2 \(f( R )\)-gravity
The action of GR is holographic [15, 16], i.e. there is a relation between the surface and bulk terms as following:
where
As can be seen, it can be written as a quadratic Lagrangian plus a total derivative term [15, 16]. Unlike the GR Lagrangian, \( f( R ) \)-gravity given by
seems to be non-degenerate.Footnote 1 Varying the above action and integrating by part, without implying any BC, we haveFootnote 2
where
is the equation of motion. \(\Pi _{ij}=\epsilon \sqrt{h}( K _{ij}- K h_{ij})\) is the momentum conjugate to \( h^{ij} \) in GR and \( n_i \) is the normal vector of the boundary. As can be seen, to obtain the equations of motion, imposing the Dirichlet BC,Footnote 3 we can get rid of the first surface integral in the above equation. To remove the second surface integral, the usual GHY boundary term can be added to the action (3) as follows
Varying the above action gives
Hence, to get the equations of motion, we need to impose \(\delta R|_{\textit{ Boundary}}=0 \), in addition to \( \delta h^{ij}|_{\textit{ Boundary}}=0 \). In Appendix C, we have shown that \(\delta R\) is a combination of variations \( \delta h^{ij} , \delta K_{ij}, \delta n^i, \nabla _i \delta K \) and \( \delta (\nabla _a \nabla _i n^a ) \). Now we can ask if \( \delta R|_{\textit{ Boundary}}=0 \) is compatible with the Dirichlet BC?
To answer this question we need to define, in a consistent way, the momenta conjugate to the field variables in order to distinguish the Dirichlet and Neumann BCs where the momentum fields vanish on the boundary. However, this can be done only for degenerate theories, where the bulk term of Lagrangian contains at most the first order derivatives of the fields. Noting Ostrogradsky approach [17], we should change the \( f( R ) \) Lagrangian into a degenerate one as much as possible. To do so, using scalar-tensor formulation, by introducing an scalar field \( \phi \), we write \( f( R ) \) action as follows:
in which \( \phi =f'( R ) \), \( V(\phi )= R (\phi )\phi -f( R (\phi )) \) and we have assumed that \( f''(R)\ne 0 \). Now substituting the relation (1) in the above action, we have
The first integral contains only the metric, its first order derivatives and the scalar field \( \phi \). Integrating by parts, this is also the case for the second integral, and thus the above Lagrangian is degenerate. To see this, let us rewrite Eq. (9) as follows
where
and \( {\mathcal {M}}^{iabpqr} \) is defined in Eq. (2). Note that \( P ^{ab}\equiv \partial (\sqrt{-g}{\mathcal {L}}_{\textit{ quad}})/\partial (\partial _{0} g_{ab})\) is the canonical momentum of \( g_{ab} \) in GR. Hereafter we have also assumed that \( \partial {\mathcal {M}} \) contains two spacelike \((D-1)\)-dimensional surfaces at \( t=\text {constant} \) and one timelike surface on which the integral vanishes at large spatial distances. Now we are able to define the canonical momenta of \( \phi \) and \( g_{ab} \) as follows
and
where \( P = g_{ab} P ^{ab} \) and we have used the following relation
Considering the action (10), one can see that, regardless of the surface integral which is a GHY term, the Lagrangian contains fields and their first order derivatives. Therefore, we can be sure that the variational principle for this action is compatible with the Dirichlet BC. Before investigating in details the compatibility of the model, let us show explicitly the structure of the added GHY term in the ADM formalism. Consider the following relation
where \(n^a=N^{-1}(1,-N^\alpha )\) and the lapse and shift functions are denoted by N and \( N^{\alpha }.\)Footnote 4 In the last equality we have used the following two identities
Substituting the expression (14) into (10) gives
where the first surface integral in (17), is the same as GHY term of Refs. [6,7,8]. However, the second surface term is often lost in the literatures. We will come back to this point in the next subsection.
Now let us consider the variations of the action (10). First, we rewrite it in terms of the momenta given in Eqs. (11) and (12). By adding (and subtracting) the following surface integral
to (and from) the action (10), we get
Varying this action with respect to \( \phi \) and \( g_{ab} \) and using Eq. (13), after a little algebra, we obtain
where
and
in which
and \( H ^{iabkl} \equiv \partial M ^{iab}/\partial g_{kl} \). Substituting (21) and (22) in (20) gives
As expected, without the GHY term, the undesirable BCs: \( \delta g_{ab}|_{\textit{ Boundary}}=\delta {{\bar{P}}}_{ab}|_{\textit{ Boundary}}= \delta \phi |_{\textit{ Boundary}}=\delta (\partial ^0 \phi )|_{\textit{ Boundary}}=0\) should be assigned. In order to find the appropriate GHY term, let us discuss three different types of BCs leading to a consistent stationary action principle for \( f ( R )\)-gravity.
2.1 Dirichlet BC
Considering the surface terms in Eq. (39), in order to impose the Dirichlet BC: \( \delta g_{ab}|_{\textit{ Boundary}}=\delta \phi |_{\textit{ Boundary}}=0 \), we need to modify the action (19) by adding the following GHY term
To see that the above action is compatible with the Dirichlet BC, let us vary it as follows
which gives the equation of motion subjected the Dirichlet BC. Note that \( \phi =f'(R) \) gives \( \delta \phi |_{\textit{ Boundary}}=f''(R)\delta R|_{\textit{ Boundary}}=0\). Now we can surely say that \( \delta R|_{\textit{ Boundary}}=0 \) is compatible with the Dirichlet BC and is in fact part of it. This is a clear covariant verification of the result pointed in Ref. [7] in the framework of the ADM foliation. To be more concrete, we can determine the GHY term \(S_{\textit{ D}} ^{\textit{ GHY}}\) in terms of ADM variables. Using (14) and substituting \( \phi = f'(R) \), we have
which are the same terms present in Eq. (17). According to the Dirichlet BC, \(\delta R|_{\textit{ Boundary}}=\delta h_{ab}|_{\textit{ Boundary}}= \delta N^\mu |_{\textit{ Boundary}}=\delta N|_{\textit{ Boundary}}=0 \), the last term of the above equation can be neglected and the first term suffices [6,7,8, 15]. However, note that this is correct only for the Dirichlet BC.
To complete our discussion, we can set \( \phi =1 \) and \( V(\phi )=0 \) in Eq. (24) to find the following result for the case of GR
where
Imposing the Dirichlet BC: \( \delta g_{ab}|_{\textit{ Boundary}}=0 \), the action should be modified by the following GHY term to get the equations of motion,
Moreover, using Eq. (14), we can rewrite \( S _{\textit{ D(EH)}} ^{\textit{ GHY}}\) in the familiar form
where for the Dirichlet BC, the second term can be neglected [21].
2.2 Neumann BC
In order to obtain the GHY term related to the Neumann BC: \( \delta {\bar{P}}^{ab}|_{\textit{ Boundary}}=\delta {\bar{P}}_\phi |_{\textit{ Boundary}}=0 \), let us write (24) in a different form. From (11) and (12), we find that
Inserting this into (24) gives
This shows that the action (19) is consistent with the Neumann BC if we propose the following GHY term
Variation of (33) yields
which gives the equations of motion using Neumann BC.
Using (14) and inserting \( \phi =f'(R) \), we can write the GHY term in (33) in the ADM formalism as
It should be noted that unlike the case of Dirichlet BC, the second term in the above action can not be neglected unless for the coordinate system in which \( N^{\alpha }=0 \). It is worth to compare (35) with the GHY term (27) for Dirichlet BC. It is easily seen that
2.3 Mixed BC
There are two types of mixed BCs for f(R)-gravity: \( \delta {\bar{P}}_{ab}|_{\textit{ Boundary}}=\delta \phi |_{\textit{ Boundary}}=0\) or \( \delta {\bar{P}}_\phi |_{\textit{ Boundary}}=\delta g_{ab}|_{\textit{ Boundary}}=0\). We begin with the first one. Using the variation of f(R)-gravity action, (24) or (32), the first type mixed BC would be consistent if we have added the following GHY term to the action
Varying the above action gives
As can be seen, the mixed BC: \( \delta {{\bar{P}}}_{ab}|_{\textit{ Boundary}}=\delta \phi |_{\textit{ Boundary}}=0 \) yields consistently the equations of motion. Now using Eq. (14) and \( \phi =f'(R) \), we can write the GHY term of Eq. (37) in terms of ADM variables as
It is also worth noting here to find the relation between Dirichlet and the above mixed GHY boundary terms in f(R) -gravity. Comparing the above result with that obtained in Eq. (27), we see that
For GR, i.e. \( \phi =1 \) and \( V(\phi )=0 \), it is interesting that the newly defined action (37) is consistent with the Neumann BC
This shows that the pure Neumann BC may be used for GR in arbitrary dimensions. To clarify more, using Eq. (14), it is easy to see that the above GHY term with respect to the ADM variables takes the form
where again the second term in the above action or in (39), can be ignored only for the special choice of coordinate system mentioned in the previous subsection. Also, it can be easily seen that, in GR, in contrast to the Dirichlet case, the required GHY term, compatible with the Neumann BC, depends on the dimension of space-time and for \( D=4 \), the coefficient of GHY term vanishes. Thus there is no need to any GHY term in order to have a consistent theory. This point, explained here covariantly is also shown recently in Ref. [14] in ADM approach. Another interesting feature is the relation between Dirichlet and Neumann GHY term in GR. Comparing Eqs. (30) and (42), one finds
Now let us look at the second type of mixed BC: \( \delta {\bar{P}}_\phi |_{\textit{ Boundary}}=\delta g^{ab}|_{\textit{ Boundary}}=0 \). In order to discuss the consistency of \( f ( R )\)-gravity with this BC, first we use (31) to substitute for \(g_{ab}\delta {\bar{P}}^{ab} \) in (24). This leads to
Clearly by applying the BC: \( \delta {\bar{P}}_{\phi }|_{\textit{ Boundary}}=\delta g_{ab}|_{\textit{ Boundary}}=0 \), we can get the equations of motion without adding any GHY term to the above expression. This means that f(R)-gravity with the above type of mixed BC is self-consistent with no need to any GHY term in D dimension. To clarify this point better, let us return to the relation (4) in which the boundary terms are written in the ADM formalism. One can write these terms in term of the momenta conjugate to \( \phi \), \( h_{ij} \), N and \( N^\alpha \). These are derived in details in appendix D and are as follows
Substituting this into (4) and inserting \( \phi =f'(R) \), we obtain
where \( h^{ij}\delta n_i =-n_i\delta h^{ij}\) is used. It can be seen that the above surface terms, which are written in the ADM formalism, are completely in agreement with what we have derived by the covariant approach in (44). Regarding the above relation and by applying the mixed BC: \( \delta {\bar{\Pi }}_\phi |_{\textit{ Boundary}}=\delta n_i|_{\textit{ Boundary}}=\delta h^{ij}|_{\textit{ Boundary}}=0 \), we can get the equations of motion in D dimension without any GHY term.
3 Conclusion
In this paper it is shown that unlike GR, the action of \( f( R ) \)-gravity is not holographic such as the action of Lanczos–Lovelock theory. Moreover, the Lagrangian of \( f( R ) \)-gravity can not be expressed as the sum of quadratic and total derivative terms. So \( f( R ) \) Lagrangian is not degenerate. Following the Ostrogradsky approach, since \( f( R ) \)-gravity is a theory with higher order derivatives of metric, it carries a single additional degree of freedom, which is the scalar field of equivalent Brans–Dicke action. Introducing this field, leads to a degenerate Lagrangian which is used to develop the problem of BC and the corresponding GHY terms in \( f( R ) \)-gravity [7, 8].
Here we have followed a foliation independent approach to find the GHY boundary terms in \( f( R ) \)-gravity, required to make the BC variation problem well-defined. We have shown that in addition to the Dirichlet BC, the Neumann BC and two types of the mixed BCs can be introduced for the \(f( R )\)-gravity. The remarkable point which is one of the main results of this paper is about the mixed BCs. We have shown that one of the mixed BC: \( \delta {\bar{P}}_{ab}|_{\textit{ Boundary}}=\delta \phi |_{\textit{ Boundary}}=0\) is reduced to the Neumann BC in the case of GR. This BC together the other mixed BC: \(\delta {\bar{P}}_\phi |_{\textit{ Boundary}}=\delta g^{ab}|_{\textit{ Boundary}}=0\) are self-consistent BCs, i.e. these do not need to any GHY term to be consistent with the theory, the first one for GR and the second one for \(f( R )\)-gravity, both in D dimension.
Notes
This point is explicitly shown in Appendix A.
For a detailed calculations see Appendix B.
In GR, Dirichlet BC means, \( \delta g_{ab}|_{\textit{ Boundary}}=0 \). Since \(g_{ab}= h_{ab}+\epsilon n_a n_b\), it follows that \( \delta h_{ab}|_{\textit{ Boundary}}= \delta n^i|_{\textit{ Boundary}}=0 \).
Thus in the ADM formulation of \(f( R )\) gravity, the Dirichlet BC means \( \delta h^{ab}|_{\textit{ Boundary}}= \delta N^\mu |_{\textit{ Boundary}}=\delta N|_{\textit{ Boundary}}=\delta \phi |_{\textit{ Boundary}}=0 \).
References
P.A.M. Dirac, Phys. Rev. 114, 924 (1959)
B.S. Dewitt, Phys. Rev. 160, 1113 (1967)
J.W. York Jr., Phys. Rev. Lett. 28, 1082 (1972)
T. Regge, C. Teiltelboim, Ann. Phys. 88, 286–318 (1974)
G.W. Gibbons, S.W. Hawking, Phys. Rev. D 15, 2752 (1977)
I. Papadimitriou, JHEP 0705, 075 (2007)
E. Dyer, K. Hinterbichler, Phys. Rev. D 79, 024028 (2009)
A. Guarnizo, C. Leonardo, J.M. Tejeiro, Gen. Relativ. Gravit. 42, 2713 (2010)
R.C. Myers, Phys. Rev. D 36, 392 (1987)
N. Deruelle, J. Madore, arXiv:gr-qc/0305004
N. Deruelle, N. Merino, R. Olea, Phys. Rev. D 97, 104009 (2018)
C. Krishnan, K.V.P. Kumar, A. Raju, JHEP 10, 043 (2016)
I. Papadimitriou, K. Skenderis, JHEP 0508, 004 (2005)
C. Krishnan, R. Avinash, Mod. Phys. Lett. A 32, 1750077 (2017)
T. Padmanabhan, Gravitation: foundations and frontiers (Cambridge University Press, Cambridge, 2010)
A. Mukhopadhyay, T. Padmanabhan, Phys. Rev. D 74, 124023 (2006)
R.P. Woodard, Scholarpedia 10(8), 32243 (2015)
S. Capozziello, V. Faraoni, Beyond Einstein gravity a survey of gravitational, theories for cosmology and astrophysics (Springer, Berlin, 2011)
T.P. Sotiriou, Class. Quantum Gravity 23, 17 (2006)
V. Faraoni, Cosmology in scalar-tensor gravity (Springer Science and Business Media, Berlin, 2004)
E. Poisson, An advanced course in general relativity, lecture notes at University of Guelph (2002)
A. De Felice, S. Tsujikawa, Living Rev. Relativ. 13, 3 (2010)
T.P. Sotiriou, V. Faraoni, Rev. Mod. Phys. 82, 451–497 (2010)
K. Bhattacharya, B.R. Majhi, Phys. Rev. D 95, 064026 (2017)
I.D. Saltas, M. Hindmarsh, Class. Quantum Gravity 28, 035002 (2011)
Acknowledgements
The authors would like to thank the Iran National Science Foundation (INSF) for supporting this research under grant number 97015575. F. Shojai is grateful to the University of Tehran for supporting this work under a grant provided by the university research council.
Author information
Authors and Affiliations
Corresponding author
Appendices
A Non-degeneracy of \( f ( R ) \)-gravity
Let us to start from the \( f( R ) \) action in the scalar-tensor formulation
This is, in fact, the action of Brans–Dicke theory in the Jordan frame with parameter \( \omega =0 \) [19, 20, 22, 23]. As it is well-known, using the conformal transformation [20]:
the action (8A.1) changes to Einstein gravity minimally coupled to a scalar field. Thus, in the so-called Einstein frame, the separation of the Lagrangian into \( \text {bulk} \) and surface terms can be done. Hereafter all quantities in the Einstein frame are denoted by \( \sim \). Noting
and \( \sqrt{-{\tilde{g}}}=\phi ^{D/(D-2)}\sqrt{-g} \), we can find
where
in which \( U({\tilde{\phi }}(\phi ))=\frac{V(\phi )}{\phi ^{D/(D-2)}} \). Now we can separate the action of \( f( R ) \)-gravity into a quadratic \( \text {bulk} \) term and a surface term. To do this, let us recall that
where \( {\tilde{V}}^c={\tilde{g}}^{ik}{\tilde{\Gamma }}^c_{ik}-{\tilde{g}}^{ck}{\tilde{\Gamma }}^m_{mk} \) [15]. Hence, the \( \text {bulk} \) term of (A.5) in the Einstein frame reads
The second term of (A.6) is denoted as \(\tilde{{\mathcal {L}}}_{\text {Sur}}\) and leads to a surface term. Transforming back to the Jordan frame via Eq. (A.2), we obtain:
and
The above relations finally yield
where
and
in which \( V^c=g^{ik}\Gamma ^c_{ik}-g^{ck}\Gamma ^i_{ik} \) [24, 25].
Using Eqs. (A.11) and (A.12), a simple calculation shows
and
Inserting (A.13) and (A.14) into (A.10) and using \( \phi =f'( R ) \), finally one obtains
where
Considering relation (A.15), we see that the surface part of the Lagrangian is not determined completely by its bulk part. This is in contrast to EH Lagrangian, or more generally Lanczos–Lovelock Lagrangians [24]. Furthermore, the bulk Lagrangian in \( f( R ) \)-gravity is not necessarily a quadratic Lagrangian and contains an arbitrary function of the second order derivatives of metric. Hence, the \( f( R ) \) Lagrangian is not a degenerate Lagrangian.
B Variation of \( f( R ) \)-gravity action without BC
The variation of the action of \( f( R ) \)-gravity gives
The first integral includes some terms of the equations of motion. Using the contracted form of Palatini equation
and integrating by part in the second term of (B.17), we would have
Inserting (B.19) in (B.17), we get
Now we want to write the surface integral of (B.20) in ADM foliation of space-time. The first term gives
where \( D_i \) is the spatial-covariant derivative defined on \(\partial {\mathcal {M}}\), \( U^i\equiv n_jh^i_k\delta g^{jk} \) and for the first equality see [15]. The third term of (B.21) is zero assuming the manifold is compact in D-1 dimension. The last term can be written as
Then we have (B.21) as
Now let’s calculate the second term of surface integral in (B.20)
where \( h^a_jn^j=0 \), \( \delta n^j=\frac{1}{2}\epsilon n^jn_kn_e\delta g^{ke}+n_kn^j_{\ell } \delta g^{k\ell }\) and also \( \delta g^{ij}=\delta h^{ij}+\epsilon n^i\delta n^j+\epsilon n^j\delta n^i\) have been used. Eventually we can write the surface integrals of (B.20) as
Substituting (B.25) and (B.23) in (B.20), yields
where
C Variation of the scalar curvature
It is instructive to find what does the condition \( \delta R \mid _{\tiny { \text {Boundary}}}=0 \) mean. To answer this question, first let’s remind the Gauss–Codazzi equation:
where \( \epsilon =-1 \) and \({}^{(D-1)} R \) is the scalar curvature of the \((D-1)\)-dimensional subspace and in the first line \( a^i=n^a\nabla _an^i \) is the acceleration of the normal vector field. Then taking variation of (C.1), the Palatini identity is as follows
where the variation of spatial scalar curvature reads
As is obvious from (C.2) and (C.3), \( \delta R \) is a combination of \( \delta h^{mn},\delta n^i,\delta K ^{mn} \) \( ,\nabla _i(\delta K ),\delta (\nabla _a \nabla _i n^a) \) and spatial-covariant derivatives of \( \delta h^{mn} \).
D The conjugate momenta in f(R)-gravity
To find the conjugate momenta, we write the f(R) action in the Brans–Dicke form and then using (C.1), make it degenerate.
To do this, substituting the Gauss–Codazzi equation in D dimension, (C.1), into (8), we find that
By-part integration on the last term gives
where \( n_ia^i=0 \), \( n_in^i=\epsilon \) and \( D\phi \equiv n^i\nabla _i\phi \) have been used. Using following calculation
and \( n^i=(\frac{1}{N},\frac{-N^{\alpha }}{N}) \), we have
Substituting (D.6) and (D.7) into (D.5), we obtain
Now we can define the momenta conjugate to \( h_{\alpha \beta } \), N, \( N^{\alpha } \) and \( \phi \) as
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
Funded by SCOAP3
About this article
Cite this article
Khodabakhshi, H., Shojai, F. & Shirzad, A. On the classification of consistent boundary conditions for \( f ( R )\)-gravity. Eur. Phys. J. C 78, 1003 (2018). https://doi.org/10.1140/epjc/s10052-018-6494-5
Received:
Accepted:
Published:
DOI: https://doi.org/10.1140/epjc/s10052-018-6494-5