Emergent Supersymmetry in Warped Backgrounds

Emergent Supersymmetry in Warped Backgrounds

We show that quantum mechanical supersymmetries are emerged in Kaluza-Klein spectrum of linearized gravity in several warped backgrounds as a consequence of higher-dimensional general coordinate invariance. These emergent supersymmetries play an essential role for the spectral structure of braneworl...

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Hauptverfasser: Nagasawa, T., Ohya, S., Sakamoto, K., Sakamoto, M.
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Veröffentlicht: Інститут математики НАН України 2011
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spelling irk-123456789-1471842019-02-14T01:26:00Z Emergent Supersymmetry in Warped Backgrounds Nagasawa, T. Ohya, S. Sakamoto, K. Sakamoto, M. We show that quantum mechanical supersymmetries are emerged in Kaluza-Klein spectrum of linearized gravity in several warped backgrounds as a consequence of higher-dimensional general coordinate invariance. These emergent supersymmetries play an essential role for the spectral structure of braneworld gravity. We show that for the case of braneworld models with two codimension-1 branes the spectral pattern is completely determined only through the supersymmetries. 2011 Article Emergent Supersymmetry in Warped Backgrounds / T. Nagasawa, S. Ohya, K. Sakamoto, M. Sakamoto // Symmetry, Integrability and Geometry: Methods and Applications. — 2011. — Т. 7. — Бібліогр.: 17 назв. — англ. 1815-0659 2010 Mathematics Subject Classification: 81Q60 DOI:10.3842/SIGMA.2011.065 http://dspace.nbuv.gov.ua/handle/123456789/147184 en Symmetry, Integrability and Geometry: Methods and Applications Інститут математики НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description We show that quantum mechanical supersymmetries are emerged in Kaluza-Klein spectrum of linearized gravity in several warped backgrounds as a consequence of higher-dimensional general coordinate invariance. These emergent supersymmetries play an essential role for the spectral structure of braneworld gravity. We show that for the case of braneworld models with two codimension-1 branes the spectral pattern is completely determined only through the supersymmetries.
format Article
author Nagasawa, T.
Ohya, S.
Sakamoto, K.
Sakamoto, M.
spellingShingle Nagasawa, T.
Ohya, S.
Sakamoto, K.
Sakamoto, M.
Emergent Supersymmetry in Warped Backgrounds
Symmetry, Integrability and Geometry: Methods and Applications
author_facet Nagasawa, T.
Ohya, S.
Sakamoto, K.
Sakamoto, M.
author_sort Nagasawa, T.
title Emergent Supersymmetry in Warped Backgrounds
title_short Emergent Supersymmetry in Warped Backgrounds
title_full Emergent Supersymmetry in Warped Backgrounds
title_fullStr Emergent Supersymmetry in Warped Backgrounds
title_full_unstemmed Emergent Supersymmetry in Warped Backgrounds
title_sort emergent supersymmetry in warped backgrounds
publisher Інститут математики НАН України
publishDate 2011
url http://dspace.nbuv.gov.ua/handle/123456789/147184
citation_txt Emergent Supersymmetry in Warped Backgrounds / T. Nagasawa, S. Ohya, K. Sakamoto, M. Sakamoto // Symmetry, Integrability and Geometry: Methods and Applications. — 2011. — Т. 7. — Бібліогр.: 17 назв. — англ.
series Symmetry, Integrability and Geometry: Methods and Applications
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AT ohyas emergentsupersymmetryinwarpedbackgrounds
AT sakamotok emergentsupersymmetryinwarpedbackgrounds
AT sakamotom emergentsupersymmetryinwarpedbackgrounds
first_indexed 2025-07-11T01:33:42Z
last_indexed 2025-07-11T01:33:42Z
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fulltext Symmetry, Integrability and Geometry: Methods and Applications SIGMA 7 (2011), 065, 13 pages Emergent Supersymmetry in Warped Backgrounds Tomoaki NAGASAWA †1, Satoshi OHYA †2, Kazuki SAKAMOTO †3†4 and Makoto SAKAMOTO †4 †1 Tomakomai National College of Technology, 443 Nishikioka, Tomakomai 059-1275, Japan E-mail: nagasawa@gt.tomakomai-ct.ac.jp †2 INFN and Dipartimento di Fisica, Università di Pisa, Largo Bruno Pontecorvo 3, 56127 Pisa, Italy E-mail: satoshi.ohya@pi.infn.it †3 Present address: Materials Research Laboratory, Kobe Steel, Ltd., Japan †4 Department of Physics, Kobe University, 1-1 Rokkodai, Nada, Kobe 657-8501, Japan E-mail: dragon@kobe-u.ac.jp Received May 27, 2011; Published online July 11, 2011 doi:10.3842/SIGMA.2011.065 Abstract. We show that quantum mechanical supersymmetries are emerged in Kaluza– Klein spectrum of linearized gravity in several warped backgrounds as a consequence of higher-dimensional general coordinate invariance. These emergent supersymmetries play an essential role for the spectral structure of braneworld gravity. We show that for the case of braneworld models with two codimension-1 branes the spectral pattern is completely determined only through the supersymmetries. Key words: supersymmetry; boundary condition; extra dimension 2010 Mathematics Subject Classification: 81Q60 1 Introduction In this paper we extend our previous analysis [1, 2, 3] to a wider class of warped backgrounds including Randall–Sundrum model [4, 5] and Karch–Randall model [6]. We will show that higher-dimensional general coordinate invariance is again translated into the quantum mechani- cal supersymmetries in the spectrum. The hidden supersymmetry structures we wish to illumi- nate in this paper are: an N = 2 supersymmetry between graviton- and vector-modes; another N = 2 supersymmetry between vector- and scalar-modes (with constant shift of the origin of energy); and the second-order derivative supersymmetry between graviton- and scalar-modes (with constant shift of the origin of energy). Schematic view of this supersymmetry structure is as follows: (spin-0 mode) (spin-1 mode) (spin-2 mode) Q+ (01) Q− (01) -� Q+ (12) Q− (12) -� Q+ (02) ? Q− (02) 6 where Q+ (01), Q+ (12), Q−(01), Q−(12) are the first-order derivative supercharges and Q+ (02), Q−(02) the second-order derivative supercharges (see Section 3). Revealing the above supersymmetry structure in several warped backgrounds without matter, we then demonstrate its impacts on spectral pattern of braneworld gravity. mailto:nagasawa@gt.tomakomai-ct.ac.jp mailto:satoshi.ohya@pi.infn.it mailto:dragon@kobe-u.ac.jp http://dx.doi.org/10.3842/SIGMA.2011.065 2 T. Nagasawa, S. Ohya, K. Sakamoto and M. Sakamoto The rest of this paper is organized as follows. Section 2 is devoted to a quick review for the background warped geometries we use. In Section 3 we show that quantum mechanical super- symmetries generically emerge in the Kaluza–Klein mass eigenvalue problems as a consequence of higher-dimensional general coordinate invariance. In Section 4 we show that in braneworld gravity with two codimension-1 branes the spectral pattern of Kaluza–Klein modes is completely determined only through the supersymmetry structure. We conclude in Section 5. 2 Preliminary: background geometry In this paper we study linearized pure Einstein gravity on (d + 1)-dimensional warped back- grounds described by the following metric ds2 = GMN (x, z)dxMdxN = e2A(z) [ gµν(x)dxµdxν + dz2 ] , (1) where A(z) is the warp factor which turns out to play a role of superpotential (or prepotential) in analog supersymmetric quantum mechanics. In this section we recall the background geometries given as the classical solutions to the Einstein equation without matter with respect to the metric (1). (Throughout of this paper the spacetime dimension (d+ 1) is left arbitrary although in the phenomenological viewpoint we are interested in the case d = 4.) To begin with, let us start with the action. The bulk Einstein–Hilbert action that describes braneworld we wish to study is SEH = Md−1 ∫ ddx ∫ dz √ −G [ R(G)− d(d− 1)Λd+1 ] , where M is the mass scale of (d + 1)-dimensional gravity and Λd+1 is the (d + 1)-dimensional bulk cosmological constant. The factor d(d − 1) is introduced for later convenience. R(G) is the Ricci scalar curvature constructed from the background metric GMN . The integration range of z will be specified later. (Our conventions for the curvature tensor, Ricci tensor etc. are summarized in Appendix A.) As shown in Appendix A, the bulk Einstein equations are reduced to the following nonlinear equations for the warp factor: [A′(z)]2 −A′′(z) = Λd, (2) A′′(z)e−2A(z) = −Λd+1, (3) where prime (′) indicates the derivative with respect to z. Λd is the cosmological constant for the d-dimensional foliation of the bulk spacetime given by R(g) = d(d− 1)Λd, where R(g) is the Ricci scalar constructed from the metric gµν(x). We note that the differential equation (2) is nothing but the Riccati equation such that it can be linearized as (−∂2z + Λd)e −A(z) = 0. Thus, according to the sign of the cosmological constants Λd+1 and Λd, we obtain the following four types of the warp factors [6]: A(z) =  − log [ `d `d+1 sin ( z − z0 `d )] for Λd < 0 and Λd+1 < 0 (AdSd/AdSd+1), − log ( z − z0 `d+1 ) for Λd = 0 and Λd+1 < 0 (Md/AdSd+1), − log [ `d `d+1 sinh ( z − z0 `d )] for Λd > 0 and Λd+1 < 0 (dSd/AdSd+1), − log [ `d `d+1 cosh ( z − z0 `d )] for Λd > 0 and Λd+1 > 0 (dSd/dSd+1), (4) Emergent Supersymmetry in Warped Backgrounds 3 where z0 is the integration constant. `d+1 and `d are the curvature scale of bulk spacetime and its foliation, respectively, and given by `d+1 := 1√ |Λd+1| ≥ 0, `d := 1√ |Λd| ≥ 0. Now we are in a position to specify the range of coordinate z. First, without any loss of generality we can set z0 = 0 because it just corresponds to the choice of the origin. Then, according to the configuration of codimension-1 brane(s), the range of z should be chosen as follows: • Two zero-thickness branes: z ∈  (z1, z2), 0 < z1 < z2 < π`d, for AdSd/AdSd+1, (z1, z2), 0 < z1 < z2 <∞, for Md/AdSd+1 (Randall–Sundrum I [4]), (z1, z2), 0 < z1 < z2 <∞, for dSd/AdSd+1, (z1, z2), −∞ < z1 < z2 <∞, for dSd/dSd+1. (5) • A single zero-thickness brane: z ∈  (z1, π`d), 0 < z1 < π`d, for AdSd/AdSd+1 (Karch–Randall [6]), (z1,∞), 0 < z1 <∞, for Md/AdSd+1 (Randall–Sundrum II [5]), (z1,∞), 0 < z1 <∞, for dSd/AdSd+1 (Karch–Randall [6]), (z1,∞), −∞ < z1 <∞, for dSd/dSd+1. • Without zero-thickness brane: z ∈  (0, π`d), for pure AdSd/AdSd+1, (0,∞), for pure Md/AdSd+1, (0,∞), for pure dSd/AdSd+1, (−∞,∞), for pure dSd/dSd+1. Each brane configuration has its own advantage such as a candidate to the solution of hierar- chy problem [4] or alternative scenario to compactification as a consequence of localization of massless graviton mode at the brane position [5, 6]. Irrespective of these brane configurations, there always exists supersymmetry structure in the spectrum of dimensional reduced theory. For the sake of simplicity, however, in what follows we will concentrate ourselves to the case of two branes configuration (5) in order to discretize the spectrum. The case of pure AdSd/AdSd+1 is briefly discussed in Appendix B. 3 From general coordinate invariance to quantum mechanical supersymmetry Supersymmetry structure in braneworld gravity has been already pointed out by several authors and used to analyze the Kaluza–Klein spectrum [7, 8, 9]. However, all of these analysis are just based on one of two N = 2 supersymmetries between graviton- and vector-modes. Whole supersymmetry structure has not yet been uncovered. In this section we show that quantum mechanical supersymmetries generically emerge as a consequence of (d+ 1)-dimensional general coordinate invariance. 4 T. Nagasawa, S. Ohya, K. Sakamoto and M. Sakamoto To begin with, let us consider metric fluctuations hMN around the background metric (1) as follows ds2 = e2A(z) [gMN (x) + hMN (x, z)] dxMdxN . The most useful parameterization of hMN is turned out to be of the form hMN = ( hµν − 1 d−2gµνφ hµz hzν φ ) . Under the infinitesimal coordinate transformation xM 7→ x̂M = xM + ξM (x, z), the metric fluctuations transform, at the linearized level, as hMN (x, z) 7→ ĥMN (x, z) = hMN (x, z) + δhMN (x, z), where δhµν = −∇µξν −∇νξµ − 2 d− 2 gµν ( ∂z + (d− 1)A′ ) ξz, (6) δhµz = −∂zξµ −∇µξz, (7) δφ = −2 ( ∂z +A′ ) ξz. (8) Here ∇µ is the covariant derivative with respect to the background metric gµν(x). As we will show below, the linearized general coordinate transformations (6)–(8) are translated into the supersymmetry transformations on the mode functions. To see this, let us first suppose that the metric fluctuations are expanded into some complete orthogonal basis {f (n)0 (z)}, {f (n)1 (z)} and {f (n)2 (z)}, which are determined later, and written as follows hµν(x, z) = ∑ n h(n)µν (x)f (n) 2 (z), (9) hµz(x, z) = ∑ n h(n)µz (x)f (n) 1 (z), (10) φ(x, z) = ∑ n φ(n)(x)f (n) 0 (z). (11) If one wants to study braneworld models with non-compact extra dimension, contributions from the continuum spectrum must be added. The supersymmetry structure we wish to show below is, however, independent of whether the spectrum is discrete or continuum. Now let us move on to the analysis of supersymmetry structure between vector- and graviton- modes. Since the covariant derivative ∇µ is blind for the coordinate z, the first two terms of the gauge transformation (6) implies that the gauge parameter ξµ(x, z) should be expanded by the same basis to hµν such that it should be written as ξµ(x, z) = ∑ n ξ (n) µ (x)f (n) 2 (z). Then, in order to be consistent with the first term of the gauge transformation (7), ∂zf (n) 2 must be proportional to f (n) 1 . Thus we are led to the following relation: A−1 f (n) 2 (z) = mnf (n) 1 (z) with A−1 := ∂z, (12) where mn is just a proportional coefficient here. Next, according to the second term of the gauge transformation (7), we see that the gauge parameter ξz(x, z) should be expanded by the same basis to hµz such that it must be written as ξz(x, z) = ∑ n ξ (n) z (x)f (n) 1 (z). Then, according to the last term of the gauge transformation (6), we conclude that −(∂z + (d− 1)A′)f (n)1 must be proportional to f (n) 2 : A+ 1 f (n) 1 (z) = mnf (n) 2 (z) with A+ 1 := − ( ∂z + (d− 1)A′ ) , (13) Emergent Supersymmetry in Warped Backgrounds 5 where we have used the fact that without any loss of generality we can use the same coefficient as (12). These two equations lead to the following eigenvalue equations H1f (n) 1 (z) = m2 nf (n) 1 (z) with H1 := A−1 A + 1 = −∂z ( ∂z + (d− 1)A′ ) , (14) H2f (n) 2 (z) = m2 nf (n) 2 (z) with H2 := A+ 1 A − 1 = − ( ∂z + (d− 1)A′ ) ∂z. (15) As we will show in the next section, A+ 1 and A−1 are hermitian conjugate to each other. Now it is obvious that there exists an N = 2 quantum mechanical supersymmetry structure. Indeed, by introducing the following operators H(12) = ( H1 0 0 H2 ) = ( A−1 A + 1 0 0 A+ 1 A − 1 ) , Q+ (12) = ( 0 0 A+ 1 0 ) , Q−(12) = ( 0 A−1 0 0 ) , which act on the two-component vector (f1(z), f2(z)) T (where T stands for transposition), we have the N = 2 supersymmetry algebra {Q+ (12),Q − (12)} = H(12), {Q+ (12),Q + (12)} = {Q−(12),Q − (12)} = 0, [H(12),Q+ (12)] = [H(12),Q−(12)] = 0. Let us proceed to find another N = 2 supersymmetry structure between vector- and scalar- modes. The gauge transformation (8) implies that (∂z + A′)f (n)1 must be proportional to f (n) 0 . Thus we must have the following relation A−0 f (n) 1 (z) = m̄nf (n) 0 (z) with A−0 := ∂z +A′, (16) where at this stage m̄n is introduced as a coefficient that is independent of mn. A crucial step is to note the following identity of differential operators H1 = −∂z ( ∂z + (d− 1)A′ ) = − ( ∂z + (d− 2)A′ ) (∂z +A′) + (d− 2)Λd, (17) where in the last equality we have used the background Einstein equation (2). Combining the equation (17) and the eigenvalue equation (14), we get the following relation m̄nA+ 0 f (n) 0 (z) = [m2 n − (d− 2)Λd]f (n) 1 (z) with A+ 0 := − ( ∂z + (d− 2)A′ ) . (18) Now without any loss of generality we can set the coefficient m̄n as m̄n = √ m2 n − (d− 2)Λd. Multiplying the differential operator (∂z +A′) to (18) we get the following eigenvalue equation H0f (n) 0 (z) = m2 nf (n) 0 (z) with H0 := A−0 A + 0 + (d− 2)Λd. (19) Now it is obvious that there exists another N = 2 quantum mechanical supersymmetry structure. Indeed, by introducing the following operators H(01) = ( H0 0 0 H1 ) = ( A−0 A + 0 0 0 A+ 0 A − 0 ) + (d− 2)ΛdI, Q+ (01) = ( 0 0 A+ 0 0 ) , Q−(01) = ( 0 A−0 0 0 ) , which act on the two-component vector (f0(z), f1(z)) T , we have the following algebra {Q+ (01),Q − (01)} = H(01) − (d− 2)ΛdI, {Q+ (01),Q + (01)} = {Q−(01),Q − (01)} = 0, 6 T. Nagasawa, S. Ohya, K. Sakamoto and M. Sakamoto [H(01),Q+ (01)] = [H(01),Q−(01)] = 0. This is the N = 2 supersymmetry algebra but the origin of energy is shifted by the constant (d− 2)Λd. Let us finally study supersymmetry structure between scalar- and graviton-modes. As was discussed in [1, 2] for the case of the Randall–Sundrum background, the symmetry that guar- antees two-fold degeneracy between scalar- and graviton-modes is the second-order derivative supersymmetry, which is a nonlinear extension of ordinary N = 2 supersymmetry discussed by [10, 11, 12, 13]. Indeed, by introducing the operators H(02) = ( H0 0 0 H2 ) = ( A−0 A + 0 + (d− 2)Λd 0 0 A+ 1 A − 1 ) , Q+ (02) = ( 0 0 A+ 1 A + 0 0 ) , Q−(02) = ( 0 A−0 A − 1 0 0 ) , which act on the two-component vector (f0(z), f2(z)) T , we have the second-order derivative supersymmetry algebra [10, 11, 12, 13] {Q+ (02),Q − (02)} = H(02) ( H(02) − (d− 2)ΛdI ) , (20) {Q+ (02),Q + (02)} = {Q−(02),Q − (02)} = 0, [H(02),Q+ (02)] = [H(02),Q−(02)] = 0, where (20) follows from the intertwining relation A−1 A + 1 −A + 0 A − 0 = (d− 2)Λd. (21) Note that this intertwining relation is valid only for the warp factor that satisfies the background Einstein equation (2). To summarize, we have shown that linearized general coordinate transformations reduce to the supersymmetry relations (12), (13), (16), (18) for the mode functions f (n) 0 , f (n) 1 and f (n) 2 . In order for the consistency with the general coordinate invariance these mode functions must be the eigenfunctions of the Hamiltonians H0, H1 and H2 and have the same eigenvalues (up to the zero-modes; see next section). An important point to note is that the eigenvalue equations (14), (15), (19) can be derived without referring equations of motion: it just follows from the general coordinate invariance. Another important point to note is that the warp factor A(z) must be tuned to satisfy the background Einstein equation (2), otherwise the refactorization (17) and intertwining relation (21) becomes incomplete such that the three-fold degeneracy in the spectrum will be disappeared. Although in this paper we will not solve the Schrödinger equa- tions, for the sake of completeness we summarized the corresponding Schrödinger Hamiltonians in Appendix C. 4 Spectral pattern of two branes models Supersymmetry structure severely restricts the spectral structure of the model. Indeed, as we will show below, spectral pattern of two branes model is completely determined by the super- symmetry. To see this, we first have to specify the boundary conditions at the positions of branes. Boundary conditions should be chosen to respect i) hermiticity of each Hamiltonian Hs (s = 0, 1, 2) and ii) supersymmetry relations1. The former requirement guarantees the com- pleteness as well as the orthogonality of the set of eigenfunctions {f (n)s (z)} (s = 0, 1, 2) such 1It should be noted that in the present case the notion of hermiticity is associated to the inner product (fs, gs) := ∫ z2 z1 dz e(d−1)A(z)fs(z)gs(z), (22) Emergent Supersymmetry in Warped Backgrounds 7 that it justifies the mode expansions (9)–(11). It also ensures the reality of the spectrum. The latter requirement, on the other hand, guarantees the (d + 1)-dimensional general coordinate invariance of the theory. As discussed in [2, 3, 14], boundary conditions that satisfy these two requirements are uniquely determined and given by (A+ 0 f0)(zi) = 0, (23) f1(zi) = 0, (24) (A−1 f2)(zi) = 0, zi = z1, z2. (25) Other choices of boundary conditions (say, f0(zi) = 0, f1(zi) = 0 and f2(zi) = 0) are not consistent with the supersymmetries and hence leads to the breakdown of three-fold degeneracy of the spectrum, or, equivalently, breakdown of (d+1)-dimensional general coordinate invariance. An important point to note is that with these boundary conditions the spectrum of Hs (s = 0, 1, 2) are bounded from below. To see this, let fs be a normalized eigenfunction of Hs satisfying the eigenvalue equation Hsfs = Esfs. Then we have 0 ≤ ‖A−1 f2‖ 2 = (A−1 f2,A − 1 f2) = (f2,A+ 1 A − 1 f2) = (f2, H2f2) = E2, (26) 0 ≤ ‖A+ 1 f1‖ 2 = (A+ 1 f1,A + 1 f1) = (f1,A−1 A + 1 f1) = (f1, H1f1) = E1, (27) 0 ≤ ‖A−0 f1‖ 2 = (A−0 f1,A − 0 f1) = (f1,A+ 0 A − 0 f1) = (f1, [H1 − (d− 2)Λd]f1) = E1 − (d− 2)Λd, (28) 0 ≤ ‖A+ 0 f0‖ 2 = (A+ 0 f0,A + 0 f0) = (f0,A−0 A + 0 f0) = (f0, [H0 − (d− 2)Λd]f0) = E0 − (d− 2)Λd, (29) where the second equalities of each line follow from the partial integration and boundary con- ditions (23)–(25), and the third equalities the definitions of the Hamiltonians. Thus we obtain the following bound of the spectrum: E2 ≥ 0, E1 ≥ { 0 for Λd ≤ 0, (d− 2)Λd for Λd > 0, E0 ≥ (d− 2)Λd =: m2 −1. As is evident from the expressions (26)–(29), the lower bounds are saturated by the zero-modes of differential operators A−1 , A+ 1 , A−0 and A+ 0 , and given as the solutions to the first-order differential equations A−1 f (0) 2 (z) = 0 for E2 = 0, A+ 1 f (0) 1 (z) = 0 for E1 = 0, A−0 f (0) 1 (z) = 0 for E1 = (d − 2)Λd and A+ 0 f (0) 0 (z) = 0 for E0 = (d − 2)Λd. These differential equations are easily solved with the results f (0) 2 (z) ∝ const for E2 = 0, f (0) 1 (z) ∝ { e−(d−1)A(z) for E1 = 0 (Λd ≤ 0), e−A(z) for E1 = (d− 2)Λd (Λd > 0), (30) f (0) 0 (z) ∝ e−(d−2)A(z) for E0 = (d− 2)Λd. (31) Notice that in both cases Λd ≤ 0 and Λd > 0 the mode function (30) does not satisfy the boundary condition (24) in the two branes models. Thus the vector zero-mode must be thrown away, as it should in a respect that translational symmetry along z-direction is broken due to the presence of boundaries. Since the spectrum must be discretized (because z-direction is compact) where fs, gs are square integrable functions on the interval (z1, z2). Notice that the weight factor e(d−1)A(z) comes from e(d+1)A(z) ⊂ √ −G times e−2A(z) ⊂ GMNRMN (G) in the Einstein–Hilbert action. The hermiticity requirement is then (fs, Hsgs) = (Hsfs, gs) for any fs, gs. 8 T. Nagasawa, S. Ohya, K. Sakamoto and M. Sakamoto →← →← →← →← m2 m2 0 = 0 m2 −1 m2 1 m2 2 ... f (0) 0 f (1) 0 f (2) 0 f (1) 1 f (2) 1 f (0) 2 f (1) 2 f (2) 2 →← →← →← →← m2 m2 0 = 0 m2 1 m2 2 ... f (0) 0 f (1) 0 f (2) 0 f (1) 1 f (2) 1 f (0) 2 f (1) 2 f (2) 2 →← →← →← →← m2 m2 0 = 0 m2 −1 m2 1 m2 2 ... f (0) 0 f (1) 0 f (2) 0 f (1) 1 f (2) 1 f (0) 2 f (1) 2 f (2) 2 (a) Case Λd < 0 (AdSd). (b) Case Λd = 0 (Md). (c) Case Λd > 0 (dSd). Figure 1. Spectral pattern of two branes models. Black dots and white circles represent physical and unphysical degrees of freedom, respectively. Up to the ground states f (0) 2 and f (0) 0 the spectrum exhibits three-fold degeneracy. It should be emphasized that m2 −1 = (d − 2)Λd does not directly give the radion mass; see equation (32). and further triply degenerate up to these zero-modes {f (0)2 , f (0) 0 }, the mode expansions should become hµν(x, z) = h(0)µν (x)f (0) 2 (z) + ∞∑ n=1 h(n)µν (x)f (n) 2 (z), hµz(x, z) = 0 + ∞∑ n=1 h(n)µz (x)f (n) 1 (z), φ(x, z) = φ(0)(x)f (0) 0 (z) + ∞∑ n=1 φ(n)(x)f (n) 0 (z), for metric fluctuations, and, for gauge parameters, ξµ(x, z) = ξ(0)µ (x)f (0) 2 (z) + ∞∑ n=1 ξ(n)µ (x)f (n) 2 (z), ξz(x, z) = 0 + ∞∑ n=1 ξ(n)z (x)f (n) 1 (z), where the non-zero Kaluza–Klein modes {f (n)2 , f (n) 1 , f (n) 0 | n ≥ 1} form the supersymmetry multiplets as discussed in the previous section, and share the same mass eigenvalue, Hsf (n) s = m2 nf (n) s . The resultant spectral pattern is depicted in Fig. 1. Unitary gauge. Now we are in a position to see the particle content of the theory and check its mass spectrum. To this end let us go to the coordinate frame of unitary gauge. In terms of the Kaluza–Klein modes the gauge transformations (6)–(8) read ĥ(n)µν (x) = h(n)µν (x)−∇µξ(n)ν (x)−∇νξ(n)µ (x) + 2 d− 2 gµν(x)mnξ (n) z (x), ĥ(n)µz (x) = h(n)µz (x)−mnξ (n) µ (x)−∇µξ(n)z (x), φ̂(n)(x) = φ(n)(x)− 2m̄nξ (n) z (x), for the non-zero Kaluza–Klein modes (n ≥ 1), and ĥ(0)µν (x) = h(0)µν (x)−∇µξ(0)ν (x)−∇νξ(0)µ (x), φ̂(0)(x) = φ(0)(x), for the zero-modes (n = 0). By moving to the coordinate frame by choosing ξ(n)z (x) = 1 2m̄n φ(n)(x), n ≥ 1, Emergent Supersymmetry in Warped Backgrounds 9 ξ(n)µ (x) = 1 mn h(n)µz (x)− 1 2mnm̄n ∇µφ(n)(x), n ≥ 1, the non-zero vector- and scalar-modes are all gauged away, φ̂(n)(x) = 0 and ĥ (n) µz (x) = 0, n ≥ 1. In this coordinate frame we are left with the infinite tower of massive graviton modes ĥ(n)µν (x) = h(n)µν (x)− 1 mn ∇µh(n)νz (x)− 1 mn ∇νh(n)µz (x) + 1 mnm̄n ∇µ∇νφ(n)(x) + 1 d− 2 mn m̄n gµν(x)φ(n)(x), n ≥ 1, and the massless graviton mode ĥ (0) µν and the radion mode φ̂(0). These are physical degrees of freedom and turn out to satisfy the following equations of motions[ 4(2) L +m2 n − 2(d− 1)Λd ] ĥ(n)µν (x) = 0, ∇µĥ(n)µν = gµνh(n)µν = 0,[ 4(0) L +m2 −1 − 2(d− 1)Λd ] φ̂(0)(x) = 0, where 4(0,2) L is the Lichnerowicz operator given by 4(2) L hµν = −2dhµν + [∇λ,∇µ]hλν + [∇λ,∇ν ]hµ λ = −2dhµν − 2Rµρνσ(g)hρσ +Rρµ(g)hρν +Rρν(g)hρµ, 4(0) L φ = −2dφ. 2d is the d-dimensional d’Alambertian with respect to the metric gµν(x). Rµρνσ(g) and Rµν(g) are given in (35), (36) in Appendix A. Now we are ready to read off the mass of the gravitons and radion from the equations of motion. The graviton mass is simply given by m2 graviton = m2 n, n = 0, 1, 2, . . . . On the other hand, the radion mass should read m2 radion = m2 −1 − 2(d− 1)Λd = −dΛd, (32) which coincides with the previous results when Λd < 0 [15]. Notice that for the case of de Sitter brane Λd > 0, the radion acquires negative mass squared. Referring to the zero-mode solution (31) with the solution (4) and the inner product (22), however, we immediately see that this de Sitter radion mode becomes non-normalizable in the limit z2 →∞ and hence disappears from the spectrum of single brane models as discussed by Karch and Randall [6]. 5 Conclusions In this paper we have studied (d+ 1)-dimensional braneworld gravity with a single extra dimen- sion with non-vanishing bulk as well as brane cosmological constants. Without matter, classical Einstein equation admits four distinct types of warp factors, including Randall–Sundrum and Karch–Randall models. Irrespective of these four types of warped backgrounds, we have shown that there always exists a supersymmetry structure in the Kaluza–Klein spectrum as a conse- quence of (d+ 1)-dimensional general coordinate invariance. As discussed in Section 3, we have shown that scalar- and vector-modes formN = 2 supersymmetry multiplet, vector- and graviton- modes form another N = 2 supersymmetry multiplet, and scalar- and graviton-modes form the second-order derivative supersymmetry multiplet. The resultant spectrum exhibits three-fold 10 T. Nagasawa, S. Ohya, K. Sakamoto and M. Sakamoto degeneracy up to the ground states. This supersymmetry structure is powerful enough to de- termine the spectral pattern of Kaluza–Klein modes. Indeed, for the case of models with two codimension-1 branes, we have shown that the spectral pattern is controlled by supersymme- try and can be determined without referring neither equations of motion nor two-point Green functions (up to the constant shift 2(d − 1)Λd for the radion mode). What we need are only supersymmetries and boundary conditions. A Background Einstein equation Let us solve the (d+ 1)-dimensional bulk Einstein equation2 RMN (G)− 1 2 GMN [ R(G)− d(d− 1)Λd+1 ] = 0, with the metric ansatz GMN (x, z) = e2A(z)gMN (x), gMN (x) = ( gµν(x) 0 0 1 ) . Regarding that GMN is given by the conformal transformation gMN (x)→ e2A(z)gMN (x), we can easily evaluate the Ricci tensor RMN (G) by using its transformation law under the conformal transformation. The result is Rµν(G) = Rµν(g)− gµν [ A′′ + (d− 1)(A′)2 ] , Rµz(G) = 0, Rzz(G) = −dA′′, where Rµν(g) is the Ricci tensor with respect to the metric gµν(x). With these expressions the Ricci scalar is given by R(G) = GµνRµν(G) +GzzRzz(G) = e−2A [ R(g)− 2dA′′ − d(d− 1)(A′)2 ] . Thus the µν-component of bulk Einstein equation is 0 = Rµν(g)− 1 2 gµνR(g) + gµν [ (d− 1)A′′ + 1 2 (d− 1)(d− 2)(A′)2 + 1 2 d(d− 1)Λd+1e 2A ] , (33) while the zz-component is 0 = −1 2 R(g) + 1 2 d(d− 1)(A′)2 + 1 2 d(d− 1)Λd+1e 2A. (34) Note that the µz-component is trivial and does not lead to any constraint. Subtracting (33) by gµν × (34) we get Rµν(g) = (d− 1)gµν [(A′)2 −A′′]. 2Our conventions are as follows: metric signature: (−,+,+, . . . ,+), Christoffel symbol: ΓA MN (G) = 1 2 GAB(∂MGBN + ∂NGBM − ∂BGMN ), Curvature tensor: RK LMN (G) = ∂MΓK LN (G)− ∂NΓK LM (G) + ΓA LN (G)ΓK AM (G)− ΓA LM (G)ΓK NA(G), Ricci tensor: RMN (G) = RA MAN (G). Emergent Supersymmetry in Warped Backgrounds 11 By contracting this expression with respect to gµν and substituting the result into the equa- tion (34) we get R(g) = d(d− 1)[(A′)2 −A′′], 0 = A′′ + Λd+1e 2A. Since the warp factor A(z) is a function of z while the scalar curvature R(g) a function of xµ, there is no nontrivial solution to the Einstein equation except for the constant curvature case R(g) = const. Thus, by setting R(g) = d(d− 1)Λd, we obtain the announced equations (2), (3). We note that with these background metric the following identities hold Rµρνσ(g) = Λd(gµνgρσ − gµσgνρ), (35) Rρσ(g) = Rµρµσ(g) = (d− 1)Λdgµν . (36) B Shape invariance method and graviton mass spectrum for pure AdSd/AdSd+1 Similar analysis presented in Section 3 leads to the following hierarchy of Hamiltonians spin-0 mode : H0 = A−0 A + 0 + ε0 spin-1 mode : H1 = A+ 0 A − 0 + ε0 = A−1 A + 1 + ε1 spin-2 mode : H2 = = A+ 1 A − 1 + ε1 = A−2 A + 2 + ε2 spin-3 mode : H3 = = A+ 2 A − 2 + ε2 = · · · ... ... For general s, the first-order differential operators A+ s and A−s are given by A+ s = −∂z − (s+ d− 2)A′(z), A−s = +∂z − (s− 1)A′(z), which satisfies the intertwining relation A−s A+ s −A+ s−1A − s−1 = 2s̄Λd, where s̄ := s+ d− 4 2 . The constant shift εs is given by εs = −(s− 1)(s+ d− 2)Λd = [ (d− 1)2 4 − ( s̄+ 1 2 )2 ] Λd. Notice that when there is no codimension-1 branes, standard shape invariance method is appli- cable (for shape invariance method, see for example [16]). Thus, for pure AdSd/AdSd+1, the graviton mass spectrum can be obtained without solving the equation of motion and given by m2 graviton = m2 n := (n− 1)(n+ d− 2)|Λd|, n = 2, 3, 4, . . . , which coincides with the group theoretical results when d = 4 [6]. The resultant spectral pattern becomes as shown in Fig. 2. 12 T. Nagasawa, S. Ohya, K. Sakamoto and M. Sakamoto →← →← →← →← →← m2 m2 0 m2 1 = 0 m2 2 m2 3 ... f (0) 0 f (1) 0 f (2) 0 f (3) 0 f (1) 1 f (2) 1 f (3) 1 f (2) 2 f (3) 2 Figure 2. Spectral pattern of pure AdSd/AdSd+1. Particle contents are: one massive scalar (f (0) 0 ), one massive vector (f (1) 1 ), and an infinite tower of massive gravitons ({f (n)2 | n = 2, 3, 4, . . . }). The spectrum of Hamiltonian H0 is given by m2 n = (n− 1)(n+ d− 2)|Λd|, n = 0, 1, 2, . . . . C Analog supersymmetric quantum mechanics Under the following similarity transformation hMN 7→ h̄MN = e d−1 2 A(z)hMN , which eliminates the weight factor e(d−1)A(z) in the inner product (22), the Hamiltonian is transformed as Hs 7→ H̄s = e d−1 2 A(z)Hse − d−1 2 A(z), or, explicitly, H̄s = Ā−s Ā+ s + εs = Ā+ s−1Ā − s−1 + εs−1, where Ā+ s and Ā−s are the similarity transformed first-order differential operators given by Ā+ s = e d−1 2 A(z)A+ s e− d−1 2 A(z) = +∂z + ( s̄+ 1 2 ) A′(z), Ā−s = e d−1 2 A(z)A−s e− d−1 2 A(z) = −∂z + ( s̄+ 1 2 ) A′(z). With this similarity transformation the first-order derivative terms disappear from the Hamil- tonians. Indeed, by substituting the background solution (4), the similarity transformed Hamil- tonian reads H̄s = −∂2z + Vs(z), where the potential is given by Vs = (s̄2 − 1/4)A′′(z) + (d− 1)2 4 Λd, or, more explicitly, Vs(z) =  1 `2d s̄2 − 1/4 sin2(z/`d) − (d− 1)2 4 1 `2d for AdSd/AdSd+1, s̄2 − 1/4 z2 for Md/AdSd+1, 1 `2d s̄2 − 1/4 sinh2(z/`d) + (d− 1)2 4 1 `2d for dSd/AdSd+1, − 1 `2d s̄2 − 1/4 cosh2(z/`d) + (d− 1)2 4 1 `2d for dSd/dSd+1. (37) Emergent Supersymmetry in Warped Backgrounds 13 Thus the spectral problem of our braneworld gravity just reduces to the problem of supersymmet- ric quantum mechanics with the trigonometric Pöschl–Teller potential, inverse square potential, and hyperbolic Pöschl–Teller potential of sinh and cosh types. Notice that the constant term in (37) is nothing but the Breitenlohner–Freedman (BF) bound in AdSd [17]: m2 BF = −(d− 1)2 4 1 `2d . 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