Heavy Holographic Exotics: Tetraquarks as Efimov States

We provide a holographic description of non-strange multiquark exotics as compact topological molecules by binding heavy-light mesons to a tunneling configuration in D8-D$\bar 8$ that is homotopic to the vacuum state with fixed Chern-Simons number. In the tunneling process, the heavy-light mesons transmute to fermions. Their binding is generic and arises from a trade-off between the dipole attraction induced by the Chern-Simons term and the U(1) fermionic repulsion. In the heavy quark limit, the open-flavor tetraquark exotics $QQ\bar q\bar q$ and $\bar Q\bar Q qq$, emerge as bound Efimov states in a degenerate multiplet $IJ^\pi=(00^+ , 01^+)$ with opposite intrinsic Chern-Simons numbers $\pm \frac 12$. The hidden-flavor tetraquark exotics such as $Q\bar Q q\bar q$, $QQ\bar Q\bar q$ and $QQ\bar Q\bar Q$ as compact topological molecules are unbound. Other exotics are also discussed.

The reported pentaquark states with hidden charm initially suggested in [23], have been addressed by many [24][25][26][27] including the newly reported neutrals Ω 0 c as discussed in [28][29][30][31].Given the difficulty to track QCD in the infrared, it is not easy to identify a first principle mechanism for the formation of these multiquark states.
Most of the multiquark states reported so far involve * Electronic address: yizhuang.liu@sjtu.edu.cn† Electronic address: maciej.a.nowak@uj.edu.pl‡ Electronic address: ismail.zahed@stonybrook.eduboth heavy and light quarks but fall outside the realm of the canonical quark model [22].It is well established that the light quark sector of QCD exhibits spontaneous chiral symmetry breaking, while the heavy quark sector is characterized by heavy quark symmetry [32].Both symmetries are at the origin of the chiral doubling suggested in heavy-light mesons [33,34], and confirmed experimentally in [35,36].It is therefore important that a theoretical approach to the multiquark states should have manifest chiral and heavy quark symmetry, a clear organizational principle in the infrared, and should address concisely the multi-body bound state problem.
The holographic principle in general [37][38][39], and the D4-D8-D 8 holographic set up in particular [40] provide a framework for addressing QCD in the infrared in the double limit of a large number of colors and strong coupling λ = g 2 Y M N c .It is confining and exhibits spontaneous chiral symmetry breaking geometrically.In leading order in 1/λ, the light meson sector is well described by an effective action on the fused D8-D 8 branes that is consistent with known effective theories [41].The same setup can be minimally modified to account for the description of heavy-light mesons as well, with full account of heavy quark symmetry [42].Light and heavy-light baryons are dual to instantons and instanton-heavy meson bound states in bulk [42][43][44][45][46][47][48], providing a concise approach to the multi-body bound state problem.In a way, the holographic construction provides a geometrical realization of the Skyrmion and its variants [25,49,50], without the shortcomings of the derivative expansion.Alternative holographic models for the description of heavy hadrons have been developed in [51][52][53] without the dual strictures of chiral and heavy quark symmetrty.
The organization of the paper is as follows: in section 2 we recall the geometrical setup for the derivation of the heavy-light effective action with two light and one heavy flavor.We detail the heavy-light Dirac-Born-Infeld (hereafter DBI) action and the particular classical fields of interest for the description of the holographic multiquark states.In section 3 we derive explicitly a class of O( 4) tunneling configurations with fixed Chern-Simons (hereafter CS) number in D8-D 8, that interpolate continuously between a unit topological charge (fermion) and zero topological charge (boson).We also derive their associated fermionic zero modes.In section 4, we detail how a heavy meson attached to the tunneling configuration transmutes to a fermion.We also derive the pertinent Hamiltonian on the moduli associated to the topological molecule formed of heavy mesons attached to the O(4) tunneling configuration.In the heavy quark limit, the open-flavor and non-strange tetraquarks and hexaquarks are found to be bound Efimov-like states.The hidden-flavor tetraquarks are not bound.In general, heavier exotics are not bound.Our conclusions are in section 5. We provide two appendices for completeness.

A. D-brane set up
The D4-D8-D 8 setup for light flavor branes is standard [40].The minimal modification that accomodates heavy mesons makes use of an extra heavy brane as discussed in [42].It consists of N f light D8-D 8 branes (L) and one heavy (H) probe brane in the cigar-shaped geometry that spontaneously breaks chiral symmetry.A schematic description of the set up for N f = 2 is shown in Fig. 1.We assume that the L-brane world volume consists of R 4 × S 1 × S 4 with [0 − 9]-dimensions.The light 8-branes are embedded in the [0−3+5−9]-dimensions and set at the antipodes of S 1 which lies in the 4-dimension.The warped [5 − 9]-space is characterized by a finite size R and a horizon at U KK .

B. DBI action
The effective action on the probe L-branes consists of the non-Abelian DBI and CS action.After integrating over the S 4 , the leading contribution in 1/λ to the DBI action is The warping factors are with U 3 z = U 3 KK + U KK z 2 , and κ ≡ aλN c and a = 1/(216π 3 ) [40].Our conventions are (−1, 1, 1, 1, 1) with A † M = −A M and the labels M, N running over µ, z only in this section.All units are given in terms of M KK = 1, which is readily recovered by dimensional inspection.The effective fields in the field strengths are [42] The matrix valued 1-form gauge field is For N f = 2, the naive Chern-Simons 5-form is We note that for only N f > 2 it fails to reproduce the correct transformation law under the combined gauge and chiral transformations [46].In particular, when addressing the N f = 3 baryon spectra, (5) does not treproduce the important hypercharge constraint [46], but can be minimally modified to do that.
For N f coincidental branes, the Φ multiplet is massless, but for separated branes as illustrated in Fig. 1 they are massive with the additional contribution The value of m H is related to the separation between the light and heavy branes, which is about the length of the HL string.Below, m H will be taken as the heavy meson mass.

C. Light fields
In the coincidental brane limit, light baryons are interchangebly described as a flavor instanton or a D4 brane wrapping the S 4 .The instanton size is small with ρ ∼ 1/ √ λ after balancing the order λN c bulk gravitational attraction with the subleading and of order λ 0 N c U(1) induced topological repulsion [40].
To describe tetraquark states which carry zero topological charge or baryon number, but are still tightly bound by the underlying light gauge field in holography, we suggest to use a tunneling configuration on the sphaleron path that is homotopic to the vacuum state.The configuration will carry fixed Chern-Simons number.We will seek it using the maximally symmetric O(4) gauge field F zm (y)| |y|=R = 0 (7) subject to the condition of zero electric field strength at the turning point R = ρ.From here on M, N runs only over 1, 2, 3, z unless specified otherwise.If ρ ∼ 1/ √ λ is the typical size of these tunneling configuations, then it is natural to recast the DBI action using the rescaling The rescaled fields satisfy the equations with the use of the Hodge dual notation, subject to the turning point condition (7) in leading order in 1/λ.The detailed solution to (9) will be given below.Unlike the instanton which is stable, these tunneling configurations are unstable and tend to relax to the vacuum state.They are the O(4) analogue of an instanton-anti-instanton configuration running to its demise through the valley.Below, we will show that they can stabilize quantum mechanically when heavy mesons bind to them.

D. Heavy-light fields
Let (Φ 0 , Φ M ) be the pair of heavy quantum fields that bind to the tunneling configuration above.If again ρ ∼ 1/ √ λ is their typical size, then it is natural to recast the heavy-light part of the DBI action using the additional rescaling The interactions between the light gauge fields (A 0 , A M ) and the heavy fields (Φ 0 , Φ M ) to quadratic order split to several contributions [42] L = aN c λL 0 + aN c L 1 + L CS (11) which are quoted in the Appendix for completeness.Here we only need the leading contributions stemming from (11) in the additional heavy mass limit m H → ∞.For that, we split Φ M = φ M e −im H x0 for particles (m H → −m H for anti-particles).The leading order contribution takes the form subject to the constraint equation while the subleading contributions in (11) to order λ 0 m H simplify to For self-dual light gauge fields with F M N = F M N , the last contribution in (12) vanishes, and the minimum is reached for f M N = f M N .This observation when combined with the transversality condition for D M φ M = 0, amounts to a first order equation for the combination ψ = σM φ M with σ M = (i, σ), i.e.
σ M D M ψ = Dψ = 0 (15) as noted in [42].In a self-dual gauge configuration, the heavy spin-1 meson transmutes to a massless spin-1 2 spinor that is BPS bound in leading order.For the tunneling configuration in (7) the self-duality condition no longer holds.With this in mind, we now proceed to determine first the explicit tunneling configuration (A 0 , A M ) by solving (9), and then its variational zero mode.

III. TUNNELING FIELD AND ITS FERMIONIC ZERO MODE
In this section we detail the construction of a family of O(4) symmetric tunneling configurations (7) solution to (9).They carry fractional Chern-Simons number at the turning point, and interpolate parametrically between the instanton and the sphaleron configuration at the turning point when continued to Minkowski space.Their O(3) symmetric relatives through a conformal transfornation are discussed in the Appendix.We note that similar configurations were used in the context of explosive sphalerons and their applications to finite energy collisions [54][55][56].We also derive their corresponding fermionic zero modes, which will prove useful for the discussion of the heavy-meson bound states through transmutation.

A. O(4) tunneling configuration
Consider the O( 4) static and symmetric ansatz for the SU(2) gauge configuration with the conformal variable ξ(y) = 1 2 ln(y 2 /ρ 2 ).The antiinstanton and anti-sphaleron configurations follow from a similar construction with a dual background η → η.In terms of ( 16) the static O(4) symmetric part of the Yang-Mills action in (1) without warping reads with T the length of time, the induced effective coupling for the flavor gauge fields g 2 κ = 1/κ, and the double well potential with f = 1 − f .The O(4) profile f (ξ) extremizes ( 17) by satisfying which is of the Jacobi type.Remarkably, the solution to (19) with a sphaleron-like turning point at ξ = 0 with f (ξ = 0) = 0, can be found explicitly with sn the Jacobi sine function.We note that the solution ( 20) is ξ-periodic with period Here K(k) is the elliptic function, and . In Fig. 2 we show (20) for k = 0.1, 0.5, 1.
The parameter k relates to the sphaleron-like energy at the turning point At k = 0 we recover the expected sphaleron energy At the instanton point k = 1 with zero energy E 1 = 0 we recover the instanton interpolating profile as illustrated in Fig. 2. In general, the solution (20) carries Chern-Simons number N k and energy E k at the turning point, that are tied through the profile of the potential ( 18) with N 1 = 1 the instanton topological charge, and N 0 = 1 2 the sphaleron Chern-Simons number.Only the solution with N 1 = 1 is self-dual.All the other configurations with N k < 1 are extrema rather than minima, and therefore prone to decay.They are homotopic to the vacuum state.
For the holographic dual hadronic configurations, the more relevant quantity is the action (17) for the generalized tunneling configurations (20).Since the solutions are periodic reflecting on the periodicity of the sphaleronridge, we have for the fundamental period the action which gives S 1 = (8π 2 /g 2 κ )T at the instanton point as expected, and at the sphaleron point.In particular, the holographic mass of the tunneling configuration without warping, can be read from (25) as M k = S k /T .We note that the holographic mass ratio at the sphaleron to instanton point is In Fig. 3 we show the mass ratio

B. U(1) gauge field
The U(1) gauge field in ( 9) is sourced by the local topological charge density carried by the O(4) tunneling configuration (16).For that, it is useful to determine the field strength F M N and its dual F M N , or more explicitly the electric and magnetic fields with f and E = B as expected for the instanton path.The U(1) field satisfies which can be inverted if we define so that φ 1 (ξ) is solution to which is sourced by the topological charge density.The net topological charge is Note that F 0 (ξ, k) is a total derivative as it should, which is identically zero at the sphaleron point since 31) is monotonous in k as shown in Fig. 4. It interpolates continuously between the sphaleron path at k = 0 with zero topological charge, and the instanton path at k = 1 with unit topological charge.
Eq. ( 30) is readily solved using The constants of integration C 1,2 can be fixed by choosing the solution to satisfy the zero boundary condition at ξ = − T k 2 and the regular boundary condition at ξ = T k 2 .This means that which explicitly gives

C. O(4) fermionic zero mode
The zero mode solution in the O( 4) configuration ( 1) solves the Dirac equation In the chiral basis with spin matrices σMs = (1, −i σ s ) and (36) splits into two chirality modes ψ ± each conjugate of the other.Note the difference between the preceding conventions and the hermiticity of the gauge field in this section only.If we note that the t Hooft symbol satisfies the color identity σMc σ N c = σ ac η aM N (38) with the color matrices σ M c = (1, −i σ c ), then the positive chirality mode associated to (36) satisfies with the spin and color matrices commuting, and F (ξ) following from ( 16) Note that while writing (39) we have added a U(1) part to the gauge field for notational simplicity.It will be removed in the final step below.Eq. ( 39) can be solved formally using wich is a singlet in color-spin space that satisfies Using (41)(42) in (39) yield It is here that we need to remove the U(1) contribution noted above through the substitution leading to the O( 4) symmetric equation for the zero mode amplitude The spinor zero-mode of positive parity is with the normalization constant fixed within IV. MULTIQUARK EXOTICS AS TOPOLOGICAL MOLECULES In the triple limit of a large number of colors N c , strong coupling λ and heavy meson mass m H , the holographic multiquark exotics can be constructed by attaching to the O(4) tunneling gauge configuration an arbitrary number of heavy-light mesons.Of course, in reality only a few can stick.The fermionic repulsion induced through a U(1) coupling to the Chern-Simons term stabilizes the tunneling configurations viewed as an instanton-anti-instanton process.

A. Heavy bound meson
For k = 1 with net topological charge 1, the heavy meson field in the self-dual classical background (7) transmutes to a fermionic zero mode (15) as initially noted in [42].For k < 1 which is the case of interest with fractional topological charge (fixed Chern-Simons number), the classical background ( 7) is no longer self-dual and the minimum of ( 12) can be solved using a variational fermionic ansatz of the type ( 15) with the radial coordinate r = |y|.In terms of ( 48) the leading contribution to the action S 0 associated to L 0 in (11) is with Here g = dg/dr, G(r) = f /r and G = dG/dr with the background gauge field expressed in the r-coordinate The local minimum for S 0 (g) requires that g(r) satisfies A special solution to ( 52) is of the form which is readily seen to satisfy g + 3Gg = 0 g + 3G g + 3Gg = 0 (54) and therefore which is (52).We note that for k = 1 which corresponds to the instanton path, Eq. ( 53) reduces to the standard fermionic zero mode (r 2 + ρ 2 ) − 3 2 .( 48) with ( 53) is transverse D M φ M = 0 for all values of k.In [42] describes the induced fermionic moduli upon binding, which is how the heavy quark of the original heavy-light meson manifests itself in this limit.

B. Action for the topological molecule
With the above in mind, and following the arguments presented in [42] (see section VB), the pertinent contributions to the action for the topological molecule to order λ 0 m H is with the U(1) Coulomb contribution due to the attraction induced by the Chern-Simons density ρ 0 (A) and the self-repulsion.More explicitly, we have with the Coulomb factor The contribution to (56) −2m H (φ † 0 iD M φ M − c.c) = 0 drops out for any k, thanks to the transversality of the zero-mode (48).We recall that for k = 1 the tunneling configuration is self-dual but not otherwise.This configuration is an instanton with topological charge 1, and ( 56) describes the action of holographic heavy baryons [42].

C. Hamiltonian for the topological molecule
The molecular Hamiltonian associated to (56) follows using the canonical rules for χ Q in the form after the rescaling of the fermionic fields Switching to the conformal coordinate ξ, and using the explicit profile for the tunneling gauge configuration f (ξ) in ( 20), the U(1) gauge field F 0 (ξ, k) in ( 30) and the zero mode g(ξ) in ( 53), we obtain for the k-dependent coefficients α 0,1,2 (k) As a reminder, the functions φ 1,2 are explicitly given by We fix the region of integration B to the period T k in ( 21) , with the boundary conditions specified earlier.The integrals in (62) for α 1,2 (k) are not reducible to single integrals upon the insertion of ( 63) and integration by parts, since e 2ξ−3F does not integrate to a simple function.
The first contribution in ( 60) is the holographic mass (25) of the tunneling configuration of order λN c , which is seen to reduce to the instanton mass (action) for k = 1.The second contribution is the mass of the attached heavy quarks in the mesonic molecule.The contribution linear in λ stems from the boundary term for the quadratic heavy meson action.It is non-zero for 0 ≤ k < 1 due to the deviation of the tunneling gauge configuration from self-duality.The α 1 contribution stems from the U(1) Coulomb coupling of the charge χ † χ to the background charge ρ 0 and the Chern-Simons terms.The (χ † χ) 2 contribution stems from the U(1) Coulomb-like self-interaction.All of these contributions are similar to the k = 1 case with the exception of the α 0 -contribution.

D. Classical binding energy
In general the treatment of the size ρ requires quantum mechanics as we detail below.However, for a classical estimate, we note that since the dependence of M k versus k is mild as seen in Fig. 3 with a size of order (λN c ) 0 / √ λ, we may fix it near the instanton point at k ∼ 1 with the result [44,45]  in units of is the number of heavy quarks (mesons) attached to the tunneling configuration, their classical binding energy ∆ H (k) as a function of k follows from ( 60) as (M 1 = 8π 2 κ) We fix the holographic parameters to: N c = 3, λ = 20 [44,57] and M KK = m ρ / √ 0.67 ≈ 1 GeV [44].For N Q = 2, we show in Fig. 8 the classical binding energy ∆ H (0) versus m H in units of M KK .We recall that k = 0 corresponds to the sphaleron path with zero topological charge.For charm and bottom, m H is fixed to the (0 − , 1 − ) multiplet, i.e. m D ≈ 1.870 GeV for (D, D * ) and m B ≈ 5.279 GeV for (B, B * ).The classical binding of both charm and bottom is large and depends sensitively on the value of ρ.In the heavy quark limit with m H → ∞, the classical binding disappears when the repulsion (α 2 ) exceeds the attraction (α 1 ) modulo M k , i.e.
A more accurate estimate of the binding requires a quantum treatment as we now discuss.

E. Quantum moduli
The quantum moduli space of the O(4) tunneling configurations is analogous to the instanton moduli or R 4 × R 4 /Z 2 (flat space) [40].Here we focus on R 4 /Z 2 which corresponds to the size and global flavor SU (2) orientations.We will refer to y I = ρa I as the coordinates on R 4 /Z 2 , with the SU(2) orientations parametrized by a I subject to the normalization a 2 I = 1, and to ρ as the size of the instanton.The collective Hamiltonian on the R 4 /Z 2 moduli for the bound molecule follows from the arguments given in [42] as and the inertial parameters m 1 = 16π 2 aN c , ω 2 1 = 1 6 .Here q(k) is the U(1) topological self-repulsion in the absence of the heavy mesons In Fig 9 we show (68) versus k, which is seen to increase monotonously with the topological charge, from q(0) = 0 on the sphaleron path to q(1) = 1 on the instanton path [42].
All contributions in (67) are in principle leading in the triple limit N c > λ > m H 1 provided that N Q /N c is of order 1.However, in practice some of the the inequalities may not be fulfilled.This is a known shortcoming of the holographic construction, where for instance λ > N c is used in most applications [40,44,57].
For N Q = 0, the eigenstates of ( 66) are given by T l (a)R ln , where T l (a) are the spherical harmonics on S 3 with ∇ 2 T l = −l(l + 2)T l .Under SO(4)∼ SU( 2 is the isospin rotation and the right factor is the space rotation with quantum numbers I = J = l 2 .For N Q = 0, the isospin (I) and the spin (J) decouple with the identification [42] The isospin-spin representations are now

F. Multiquark exotics
The radial equation for the reduced wavefunction R nl = u nl /ρ 3 2 following from (66) now reads The quantum corrected classical binding energy ( 65) is now The occurence of the 1/ρ 2 potential at short distances, stems from the nature of the attraction in ( 60) which is dipole-like and the repulsion in (60) which is U(1)like and Coulombic in 4-spatial dimensions.It is dominant at small distances, with the critical coupling of − 1 4 for the formation of deep bound states below the heavy meson threshold.Throughout, binding means that In Fig. 10 we show the behavior of s l (x) ≡ g l (0) + 1 4 as a function of x = N Q /N c with m H → ∞, on the sphaleron path (zero topological charge), for l = 0 lower (blue) curve, l = 1 middle (orange) curve and l = 2 upper (green) curve.Only for l = 0 and x = N Q /N c < 1.2 is the attraction sufficiently strong to form deep bound states.Higher waves with l = 1, 2, ... are unbound.For N c = 3, only N Q ≤ 3 states are a priori bound, i.e. open-flavor tetraquark QQq q and hexaquark QQQq q q states.The S-wave tetraquark states QQq q carry IJ π = 00 + , 01 + assignments with Chern-Simons number + 1 2 , and are degenerate.

G. Efimov states
For small distances and S-waves, (71) reduces to For g 0 (k) + 1 4 < 0, the potential in ( 74) is sufficiently attractive to form deep bound states.However, it is singular and requires regularization [58].The scale invariance of (74) allows for a universal regularization using the renormalization group approach, whereby the depth of the attractive and singular potential, can be chosen to be a function of a short distance cutoff R S [58].As a result, (74) admits many S-wave bound states with an accumulation near threshold, the so-called Efimov states [59].We note that in our case, there is a minimal value for the cutoff R min = 1/m H , so the number of bound states is limited.
The bound state spectrum for (74) was detailed in [58] with extensive analysis in the context of the renormalization group cycle, with the result where x = N Q /N c .To avoid cluttering the notations, we omitted the x-dependence in all quantities except ν k,x .
The behavior of ν k,x versus k is shown in Fig. 11 for N c = 3, x = 2/3 and m H → ∞.The coupling peaks at k = 1 2 , halfway between the instanton and sphaleron path.
Consecutive bound state energies are tied geometrically showing their accumulation or dissipation at threshold e k,00 = 0, i.e. the Efimov effect.The undetermined constant C in the quantum spectrum (75) reflects on the singular potential, that warrants renormalization.Changing C amounts to redefining the depth of the singular potential.In (75) the scale r 0 is fixed by the curvature or range of the long distance 1/ρ 2 potential.From (71) we fix it by matching the strength of the short distance potential to the strength of the large distance harmonic potential, i.e. r 2 0 = 1/(m k ω 1 ).As a result, the quantum binding energy (73) becomes For N c = 3 and at the sphaleron point with k = 0, the binding energy (77) depends on the coupling λ, the occupation ratio x = N Q /N c < 1.2 and the parameter C (cutoff depth).We fix C so that the binding energy vanishes for x = 1/3 giving a Qq meson state of energy exactly m H .With this in mind, (77) reads In the heavy quark limit, ν 0,1/3 = 1.10, ν 0,2/3 = 1.26 and ν 0,3/3 = 0.93.Fig. 12 shows the behavior of the binding energies (78) versus the t Hooft coupling λ, for x = 1  3 upper (green) curve, x = 2 3 lower (orange) curve and x = 3 3 middle (blue) curve, in the heavy quark limit.For m H → ∞, the binding energies of the tetraquark states QQq q and hexaquark states QQQq q q are listed in the first column of Table I-II respectively.The binding energies are not very sensitive to 10 ≤ λ ≤ 20.For bottom B-mesons with m B = 5.279 GeV and charmed D-mesons with m D = 1.87 GeV, the binding energies for tetraquark and hexaquark states are also listed in Table I-II respectively.The hexaquark states are unbound for finite masses.
We note that for the bound tetraquark states, the Efimov factor is e −2π/ν 0,2/3 ≈ 10 −3 .This factor in the geometrical ratio (76) shows that the radially excited tetraquark exotics rapidly move to the continuum and unbind.So we expect only one bound state to survive.
The heavy multiquark states with hidden-flavor are also covered by the present analysis provided that N 4) tunneling configuration should be an anti-instanton path with topological charge −1, interpolating to an anti-sphaleron path with Chern-Simons number − 1 2 .This implies conjugate symmetry for bosonic multiquark states.As a result, the conjugate tetraquark states Q Qqq are bound and degenerate λ QQQq q q GeV bbbq q q GeV bbcq q q GeV cccq q q GeV 10 −0. with QQq q.Heavier tetraquark states such as Heavier multiquark states of the type QQ Qq and QQ Qq q q with N Q → N Q − N Q = 1 are unbound, but those of the type QQ(Q Q) p q q with N Q − N Q = (p + 2) − p = 2 are bound in the heavy quark limit.
Our holographic results support a double-bottom tetraquark state with a binding energy ∆ BB = −(0.088−0.091) GeV somewhat lower than the lattice estimate, a mixed bottom-charm tetraquark with a binding energy ∆ CB = −(0.064− 0.080) GeV closer to the lattice estimate, and a bound double-charm tetraquark with a binding energy ∆ CC = −(0.041− 0.072) GeV contrary to the lattice estimate.These results are overall consistent with earlier estimates in the context of the random instanton model [21].
Finally, we note that multiquark exotics in the context of holography have been recently addressed in the context of the holography inspired stringy hadron model (HISH) [53].We view our analysis as complementary to the HISH analysis as it applies to the low lying exotics as opposed to the highly excited and stringy exotics.Our analysis can be extended to the excited and unbound exotic states for slow rotations, with the rotational-vibrational spectrum for l > 0 following from (66-67) through standard arguments [40,42].The states described by ( 70) are unstable against the strong decay to heavy-light mesons.For l 1 the spectrum (79) does not reggeize since E 0,nl ≈ l.A way to achieve reggeization is through relativistic rotations, that allow for a stringy-like deformation of the underlying O(4) tunneling configuration.This will be discussed elsewhere.

V. CONCLUSIONS
We have presented a top-down holographic approach to multiquark exotic states using a minimally modified D4-D8-D 8 set up to account for two light and one heavy flavor [42].The heavy multiquark states are topological molecules of heavy-light mesons bound to a tunneling gauge configuration with fixed Chern-Simons number.The latter interpolates between an instanton path with net topological charge 1 or baryon number (a fermion), and a sphaleron path with net topological charge 0 and Chern-Simons number 1  2 (a boson).The geometrical interpolation between a fermion and a boson in higher dimensions, is remarkable.It points to a topological duality between the heavy baryon exotics discussed in [42], and the heavy meson exotics addressed here.This is suggestive of a geometrical realization and generalization of the Savage-Wise symmetry [61] to most heavy exotics.
In leading order in the heavy quark limit, the bounded heavy mesons to the tunneling path with fixed Chern-Simons number transmute to fermions.This mechanism is reminiscent of the transmutation of the strange quark spin to the Skyrmion in the kaon-Skyrmion bound state [62].The binding of the fermions follows by balancing the attraction induced by the Chern Simons term which is dipole-like, and the dual repulsion stemming from the induced U(1) gauge field together with the deviation of the tunneling configuration from self-duality which are 4dimensional Coulomb-like.The ensuing potential in the molecule is singular.As a result the topologically bound exotics are Efimov states.
Our analysis shows that only the open-flavor molecules with x = N Q /N c < 1.2 are bound in the heavy quark limit.For N c = 3, the open-flavor exotics QQq q and their conjugate Q Qqq are bound in a degenerate multiplet IJ π = (00 + , 01 + ) with opposite intrinsic Chern-Simons numbers ± 1 2 .The open-flavor and non-strange hexaquark states QQQq q q are bound in the heavy quark limit only.The heavier exotics QQ Q Q are unbound.The compact exotics with hidden-flavor such as QQ Qq and Q Qq q are also unbound, but the heavier exotics such as QQ(Q Q)q q are bound in the heavy quark limit.
The leading holographic correction in the heavy quark mass is found to penalize the binding in ccq q more than in bbq q.Our analysis suggests a rotational-vibrational tower of multiquark excitations prone to strong decay.Some of the shortcomings of the present approach lie in the use of the triple limits of large N c , large coupling λ, and large meson mass m H .Although the relaxation of these limits is straightforward in principle, its systematic implementation is involved in practice.This not withstanding, the present setup is noticeable because of the limited number of parameters it carries.The brane tension κ ∼ λN c is usually traded for the pion decay constant, and the KK scale for the rho meson mass all in the light meson sector, leaving the treatment of the heavy-light sector parameter free modulo the heavy meson masses m H .
Unlike most of the approaches for heavy exotics [63] (and references therein), the present construction enforces heavy quark symmetry, the spontaneous breaking of chiral symmetry, provides a systematic organizational framework using the QCD parameters N c , λ, m H , and solves the multi-body problem using topological bound states.
The construction can be improved in a number of ways.For instance, by breaking isospin symmetry and including strangeness to account for strange topological exotics, or by adding a tachyon and a tachyon potential to bring the model closer to QCD at short distances, perhaps in the context of improved holographic QCD [64].These and related issues will be discussed next.

VII. APPENDIX I: HEAVY-LIGHT ACTION
The explicit construction of the holographic heavy-ligh action was detailed in [42].Here we quote the relevant expressions for (11) for completeness, and In this Appendix we suggest yet another tunneling configuration with O(3) instead of O(4) symmetry that is also suitable for binding heavy-light mesons which is fully localized in flat R 4 .This configuration is characterized by a turning point in the holographic direction at z = 0, in agreement with the explosive sphaleron configurations discussed in [54][55][56].To construct it, we note that the O(4) solutions to the Yang-Mills equations with a turning point at ξ = 0 relates to the solution with a turning point at z = 0 by the inversion This result is in agreement with the one derived in [56] prior to the analytical continuation to Minkowski space (see their Eq.22 with a minor correction of the 2 to 3 2 in their exponent).

FIG. 1 :
FIG.1: N f = 2 antipodal 8L light branes, and one 8H heavy brane shown in the τ U plane, with a bulk O(4) symmetric tunneling configuration with a turning point, embedded in 8L and a massive HL-string connecting them.