On Holographic (stringy ) Baryons

1. On Holographic (stringy ) Baryons Crete June 09 work done with V. Kaplunovsky G. Harpaz ,N. Katz and S.Seki

2. Introduction • Holography is a useful tool in discussing the physics of glueballs and meson. • Baryons can be described as a semi-classical stringy configurations. • In large N baryons require a special treatment. This leads to the description in terms of skyrmions. • The holographic duals of baryons are instantons of a five dimensional flavor gauge theory. • Relating SUGRA predictions to a stringy picture. • Modern stringy baryons versus the “old” picture • We will put emphasis on comparison to data.

3. Outline • The Regge trajectories revisited • Stringy holographic baryons • Does the baryonic vertex have a trace in data • The stability of stringy baryons, simulation • Confining background- the Sakai Sugimoto model • Baryons as flavor gauge instantons • Baryonic properties in a genrealized model • Attraction between nucleons • Summary - Are we back in square one?

4. Regge trajectories revisited • Since excited baryons as we will see have a shape of a single string, lets discuss first stringy mesons. • On the probe branes there are only scalars and vectors so there are no candidates for higher spin mesons. • Apart from special tayllored models SUGRA does not admit the linearity of M2 ~ n • Mesons and baryons admit Regge behavior M2 ~ J and hence are described by semi-classical strings.

6. Reggetrajectoriesof baryons

7. The Regge mesons are described by semi-classical strings that end on the probe branes in the ``confining background”

9. We solve the the equations of motion associated with the NG action in the confining background. • An approximate solution takes the form of |___| • The same relations between the Mass and the angular momentum follow from a system of an open string with massive endpoints in flat space-time. • This is similar to old models of mesons that include a string with massive endpoints

11. In the small mass limit wR -> 1 • In the large mass limit wR -> 0

12. Quantization of the string • There is no exact expression of the quatization of the string with the massive endpoints. • For the the low mass case one can use the intercept of the massless case so that

13. Fit of the first r trajectory High mass trajectory Low masstrajectory

14. Fit of the first b b trajectory High mass trajectory Low mass trajectory

15. Obviously the approximation of low mass trajectory yields a better fit for the r meson trajectories and the high mass has a lower c2 for the b bar b mesons. • The best fit for all the light trajectories was found for the following parameters ( preleminry) msep~ 0.1 GEV Tst ~ 0.17 GEV2 a’ ~ 0.94 GEV-2 • For the b quark msep ~ 5 GEV

16. Fit to the Regge trajectories of baryons

17. What are the deviations of the full holographic model from the toy model? • For mesons of not so large J and hence also L there are deviations from the |__| configuration . • The ends of the string are charged under U(Nf) gauge interaction. For a single probe brane U(1) the constraint equation is modified and as a result we find that the constant term ( intercept) gets a shift. The charge is proportional to the string coupling which is a function of u0 and hence of the string endpoint mass!

18. Combining the low spin spectra ( scalar and vector) from brane fluctuations with the high spin spectra from stringy configurations imposes a puzzle since the mass of the formers Mm~ 1/R while the tension of the string Tst ~(1/R)2l • Since for small curvature we need l >> 1, there is a large unacceptable gap between low and high spin mesons. • This implies that will eventually have to work with curvature of order one.

19. Quark masses • We have encounter the end of the string mass Mmes~ Tst L + m1sep + m2sep • msep is neither mQCD nor constituent mass • GOR relation tells us that mp2~ mQCD<qq>/fp2 • In the SS model mp=0 <qq> 0 mQCD =0 • In the generalized SS with u0 > uL mp=0 <qq> 0 mQCD =0 msep mQCD

21. To turn on a QCD mass or more generally an ( (non-local) operator that breaks explicitly chiral symmetry • One can either introduce a ``tachyonic DBI” (Casero, Kiritsis and Paredes; Bergman, Seki J.S, Dhar Nag or introduce an open Wilson line (Aharony Kutasov) Both admit the GOR relation

22. Holographic Baryons • How to identify a baryon in holography ? • Since a quark corresponds to a string, the baryon has to be a structure with Nc strings connected to it. • Witten proposed a baryonic vertex in AdS5xS5 in the form of a wrapped D5 brane over the S5. • On the world volume of the wrapped D5 brane there is a CS term of the form

23. Strings end on the boundaryexternal baryon • /flfflav • Strings end on a flavor branedynamical baryons

24. The flux of the five form It implies that there is a charge Nc for the abelian gauge field. Since in a compact space one cannot have non-balanced charges there must be N c strings attached to it.

25. Possible experimental trace of the baryonic vertex? • We have seen that the Nucleon states furnish a Regge trajectory. • For Nc=3 a stringy baryon may be similar to the Y shape “old” stringy picture. The difference is the massive baryonic vertex.

26. The effect of the baryonic vertex in a Y shape baryon on the Regge trajectory is very simple. It affects the Mass but since if it is in the center of the baryon it does not affect the angular momentum • We thus get instead of J= a’mes M2 + a0 J= a’bar(M-mbv)2 +a0 and similarly for the improved trajectories with massive endpoints • Comparison with data shows that the best fit is for mbv =0 and a’bar ~a’mes

27. Thus we are led to a picture where the baryon is a single string with a quark on one end and a di-quark (+ a baryonic vertex) at the other end. • This is in accordance with stability analysis which shows that a small instability in one arm will cause it to shrink so that the final state is a single string

28. Stability analysis of classical stringy baryons • ‘t Hooft (Sharov) showed that the classical Y shape three string configuration is unstable • We have examined Y shape strings with massive endpoints and with a massive baryonic vertex in the middle. • The analysis included numerical simulations of the motions of mesons and Y shape baryons under the influence of symmetric and asymmetric disturbance. • We also performed a parturbative analysis

29. The conclusion from both the simulations and the perturbative analysis is that indeed the Y shape string configuration is unstable to asymmetric deformations. Thus an excited baryon is an unbalanced single string with a quark on one side and a diquark and the baryonic vertex on the other side.

30. Baryons in confining SUGRA backgrounds • Holographic baryons duals of QCD-like baryons have to include baryonic vertex embedded in a gravity background ``dual” to the YM theory with flavor branes that admit chiral symmetry breaking • A suitable candidate is the Sakai Sugimoto model which is based on the incorporation of D8 anti D8 branes in Witten’s model

31. Witten’s model-a prototype of confining model • A way to get a confining background is to cut the radial direction and introduce a scale. • One approach is indeed to cut by hand an Ads space. This is not a solution of the SUGRA equations of motion. People use it to examine phenomenological properties (AdsQCD) • The approach of Witten was to compactify one coordinate of D3 (D4) brane background with a “cigar-like” solution. R UL

32. One imposes anti-periodic boundary conditions on fermions. This kills supersymmetry. • In the dual gauge theory the gauginos and the scalars acquire a mass ~1/R and hence in the small R limit they decouple and we are left only with the gauge fields. • For a Dp brane, in the small R limit we loose one space dimension and we end up with a pure gauge theory in p-1 space dimensions. • The gravity theory associated with D3 branes namely the AdS5xS5 case compactified on a circle is dual to a pure YM theory in 3d ( with KK contamiation) • The same mechanism for near extremal D4 branes yields a dual theory of pure YM in 4d.

33. D4 D4 R

34. The gauge theory and sugra parameters are related via • 5d coupling 4d couplingglueball mass • String tension • The gravity picture is valid only provided that l5 >> R • At energies E<< 1/R the theory is effectively 4d. • However it is not really QCD since Mgb ~ MKK • In the opposite limit of l5 << R we approach QCD

35. To add fundamental quarks one adds flavor branes. • Lets go for a moment from the SUGRA background back to the brane configuration. • If we add to the original stack of Nc D3 ( or D4 ) branes another set of Nf Dp branes there will be strings connecting the D3 (D4) and Dp branes. • These strings map in the dual field theory to bifundamental “quarks” that transform as the(Nc, Nf) representation of the gauge symmetry U(Nc)xU(Nf) • For Nc >> Nf the U(Nf) can be treated as a global symmetry and hence we get fundamental quarks.

36. Coming back to the SUGRA background, in the case of Nc >> Nf we can safely neglect the backreaction of the additional branes on the background. Thus we have introduced in fact flavor probe branes into a background gravity model dual of a YM (SYM) theory. This is the gravity analog of using a quenched approximation in lattice gauge theories.

37. We would like to introduce probe flavor branes to Witten’s model. What type of Dp branes should we add D4, D6 or D8 branes? How do we incorporate a full chiral flavor global symmetry of the form U(Nf)xU(Nf), with left and right handed chiral quarks?

38. Adding flavor probe branes The mass is the string endpoint masss discussed before

39. U(Nf)xU(Nf) global flavor symmetry in the UV calls for two separate stacks of branes. • To have a breakdown of this chiral symmetry to the diagonal U(Nf)D we need the two stacks of branes to merge one into the other. • This requires a U shape profile of the probe branes. • The opposite orientations of the probe branes at their two ends implies that in fact these are stacks of Nf D8 branes and a stack of Nf anti D8 branes. ( Thus there is no net D8 brane charge) • This is the Sakai Sugimoto model.

40. We “see” that the model admits chiral symmetry U(Nf)xU(Nf) in the UV which is broken to a diagonal one U(Nf)D in the IR. qL qR

41. We place the two endpoints of the probe branes on the compactified circle. If there are additional transverse directions to the probe branes then one can move them along those directions and by that the strings will aquire length and the corresponding fields mass. Thus this will contradict the chiral symmetry which prevents a mass term. • Thus we are forced to use D8 branes that do not have additional transverse directions. • The fact that the strings are indeed chiral follows also from analyzing the representation of the strings under the Lorentz group

42. Stringy baryons in the SS model • The baryonic vertex will now be wrapped D4 branes over the S4 . • The Lorentz structure of the strings is determined by the #DD, #NN, #DN b.c • In the approximation of flat space one finds a degeneracy between the R and NS ground state energies thus the bosonic and fermionic are degenerate.

43. The location of the baryonic vertex in the radial direction is determined by ``static equillibrium”. • The energy is a decreasing function of x=uB/uL and hence it will be located at the tip of the flavor brane

44. It is interesting to check what happens in the deconfining phase. • For this case the result for the energy is • For x>xcr low temperature stable baryon • For x<xcr high temperature disolved baryon The baryonic vertex falls into the black hole

46. Baryons as instantons • In the SS model the baryon takes the form of an instanton in the 5d U(Nf) gauge theory. • The instanton is the BPST instanton in the ( xi,z) 4d curved space. In the leading order in l it is exact. • For Nf= 2 the SU(2) yields a run away potential and the U(1) has an opposite nature so that one finds a “stable” size but unfortunately on the order of l-1/2 so stringy effects cannot be neglected in the large l limit.

47. Baryons in the Sakai Sugimoto model • The probe brane world volume 9d 5d upon Integration over the S4. The 5d DBI+ CS is expanded where

48. One decomposes the gauge fields to SU(2) and U(1) • In a 1/l expansion the leading term is the YM • Ignoring the curvature the solution of the SU(2) gauge field with baryon #= instanton #=1 is the BPST instanton

49. Upon introducing the CS term ( next to leading in 1/l, the instanton is a source of the U(1) gauge field that can be solved exactly. • Rescaling the coordinates and the gauge fields, one determines the size of the baryon by minimizing its energy

50. Performing collective coordinaes semi-classical analysis the spectra of the nucleons and deltas was extracted. • In addition the mean square radii, magnetic moments and axial couplings were computed. • The latter have a similar ( maybe better) agreement with data then the skyrme calculations. • The results depend on one parameter the scale. • Comparing to real data for Nc=3, it turns out that the scale is different by a factor of 2 from the scale needed for the meson spectra.