1 / 46

Holographic Mesons

Holographic Mesons. RCM & Thomson (hep-th/0605017) Kruczenski, Mateos, RCM & Winters (hep-th/0304032). Outline:. AdS/CFT with D7-branes fundamental matter. Karch + Katz (hep-th/0205236). holographic mesons.

carina
Download Presentation

Holographic Mesons

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Holographic Mesons RCM & Thomson (hep-th/0605017) Kruczenski, Mateos, RCM & Winters (hep-th/0304032)

  2. Outline: • AdS/CFT with D7-branes • fundamental matter Karch + Katz (hep-th/0205236) holographic mesons Kruczenski, Mateos, RCM + Winters (hep-th/0304032) 2. Gauge/Gravity with probe branes “universal” meson spectrum RCM + Thomson (hep-th/0605017) Arean + Ramallo (hep-th/0602174) 3. Observations/Future Directions

  3. Maldacena; Witten; Gubser, Klebanov & Polyakov; ….. AdS/CFT from D3-branes: d=10 Type IIb superstrings in AdS5 X S5 with Nc units of RR flux equivalent to all adjoint fields! d=4 N =4 U(Nc) super-Yang-Mills supergravity limit ~ large-N with strong `t Hooft coupling

  4. (Karch and Katz) Fundamental fields: decoupling limitof Nc D3-branes with Nf D7-branes D7 D7 x r=L D3 L black brane with d=4 U(Nc) o.s., d=8 U(Nf) o.s. & bifundamental 3-7 o.s. Low-energy limit with Reduces brane theory to field theory Minimum mass for 3-7 strings: Decouples asymptotic (closed) strings Gauge coupling on D7’s: • throat geometry: AdS5 X S5 with Nf D7’s • brane theory →N =4 U(Nc) SYM with fundamental matter

  5. Field theory: N=4 U(Nc) super-Yang-Mills vector: 4 Weyl fermions: 3 complex scalars: adjoint in U(Nc) coupled to: Nf massive N=2 hypermultiplets 2 complex scalars: 2 Weyl fermions: fund. in U(Nc) & global U(Nf) • SUSY: N =4 → N =2 • SO(6) → SO(4) = SU(2)L X SU(2)R

  6. Geometry: equator AdS boundary S5 D7 S3 horizon SO(4) = rotational symmetry of S3 pole

  7. Geometry: equator AdS boundary S5 D7 S3 horizon Mesons, bound states of fundamental fields, dual to open string states supported by D7-brane pole

  8. Gauge/gravity dictionary: supergravity modes: flavor indices Dq-brane modes: Probe approximation: Nf /Nc → 0 The above construction does not take into account the “gravitational” back-reaction of the D7-branes! → considering large-Nc limit with Nf fixed (see, however: Burrington et al; Kirsch & Vaman; Casero, Nunez & Paredes)

  9. Kruczenski, Mateos, RCM and Winters (hep-th/0304032) Mesons: lowest lying open string states are excitations of the massless modes on D7-brane: vector, scalars (& spinors) their dynamics is governed by usual worldvolume action: • free spectrum: • expand action to second order in fluctuations • solve linearized eq’s of motion by separation of variables Veff discrete spectrum r

  10. Kruczenski, Mateos, RCM and Winters (hep-th/0304032) Meson spectrum: = radial AdS quantum # = angular quantum # on S3 = R-charge massive supermultiplets with bosons and fermions

  11. Itzhaki, Maldacena, Sonnenschein & Yankielowcz (p<5) Gauge/Gravity Duality from Dp-branes: d=10 Type II superstrings in Dp-brane throat with Nc units of RR flux equivalent to d=p+1 N =4 U(Nc) super-Yang-Mills dimensionless effective coupling: YM coupling dimensionful !

  12. Itzhaki, Maldacena, Sonnenschein & Yankielowcz (p<5) Gauge/Gravity Duality from Dp-branes: d=10 Type II superstrings in Dp-brane throat with Nc units of RR flux dilaton and curvature run! equivalent to d=p+1 N =4 U(Nc) super-Yang-Mills dimensionless effective coupling: Supergravity only in intermediate region:

  13. Itzhaki, Maldacena, Sonnenschein & Yankielowcz (p<5) Gauge/Gravity Duality from Dp-branes: d=10 Type II superstrings in Dp-brane throat with Nc units of RR flux equivalent to all adjoint fields! d=p+1 N =4 U(Nc) super-Yang-Mills dimensionless effective coupling: Supergravity only in intermediate region:

  14. Fundamental matter (with small number of flavours) introduce probe branes e.g., D3/D7 system generalizes to Dp/D(p+4) (p+1)-dim. gauge theory with fundamental matter r, S3 ( embedded in S8–p ) Other systems: Dp/D(p+2) (p+1)-dim. gauge theory with fundamental matter on codim. 1 defect r, S2 ( embedded in S8–p )

  15. Other systems: Dp/D(p+2) (p+1)-dim. gauge theory with fundamental matter on codim. 1 defect r, S2 ( embedded in S8–p ) Dp/Dp (p+1)-dim. gauge theory with fundamental matter on codim. 2 defect r, S1 ( embedded in S8–p ) (have focused on SUSY configurations for stability)

  16. Fundamental fields: Decoupling limitof Nc Dp-branes with Nf Dq-branes Low-energy limit with U(Nc) adjoint Field theory: U(Nc) super-Yang-Mills coupled to Nfmassive hypermultiplets fund. in U(Nc) & global U(Nf) ( SUSY: N =4 → N =2 ) Gravity theory: Dp-throat containing Dq probe brane

  17. Geometry: equator S8-p Dq Sn Free quarks appear with mass: pole

  18. Geometry: equator S8-p Dq Sn Mesons, bound states of fundamental fields, dual to open string states supported by Dq-brane pole

  19. (RCM & Thomson; Arean & Ramallo) Mesons: Calculation of masses for lowest lying mesons as for D3/D7 Veff effective radial potential discrete spectrum r Detailed results numerical as radial ODE has no analytic solution (except in D3 background) Spectra have universal features: discrete, deeply bound, mass gap ) ( with mass scale dictated by Holography!

  20. Holography: (p+2)-dim. gravity (p+1)-dim. gauge theory radius energy (Horowitz & Polchinski) • gravity physics is local in radius gauge physics must be local in energy! Probe brane meson physics focused at r =L supergravity wave-packet

  21. Holography: (Peet & Polchinski) String energy: Supergravity energy: Precisely matches meson energy scale with U=mq ! Locality in energy preserved between open and closed strings! Probe brane meson physics focused at r =L supergravity wave-packet

  22. Mesons: Spectra have universal features: discrete, deeply bound, mass gap ) ( with mass scale dictated by Holography!

  23. Holographic meson scale: • SUSY versus nonSUSY: SUSY embedding: no brane bending nonSUSY embedding: brane bends bare mass = constituent mass bare mass ≠ constituent mass (eg, Sakai & Sugimoto model) Holographic meson scale set by constituent mass! • Goldstone modes: symmetry breaking may require • massless modes

  24. Conclusions/future directions: • holographic meson spectra have universal features: • discrete, deeply bound, mass gap • mass scale dictated by holography • meson interactions: scale as in large N

  25. Meson interactions: Continue expansion of D7-brane action beyond 2nd order • substitute and integrate out r and S3 4th order: agrees with standard large N Applies for general holographic theory of course, for fixed : glueballs mesons

  26. Conclusions/future directions: • holographic meson spectra have universal features: • discrete, deeply bound, mass gap • mass scale dictated by holography • meson interactions: scale as in large N • form factors: proportional to Mgap Hong, Yoon & Strassler (hep-th/0312071)

  27. Hong, Yoon & Strassler (hep-th/0312071) Form factors in D3/D7: • exam mesons with various external probes: where • “charge radius” given by Mgap in particular, does NOT scale with quantum numbers ) (surprise since • similar results should apply in general holographic theory • (since Mgap sets scale of radial profile in all cases)

  28. Observations/future directions: • holographic meson spectra have universal features: • discrete, deeply bound, mass gap • mass scale dictated by holography • meson interactions: scale as in large N • form factors: proportional to Mgap Hong, Yoon & Strassler (hep-th/0312071) • degeneracies broken for nonconformal backgrounds

  29. Degeneracies in meson spectra: • for D3 background/conformal gauge theory with • D7/D5/D3 probe branes, spectra only depend on e.g., = radial AdS quantum # = angular quantum # on S3 = R-charge • NOT true for nonconformal backgrounds: <U> grows <U> shrinks geff grows with <U> geff decreases with <U> in accord with M ~ mq / geff

  30. Observations/future directions: • holographic meson spectra have universal features: • discrete, deeply bound, mass gap • mass scale dictated by holography • meson interactions: scale as in large N • form factors: proportional to Mgap Hong, Yoon & Strassler (hep-th/0312071) • degeneracies broken for nonconformal backgrounds • beyond probe approximation; Nf /Nc finite (see: Burrington et al; Kirsch & Vaman; Casero, Nunez & Paredes)

  31. Beyond probe approximation; Nf /Nc finite • intriguing hint from Erdmenger & Kirsch (hep-th/0408113): study D2/D6 with Nf /Nc finite in far infrared M2/M6 geometric singularity scaling of meson masses match probe results: M ~ mq / geff ~ mq / Nc • perhaps no surprise given demands of holography

  32. Observations/future directions: • holographic meson spectra have universal features: • discrete, deeply bound, mass gap • mass scale dictated by holography • meson interactions: scale as in large N • form factors: proportional to Mgap Hong, Yoon & Strassler (hep-th/0312071) • degeneracies broken for nonconformal backgrounds • beyond probe approximation; Nf /Nc finite (see: Burrington et al; Kirsch & Vaman; Casero, Nunez & Paredes) • mesons with large spin

  33. Mesons with large J (in D3/D7 system): Classical rotating open strings attached to D7-brane Nambu-Goto action: Ansatz: eom: bc: T (string ends to D7)

  34. Spinning meson spectrum: solve E(J) numerically: nonrelativistic Coulomb bound states Regge behaviour applies in general with:

  35. Observations/future directions: • holographic meson spectra have universal features: • discrete, deeply bound, mass gap • mass scale dictated by holography • meson interactions: scale as in large N • form factors: proportional to Mgap Hong, Yoon & Strassler (hep-th/0312071) • degeneracies broken for nonconformal backgrounds • beyond probe approximation; Nf /Nc finite (see: Burrington et al; Kirsch & Vaman; Casero, Nunez & Paredes) • mesons with large spin

  36. Danielsson, Keski-Vakkuri & Kruczenski Holography: “shadows on the wall” AdS/CFT dictionary allows us to see “glue clouds” associated with quark/meson states eg, SUGRA dilaton is dual to ; so evaluate asymptotic dilaton sourced by particular (macroscopic) string configuration for “static quark” (infinite straight string): in agreement with the Wilson loop calculation for the potential between such external quarks Maldacena; Rey & Yee

  37. Dynamical “Quarks”: easy to repeat calculations for finite mass quarks AdS boundary D7 horizon Static/infinite-mass quarks

  38. Holography: for finite mass “quark” (straight string ending on D7): for large |x| for small |x| where ?

  39. Holographic Mesons: A exotic hybrid states Profile A:

  40. Holographic Mesons: A B Profile B:

  41. Holographic Mesons: A C B Profile C:

  42. Conclusions: Flavor physics is fun!

More Related