The Partonic Nature of Instantons

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Transcription:

The Partonic Nature of Instantons David Tong Work in progress with Ben Collie Shifmania, May 2009

Happy Birthday Misha!!

What are Instantons Made of? Instantons have a number of collective coordinates: SU(N) Yang-Mills 4 translations, 1 scale size, 4N-5 orientation 4N in total CP N Sigma-Model 2 translations, 1 scale size, 2N-3 orientations 2N in total An old idea: Instantons are composed of N partons Belavin et al 79

The Partonic Nature of Instantons The conjecture of partons usually framed for d=3+1 dimensions (for Yang-Mills) d=1+1 dimensions (for sigma-models) Here we revisit this idea in context of d=4+1 dimensions (for Yang-Mills) d=2+1 dimensions (for sigma-models) Theories are non-renormalizable (effective theories) Instantons are particle-like excitations Is the single instanton a multi-particle state? and how can we tell?

5d Yang-Mills There exists a UV completion of gauge theories in d=4+1 dimensions (at least with supersymmetry) but we don t know much about it Seiberg 96 With N=2 supersymmetry, the UV completion is the (2,0) theory in d=5+1 dimensions The UV completion has N 3 degrees of freedom. Klebanov and Tseytlin 96

The Instanton The instanton is the KK mode from the sixth dimension M inst = 8π2 e 2 = 1 R Rozali, 97 Proposal: The instanton is an N-particle state The N partons inside the instanton are the remnant of the UV degrees of freedom which comprise the (2,0) theory.

Circumstantial Evidence Turn up the heat and look at cross-over in free-energy Itzhaki et al 98 F N 2 T 5 RN 3 T 6 The transition happens at the temperature T 1 NR 1 e 2 N This had to be the case: this is where the 5d theory is strongly coupled, so this is where we need new UV degrees of freedom.

More Circumstantial Evidence Anomaly coefficient for G = ADE is conjectured to be Intriligator, 00 c 2 (G) G dual coxeter number = number of instanton moduli dimension of group Are the partons in the adjoint of G? What is the mechanism that confines them? Quantizing the scale size of the instanton gives a continuous spectrum natural for a multi-particle state. But the moduli space is not that of N free objects does this contain clues about confining mechanism?

A Toy Model These questions are difficult to answer in case of Yang-Mills The CP N sigma-model provides (as always!) a nice toy-model where we can see how some of these issues are resolved.

A Toy Model Our toy will be in d=2+1 dimensions It is a gauge theory with N=4 supersymmetry Intriligator and Seiberg, 96 Vector multiplet: Hypermultiplet: V =(A µ,φ i,fermions) Q=(q, q,fermions) i=1,2,3 U(1) N + N hypermultiplets gauge coupling = g 2 mass of hypers = m

The Low-Energy Dynamics The hypermultiplets have physical mass bare mass M a =(φ a φ a+1 +m) vevs of vector multiplets At low energies, we want an effective action for the massless vector multiplets φ a i and F a µν =g 2 ǫ µνρ ρ σ a

Low-Energy Dynamics Intriligator and Seiberg, 96 We integrate out the hypermultiplets This induces interactions for vector multiplets The low-energy dynamics is a sigma-model with target space R 4 T CP N 1 CP N 1

An Example: CP 1 Diagonal U(1) decouples Axial U(1) has two hypers, with charge +1 and -1 Integrate out hypers: L eff = 1 g 2 eff 1 g 2 eff ( φ) 2 +g 2 eff ( σ)2 = 1 g 2 + 1 m φ + 1 m+φ σ g 2 φ

The Soliton The low-energy theory has a soliton: it is a sigma-model lump 2 translation modes 1 scale size 2N-3 orientation modes µ φ=g 2 eff (φ)ǫ µν ν σ What is this soliton in the microsopic theory? It is BPS Mass = Nm Q 1 It is an N-particle state. The soliton is made of the objects that we thought we d integrated out! Q 2 Q 3 Q 1 Q 2 Q 3...Q N Aharony, Hanany, Intriligator, Seiberg and Strassler, 97

Reconstructing the UV Physics Question: Suppose we just have access to the IR physics on the Coulomb branch. What does the soliton tell us about the UV completion? Answer: Pretty much everything!

Seeing the Partons CP N 1 We get the round metric on only in the limit g 2 If we study solitons on the squashed target space, the solitons dramatically reveal themselves. Here s a soliton on CP 1 m/g 2 =0 m/g 2 =1 m/g 2 =2

Seeing the Partons Here s a single soliton on a squashed CP 2

Changing the Orientation Keep the scale size of the lump fixed Change the orientation modes Watch the partons move

Confinement of Partons Why does the low-energy theory only include the N-particle state? Q 1 Q 2...Q N Answer from microscopic theory: logarithmic confinement In d=2+1 dimensions, electric charges have This gives log divergent mass Only gauge singlet states have finite mass E 1 r This log divergence re-appears when partons move. Seen in IR theory as a log divergence in moduli space metric. Only modes which don t change dipole moments have finite norm

Parton Quantum Numbers Can we reconstruct the quantum numbers of the partons? In other words, can we reconstruct the full UV theory?

Dual Bogomolnyi Equations The Bogomonyi equations for CP are µ φ=g 2 eff (φ)ǫ 0µν ν σ 1 They have a moduli space of solutions: dimension 2kN for k soliton sector Can rewrite this equation in dual variables F µν =g 2 eff (φ)ǫ µνρ ρ σ F 0µ = ν φ

Dual Bogomolnyi Equations F 0µ = ν φ The dual Bogomolnyi equations have no smooth solutions But we can reproduce the exact soliton solution if we introduce electric sources µ ( 1 g 2 eff F 0µ )= k n=1 δ(z z + n) δ(z z n) In soliton description, these are collective coordinates. Here, they are sources.

Dual Bogomolnyi Equation The dual formulation of the Bogomolnyi equation provides an explicit map between a soliton and fundamental fields It also works for CP N-1 Can reconstruct quantum numbers of partons which determines the UV microscopic theory

Calorons: A Red Herring? There is one way that instantons are known to split into N partons Calorons Lee and Yi, Van Baal Put d=4+1 theory on circle. Add a Wilson line. Instantons N monopole strings Doesn t seem possible that this can happen in non-compact space Also happens for lumps in the toy model But the calorons have nothing to do with the true partons

Summary: Questions, not Answers Toy model in d=2+1 Explicit demonstration that solitons can be thought of as multi-particle states A study of the soliton allows us to reconstruct the UV behaviour Real Interest: d=4+1 Yang-Mills Does the instanton solution hold clues about the constituents of the (2,0) theory? What is the confinement mechanism? No hint of log confinement partons are probably not merons

Happy Birthday Misha!!

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