AdS/CFT

Autumn '07

Andy O'Bannon
Abstract - After (very) brief reviews of holography and string theory, I will sketch the original motivation for AdS/CFT, Maldacena's low-energy decoupling limit of very many D3-branes. Minimal familiarity with strings and D-branes is assumed. I end with the precise statement of the correpondence and an explanation for the rationale behind our choice and ordering of topics for the quarter. A good paper to read for today (because it is short), or for Friday, is 0709.1523 Mateos "String Theory and Quantum Chromodynamics", sections 1 - 3.
Refs -
- Mateos, "String Theory and Quantum Chromodynamics", sections 1 - 3, arXiv:0709.1523

Steve Paik
Abstract - The N=4 theory has the maximal amount of supersymmetry for an interacting quantum field theory in four dimensions with massless particles of spin <= 1. The supersymmetry is so restrictive that the theory is specified only by the choice of a gauge group, which we take to be SU(N_c), and a value of the coupling constant. We will discuss the field content of this theory and write down its Lagrangian by dimensionally reducing the N=1 Super Yang-Mills theory in ten dimensions. Then we will discuss the bosonic and fermionic symmetries and sketch the Lie algebra in a way that is easy to remember. Next we will prove that the beta function for the coupling is zero using a nonperturbative argument due to Seiberg, showing that the theory is quantum mechanically conformal. The notion of superconformal primary operators will be explained. Finally, we will show that 2 and 3 point functions are heavily constrained by the conformal symmetry.
Refs -
- D'Hoker and Freedman, pp.16-21
- Maldacena, et al. (MAGOO), hep-th/9905111, pp.30-36, 70-72

Chris Vermilion
Abstract - I will begin by discussing the conformal structure of flat (Minkowski) space. I will then introduce (p+2) dimensional Anti-de Sitter space as a hyperboloid surface in (p+3) dimensional flat space with (-,-,+,+,+,...) signature. I will discuss a few useful sets of coordinates and metrics on AdS space, building toward a discussion of the boundary. I will show that the boundary of conformally compactified AdS space is equivalent to a conformally compactified Minkowski space in one fewer dimension.
Refs -
- MAGOO, pp. 36-45
- Witten, hep-th/9802150, pp. 1-5

Kristan Jensen
Abstract - Our goal today is to understand the spectroscopy of Type IIB SUGRA on AdS5 x S5. We will begin by reviewing the theory in (9+1) dimensions and then compactify to (4+1) dimensions. To map out the spectrum of the compactified theory, we will perform harmonic analysis on the compact space and thereby generate the Kaluza-Klein modes of the theory. We will conclude with a few notes on the masses of propagating fields in AdS. We will emphasize the symmetries of the theory (compact, noncompact) throughout the talk.
Refs -
- D'Hoker & Freedman, hep-th/0201253, primarily chapter 4
- MAGOO. Sensibly, of course
- Kim, Romans, van Nieuwenhuizen, PRD, 32, 389 (1985)

Andrew Lytle
Abstract - D-branes are objects arising in string theory that have descriptions in terms of gauge theory. Today we will attempt to make this statement more precise, leading us to an understanding of d-brane configurations that can be approximated by N=4 SYM in 3+1 dimensions-- one half of the AdS/CFT correspondence.
Refs -
- Zwiebach has nice material about D-branes as classical string boundary conditions.
- Johnson's book "D-Branes" is what I studied for discussing the Dirac-Born-Infeld action.

Paul Chesler
Abstract -
Refs -
- Maldacena's orginal paper: hep-th/9711200
- Klebanov TASI lecture: hep-th/0009139

Ethan Thompson
Abstract - The method of calculating correlation functions in a conformal field theory using AdS/CFT will be developed. The field- operator mapping will be discussed. The calculation of scalar correlation functions in Euclidean space will be demonstrated, and the correspondence between the masses of fields in AdS space and the dimension of operators on the field theory side will be shown. Correlation functions of conserved currents will be briefly touched upon. Time permitting, the differences of working in Lorentz signature spacetime will be outlined.
Refs -
- Witten, hep-th/9802180
- Freedman et al, hep-th/9804058
- MAGOO, section 3.3

Chris Spitzer
Abstract - I'll be talking about UV/IR relations and the renormalization group equation derived from AdS/CFT.
Refs -
- Susskind & Witten, "The Holographic Bound in Anti-de Sitter Space" hep-th/9805114
- Balasubramanian & Kraus, "Spacetime and the Holographic Renormalization Group" [http:arxiv.org/abs/hep-th/9903190 hep-th/9903190]

Jon Walsh
Abstract - The title of my talk is "Calculating the expectation value of Wilson loops using the AdS/CFT correspondence".
Refs -
- Maldacena, "Wilson loops in large N field theories", hep-th/9803002
- Rey et. al., "Wilson-Polyakov loop at finite temperature in large N gauge theory and AdS supergravity", hep-th/9803135
- Brandhuber et. al., "Wilson loops in the large N limit at finite temperature", hep-th/9803137

Rob Schabinger
Abstract - I'll be discussing the recent results of Alday and Maldacena on four gluon scattering at strong coupling in the AdS/CFT correspondence.
Refs -
- J. Maldacena and L. Alday "Gluon Scattering Amplitudes at Strong Coupling" [http:arxiv.org/abs/0705.0303 arXiv:0705.0303]
- Z. Bern, L. Dixon, and V. Smirnov "Iteration of Planar Amplitudes in Maximally Supersymmetric Yang-Mills Theory at Three Loops and Beyond" hep-th/0505205