Preface<\/h2>\n
This is the report to conclude a directed project as part of the requirements to completing the PHYS 349 course at UBC. We present no original work, and this report is mostly a retelling of the story of the AdS\/CFT duality from a combination of sources, mostly from the book “Gauge\/Gravity Duality” by Martin Ammon and Johanna Erdmenger, “Introduction to the AdS\/CFT Correspondence” by Jan de Boer [6], “The AdS\/CFT Correspondence” by Veronika E. Hubeny [11] and “AdS\/CFT Correspondence in Condensed Matter” by A.S.T Pires [15]. The calculations were directed by Dr. Gordon Walter Semenoff (Department of Physics, The University of British Columbia)<\/p>\n
Table of Contents<\/h2>\n
Table of Contents……………………………………………………………………………… iv<\/p>\n
List of Figures…………………………………………………………………………………… vi<\/p>\n
Acknowledgments……………………………………………………………………………. vii<\/p>\n
1 Introduction…………………………………………………………………………………… 1<\/p>\n
2 Taking the Large N Limit and Holography……………………………………………… 3<\/p>\n
3 Anti-de Sitter Space…………………………………………………………………………. 5<\/p>\n
4 Correlation Functions………………………………………………………………………. 7<\/p>\n
5 Derivation of the Ads\/CFT Correspondence………………………………………….. 9<\/p>\n
5.0.1 Mapping between parameters……………………………………………………. 11<\/p>\n
5.0.2 Turning off Quantum Fluctuations, and the weak form ofthe Correspondence 12<\/p>\n
6 Probing a Strongly Correlated CFT with a D5-Brane………………………………. 13<\/p>\n
6.0.1 Maxwell’s Action on the D5 Brane……………………………………………….. 16<\/p>\n
6.0.2 Extracting the AC-Conductivity……………………………………………………. 21<\/p>\n
7 Epilogue………………………………………………………………………………………. 25<\/p>\n
Bibliography…………………………………………………………………………………… 27<\/p>\n
List of Figures<\/h3>\n
Figure 6.1 A D5 brane is held perpendicular to a stack of an infinite number of coincident D3 branes that are at r<\/em> = 0. The stack of D3 branes extends along the spacetime directions x<\/em>0<\/sup>,x<\/em>1<\/sup>,x<\/em>2<\/sup>,x<\/em>3<\/sup>, and are transversal to the other six spatial directions x<\/em>4<\/sup>,…x<\/em>9<\/sup> . In the limit depicted in the figure, the strings in the bulk are rigid, and we solve Maxwell’s equations on the surface of the D5-brane to extract the two-point current correlation function at the boundary (r<\/em> = \u221e). In essence, we are looking for this particular operator on the “upper edge” of the infinite square depicted as the D5 brane in this figure. . . . . . . . . . . . . . 14<\/p>\n The AdS\/CFT Correspondence has become very important in the last two decades, with thousands of papers having been published in high energy Physics. While still a conjecture not having been proved, there is substantial evidence to believe that it holds. One reason for its importance is that it can be used to understand strongly interacting field theories by mapping them into classical gravity in one extra dimension. The idea is that large-N gauge theories (strongly coupled conformal field theories) in d-dimensions is mapped to a gravitational theory in d+1 dimensions which is asymptotically AdS. This happens to be a strong-weak duality where if for example, the field theory is strongly coupled, the gravity theory is weakly coupled and vice versa. The most well-known form of this that the correspondence takes, originally conjectured by Maldacena [12], is that between 4-dimensional N<\/em> = 4 supersymmetric Yang-Mills theory and type IIB string theory on AdS<\/em>5<\/sub> \u00d7S<\/em>5<\/sup> – which is a 10-dimensional world where AdS<\/em>5<\/sub> refers to Anti de-Sitter space in 5 dimensions and the S<\/em>5<\/sup> to a 5-dimensional sphere. Anti-de Sitter spaces are maximally symmetric solutions of the Einstein equations with a negative cosmological constant [6]. N<\/em> = 4 super Yang-Mills theory was known to be conformally invariant (making this quantum field theory a conformal field theory, or a CFT), and it turns out that its group of conformal symmetries matches up exactly with the large symmetry group of 5-dimensional Anti-de Sitter space. Different CFTs in d-dimensions will generally correspond to theories of gravity with different field content and different parameters in the bulk (d+1 dimensions). Different arguments have shown that quantum field theories are actually quantum theories of gravity and so we can use them to compute observables of the QFT when the gravity theory is classical [13]. This fact we will use in this report.<\/p>\n Notice that the AdS\/CFT correspondence takes a gravity theory in d+1 dimensions and relates it to a non-gravitational one in d-dimensions. String theory provides a means to compute finite quantum corrections to classical gravity, but its full non-perturbative structure is still not well understood [6]. If the AdS\/CFT correspondence is true, this means that the actual quantum degrees of freedom cannot be the same as that of a local field theory that lives on the same space. If gravity had degrees of freedom that were local, we could take arbitrarily large volumes of fixed energy density – but we know from classical gravity that such a thing would eventually collapse to form a black hole. Clues for this gauge-gravity duality have been around for some time – in three dimensions in particular . It turns out that in the 3dimensional case, gravity can be described by Chern-Simons theory [1, 22].ChernSimons theory is a topological field theory that reduces to a 2-dimensional field theory when put in a manifold with a boundary [21] [6]. A precise relation between Hilbert spaces and correlation functions in compact gauge groups could be established – while for non-compact gauge groups this precise relationship is not well understood. Nevertheless this duality between Chern-Simmons theory and two-dimensional conformal field theory has many similarities to the AdS\/CFT duality [6].<\/p>\n Here we will primarily work with a weaker form of the AdS\/CFT correspondence by working in the low-energy limit in the string theory side. At very low energies, it is known that type IIB string theory on AdS<\/em>5<\/sub> \u00d7S<\/em>5<\/sup> reduces to type IIB supergravity on AdS<\/em>5<\/sub> \u00d7S<\/em>5<\/sup>. Correspondingly, we end up taking a limit on the N<\/em> = 4 supersymmetric field theory side where the rank of the U<\/em>(N<\/em>) gauge group, N<\/em> (not the same as the earlier N<\/em>) and gYM<\/sub><\/em>2<\/sup> both become large. In this limit, the equivalence between type IIB supergravity on AdS<\/em>5<\/sub> \u00d7S<\/em>5<\/sup> and N<\/em> = 4 gauge theory has been well tested [6].<\/p>\n The AdS\/CFT correspondence is associated to two ideas in Physics. The first is that large N gauge theory is equivalent to a string theory [19]. In terms of 1\/N<\/em> and gYM<\/sub><\/em>2<\/sup> , the perturbative expansion of a large N gauge theory has the following form:<\/p>\n Z<\/em> = \u2211 N<\/em>2<\/sup>\u22122g<\/em><\/sup> fg<\/sub><\/em>(\u03bb<\/em>) (2.1)<\/p>\n g<\/em>\u22650<\/p>\n where \u03bb<\/em> = gYM<\/sub><\/em>2<\/sup> N<\/em> is called the ‘t Hooft coupling constant. This is reminiscent of the loop expansion in string theory:<\/p>\n Z<\/em> g<\/em>\u22650<\/p>\n – if we replace the string coupling constant gs<\/sub><\/em> with 1\/N<\/em>. Through some mechanism, Feynman diagrams of the gauge theory are turned into surfaces that represent strings [14] – and apparently this is exactly what happens in the AdS\/CFT correspondence.<\/p>\n The second idea in Physics is that of “holography” [17, 20]. This idea is related to the thermodynamics of black holes. Hawking and Bekenstein showed that black holes can be seen as thermodynamic entities [4, 5, 9].Thus they have entropies and temperatures. The black body radiation that the black hole emits relate directly to its temperature, while its entropy is given by S<\/em> = c<\/em>3<\/sup>A<\/em>\/<\/em>4Gh<\/em>\u00af, where A<\/em> is the surface area of the event horizon of the black hole, and G<\/em> the Newton constant. These definitions make the laws of thermodynamics consistent with Einstein’s equations of general relativity. The entropy of a system can be viewed as its “information content”. It is a measure of the number of degrees of freedom that a theory has – and so it is surprising that the entropy of a black hole scales with its horizon area, and not its volume. Local field theories have their entropies proportional to their volume, so it cannot be that gravity behaves like a local field theory. It turns out that if we assume that gravity in d<\/em> +1 dimensions is somehow equivalent to a local field theory in d<\/em> dimensions, we reach a consistent picture. This is where this idea in Physics gets its name of “holography”- it is like a hologram where 3-dimensional information is encoded in a 2-dimensional surface. The AdS\/CFT correspondence is therefore holographic, since it states that quantum gravity in 5dimensions (forgetting the 5-sphere) is equivalent to a field theory in 4 dimensions [6].<\/p>\n The Anti-de Sitter space belongs to a wide class of homogeneous spaces that can be defined as quadric surfaces in flat vector spaces [15]. An example is the ddimensional sphere Sd<\/sup><\/em> given by:<\/p>\n X<\/em> embedded in Euclidean d+1 dimensional space. The d-dimensional anti-de Sitter space can be defined:<\/p>\n d<\/em>\u22121<\/p>\n X<\/em> i<\/em>=1<\/p>\n embedded in flat d+1 dimensional space with the metric:<\/p>\n d<\/em>\u22121<\/p>\n ds<\/em> i<\/em>=1<\/p>\n This has constant negative curvature [15].Of course, this can be written in different coordinate systems, and in the Poincare coordinates\u00b4 (r<\/em>,t<\/em>,~x<\/em>),<\/em>r<\/em> ><\/em> 0,~x<\/em> \u2208 Rd<\/sup><\/em>\u22122<\/sup> given by [2]:<\/p>\n X<\/em>0<\/sub> = 2r<\/em><\/p>\n Xi<\/sup><\/em> = Rrxi<\/sup><\/em>, <\/em> (i<\/em> = 1,….,d<\/em> \u22122)<\/p>\n Xd<\/sup><\/em>\u22121<\/sup> = 2r<\/em><\/p>\n the anti-de Sitter metric then becomes<\/p>\n<\/td>\n (3.4)<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n 1<\/sup><\/p>\n ds<\/em> grr<\/sub><\/em> g<\/em>xx<\/em> = g<\/em>yy<\/em> = g<\/em>zz<\/em> = r<\/em>2,<\/em><\/p>\n<\/td>\n g<\/em>tt<\/em> = \u2212r<\/em>2<\/p>\n<\/td>\n (3.6)<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n r<\/em><\/p>\n The limit where the radial coordinate r<\/em> goes to infinity is called the boundary of the anti-de Sitter space . The boundary is the place where the dual field theory lives [6]. It turns out that string theory excitations extend all the way to the boundary of the space [7]. In this way it is possible to obtain a map from string theory states in the bulk to states in the field theory living in the boundary. It also seems that r<\/em> can be seen as a dimension of scale of the dual field theory [18].<\/p>\n Maldacena’s paper [12], proposed a form of the AdS\/CFT correspondence but did not yet provide a map between the two sides. In [23] and [8] such a map was given and makes the correspondence clear. To illustrate, we consider a free field with a mass m<\/em> on the AdS side, propagating in anti-de Sitter space. We see that the field equation:<\/p>\n (+m<\/em>2<\/sup>)\u03c6<\/sub><\/em> = 0<\/p>\n has two linearly independent solutions that behave like [6] :<\/p>\n<\/td>\n (4.1)<\/p>\n<\/td>\n<\/tr>\n e<\/em>\u2212\u2206r<\/em>, e<\/em>(\u2206\u22124)r<\/em><\/p>\n as r<\/em> \u2192 \u221e, where<\/p>\n<\/td>\n (4.2)<\/p>\n<\/td>\n<\/tr>\n \u2206(\u2206\u22124) = m<\/em>2<\/sup><\/p>\n<\/td>\n (4.3)<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n Now let us consider a solution of the supergravity equations of motion , possessing the boundary condition that near r<\/em> = \u221e , the fields behave as [6]:<\/p>\n The map between AdS and CFT quantities is then given by:<\/p>\n exp<\/em> \u2212Ssugrav<\/sub><\/em> The left hand side of the above is the supergravity action evaluated on the classical solution given by \u03c6i<\/sub><\/em> , with the right hand side being a generating function for correlation functions in Yang-Mills theory [6]. For most applications, the above suffices, but it’s important to note that the left hand side is really an approximation – and we should really use the full string theory partition function subject to the relevant boundary conditions, to which our supergravity approximation is a saddlepoint approximation [11]:<\/p>\n Zstring<\/sub><\/em> We see that there is an operator Oi<\/sub><\/em> in Yang-Mills theory corresponding to every bulk field \u03c6i<\/sub><\/em> (in AdS). We can use symmetries to find which boundary operators (in the field theory side) , map to which fields (in the bulk, that is, the AdS side). The two sides must have the same quantum numbers and Lorentz structure [11].As an example, conserved currents in the field theory side correspond to global symmetries and therefore their corresponding sources act as external background gauge fields, which are boundary values of dynamical gauge fields in the AdS side (the bulk) [11]. We will use the above to find the “two point” current correlation function in the subsequent sections.<\/p>\n To do the derivation of the AdS\/CFT correspondence given in Maldacena’s original paper [12], we need the idea of D-branes (or Dirichlet branes). Polchinski introduced them in [16] as extended objects in string theory. The number of spatial dimensions they have give them a label – D0 branes are like particles, D1 branes are strings , D2 branes are like sheets etc. We have two ways to think about D-branes . The first one is as solitonic solutions to the equations of motion of low energy string theory , that is, of supergravity . (this perspective is reliable for Introduction<\/h2>\n
Taking the Large N Limit and Holography<\/h2>\n
![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528001.jpg\")
Zg <\/sub><\/em> (2.2)<\/p>\nAnti-de Sitter Space<\/h2>\n
![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528002.jpg\")
(3.1)<\/p>\n![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528003.jpg\")
R<\/em>2 <\/sup> (3.2)<\/p>\n![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528004.jpg\")
dXi<\/sub><\/em>2 <\/sup> (3.3)<\/p>\n![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528005.jpg\")
1 [1+r<\/em>2<\/sup>(R<\/em>2<\/sup> +~<\/em>x<\/em>2<\/sup> \u2212t<\/em>2<\/sup>)], <\/em> Xd<\/sub><\/em> = Rrt<\/em><\/p>\n\n\n
\n \n [1\u2212r<\/em>2<\/sup>(R<\/em>2<\/sup> \u2212~<\/em>x<\/em>2<\/sup> +t<\/em>2<\/sup>)],<\/em><\/p>\n\n ![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528006.jpg\")
(3.5)<\/p>\n\n\n
\n \n ![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528007.jpg\")
,<\/em><\/p>\n<\/td>\n\n \n \n Correlation Functions<\/h2>\n
\n\n
\n \n \n \n \n \n \n \n \n ![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528008.jpg\")
e<\/em>(\u2206\u22124)r <\/em> (4.4)<\/p>\n![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528009.jpg\")
(4.5)<\/p>\n![\"\"](\"https:\/\/images.ukessays.com\/111021\/0718528010.jpg\")
(4.6)<\/p>\nDerivation of the Ads\/CFT Correspondence<\/h2>\n