1 / 16

AGT 関係式 (2) AGT 関係式 (String Advanced Lectures No.19)

AGT 関係式 (2) AGT 関係式 (String Advanced Lectures No.19). 高エネルギー加速器研究機構 (KEK) 素粒子原子核研究所 (IPNS) 柴 正太郎 2010 年 6 月 9 日(水) 12:30-14:30. Contents. 1. Gaiotto’s discussion for SU(2) 2. SU(2) partition function 3. Liouville correlation function 4. Seiberg-Witten curve and AGT relation

valora
Télécharger la présentation

AGT 関係式 (2) AGT 関係式 (String Advanced Lectures No.19)

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. AGT関係式(2) AGT関係式(String Advanced Lectures No.19) 高エネルギー加速器研究機構(KEK) 素粒子原子核研究所(IPNS) 柴 正太郎 2010年6月9日(水) 12:30-14:30

  2. Contents 1. Gaiotto’s discussion for SU(2) 2. SU(2) partition function 3. Liouville correlation function 4. Seiberg-Witten curve and AGT relation 5. Towards generalized AGT relation

  3. Gaiotto’s discussion for SU(2) [Gaiotto ’09] SU(2) gauge theory with 4 fundamental flavors (hypermultiplets) • S-duality group SL(2,Z) • coupling const. : • flavor sym. : SO(8) ⊃ SO(4)×SO(4) ~ [SU(2)a×SU(2)b]×[SU(2)c×SU(2)d] • : (elementary) quark • : monopole • : dyon

  4. SU(2) gauge theory with massive fundamental hypermultiplets • Subgroup of S-duality without permutation of masses • In massive case, we especially consider this subgroup. • mass : mass parameters can be associated to each SU(2) flavor. • Then the mass eigenvalues of four hypermultiplets in 8v is , . • coupling : cross ratio (moduli) of the four punctures, i.e. z= • Actually, this is equal to the exponential of the UV coupling • → This is an aspect of correspondence between the 4-dim N=2 SU(2) gauge theory and the 2-dim Riemann surface with punctures.

  5. SU(2) partition function Nekrasov’s partition function of 4-dim gauge theory Now we calculate Nekrasov’s partition function of 4-dim SU(2) quiver gauge theory as the quantity of interest. • Action • classical part • 1-loop correction : more than 1-loop is cancelled, because of N=2 supersymmetry. • instanton correction : Nekrasov’s calculation with Young tableaux • Parameters • coupling constants • masses of fundamental/antifund./bifund. fields and VEV’s of gauge fields • deformation parameters : background of graviphoton or deformation of extra dimensions (Note that they are different from Gaiotto’s ones!)

  6. gauge bifund. fund. antifund. 1-loop part of partition function of 4-dim quiver gauge theory • We can obtain it of the analytic form : • where each factor is defined as VEV mass mass mass deformation parameters : each factor is a product of double Gamma function! ,

  7. Instanton part of partition function of 4-dim quiver gauge theory We obtain it of the expansion form of instanton number : where : coupling const.and and Young tableau arm leg < Young tableau> instanton # = # of boxes

  8. SU(2) with four flavors : Calculation of Nekrasov function for U(2) • The Nekrasov partition function for the simple case of SU(2) with four flavors is • Since the mass dimension of is 1, so we fix the scale as , . • (by definition) • Mass parameters : mass eigenvalues of four hypermultiplets • : mass parameters of • : mass parameters of • VEV’s : we set --- decoupling of U(1) (i.e. trace) part. • We must also eliminate the contribution from U(1) gaugemultiplet. • This makes the flavor symmetry SU(2)i×U(1)i enhanced to SU(2)i×SU(2)i. • (next page…) U(2), actually Manifest flavor symmetry is now U(2)0×U(2)1 , while actual symmetry is SO(8)⊃[SU(2)×SU(2)]×[SU(2)×SU(2)].

  9. SU(2) with four flavors : Identification of SU(2) part and U(1) part • In this case, Nekrasov partition function can be written as • where and • is invariant under the flip(complex conjugate representation) : • which can be regarded as the action of Weyl group of SU(2) gauge symmetry. • is not invariant. This part can be regarded as U(1) contribution. • Surprising discovery by Alday-Gaiotto-Tachikawa • In fact, is nothing but the conformal block of Virasoro algebra with • for four operators of dimensions inserted at : (intermediate state)

  10. Liouville correlation function Correlation function of Liouville theory with. • Thus, we naturally choose the primary vertex operator as the examples of such operators. Then the 4-point function on a sphere is • 3-point function conformal block • where • The point is that we can make it of the form of square of absolute value! • … only if • … using the properties : and

  11. Example 1 : SU(2) with four flavors (Sphere with four punctures) • As a result, the 4-point correlation function can be rewritten as • where and • It says that the 3-point function (DOZZ factor) part also can be written as the product of 1-loop part of 4-dim SU(2) partition function : • under the natural identification of mass parameters :

  12. Example 2 : Torus with one puncture • The SW curve in this case corresponds to 4-dim N=2* theory : • N=4 SU(2) theory deformed by a mass for the adjoint hypermultiplet • Nekrasov instanton partition function • This can be written as • where equals to the conformal block of Virasoro algebra with • Liouville correlation function (corresponding 1-point function) • where is Nekrasov’s partition function.

  13. Example 3 : Sphere with multiple punctures • The Seiberg-Witten curve in this case corresponds to 4-dim N=2 linear quiver SU(2) gauge theory. • Nekrasov instanton partition function • where equals to the conformal block of Virasoro algebra with for the vertex operators which are inserted at z= • Liouville correlation function (corresponding n+3-point function) • where is Nekrasov’s full partition function.

  14. SW curve and AGT relation Seiberg-Witten curve and its moduli • According to Gaiotto’s discussion, SW curve for SU(2) case is . • In massive cases, has double poles. • Then the mass parameters can be obtained as , • where is a small circle around the a-th puncture. • The other moduli can be fixed by the special coordinates , • where is the i-th cycle (i.e. long tube at weak coupling). • Note that the number of these moduli is 3g-3+n. • (g : # of genus, n : # of punctures)

  15. 2-dim CFT in AGT relation : ‘quantization’ of Seiberg-Witten curve?? • The Seiberg-Witten curve is supposed to emerge from Nekrasov partition function in the “semiclassical limit” , so in this limit, we expect that . • In fact, is satisfied on a sphere, • then has double poles at zi . • For mass parameters, we have , • where we use and . • For special coordinate moduli, we have , • which can be checked by order by order calculation in concrete examples. • Therefore, it is natural to speculate that Seiberg-Witten curve is ‘quantized’ to at finite .

  16. … … … Towards generalized AGT • Natural generalization of AGT relation seems the correspondence between partition function of 4-dim SU(N) quiver gauge theory and correlation function of 2-dim AN-1 Toda theory : • This discussion is somewhat complicated, since in SU(N>2) case, the punctures are classified with more than one kinds of N-box Young tableaux : < full-type > < simple-type > < other types > (cf. In SU(2) case, all these Young tableaux become ones of the same type .) [Wyllard’09] [Kanno-Matsuo-SS-Tachikawa’09] … … …

More Related