Sypersymmetries and Quantum Symmetries Dubna 2007 K.Stepanyantz Moscow State University Department of Theoretical Physics New identity for Green function.

Slides:

Advertisements

Similar presentations

Boyce/DiPrima 9th ed, Ch 2.8: The Existence and Uniqueness Theorem Elementary Differential Equations and Boundary Value Problems, 9th edition, by William.

Advertisements

Summing planar diagrams

Vertex Function of Gluon-Photon Penguin Swee-Ping Chia High Impact Research, University of Malaya Kuala Lumpur, Malaysia

Electrostatic energy of a charge distribution.

Spinor Gravity A.Hebecker,C.Wetterich.

L2:Non-equilibrium theory: Keldish formalism

QCD-2004 Lesson 1 : Field Theory and Perturbative QCD I 1)Preliminaries: Basic quantities in field theory 2)Preliminaries: COLOUR 3) The QCD Lagrangian.

On Interactions in Higher Spin Gauge Field Theory Karapet Mkrtchyan Supersymmetries and Quantum Symmetries July 18-23, 2011 Dubna Based on work in collaboration.

Lattice Spinor Gravity Lattice Spinor Gravity. Quantum gravity Quantum field theory Quantum field theory Functional integral formulation Functional integral.

3rd International Workshop On High Energy Physics In The LHC Era.

Happy 120 th birthday. Mimeograph Constraining Goldstinos with Constrained Superfields Nathan Seiberg IAS Confronting Challenges in Theoretical Physics.

Some questions on quantum anomalies Roman Pasechnik Moscow State University, Moscow & Bogoliubov Lab of Theoretical Physics, JINR, Dubna 46-th Cracow School.

Supersymmetry and Gauge Symmetry Breaking from Intersecting Branes A. Giveon, D.K. hep-th/

Gerard ’t Hooft Spinoza Institute Yukawa – Tomonaga Workshop, Kyoto, December 11, 2006 Utrecht University.

Chiral freedom and the scale of weak interactions.

QCD – from the vacuum to high temperature an analytical approach an analytical approach.

1 A. Derivation of GL equations macroscopic magnetic field Several standard definitions: -Field of “external” currents -magnetization -free energy II.

Planar diagrams in light-cone gauge hep-th/ M. Kruczenski Purdue University Based on:

The 2d gravity coupled to a dilaton field with the action This action ( CGHS ) arises in a low-energy asymptotic of string theory models and in certain.

Masses For Gauge Bosons. A few basics on Lagrangians Euler-Lagrange equation then give you the equations of motion:

Lecture 35 Numerical Analysis. Chapter 7 Ordinary Differential Equations.

Ｍ ultiverse and the Naturalness Problem Hikaru KAWAI 2012/ 12/ 4 at Osaka University.

HOLOGRAPHY, DIFFEOMORHISMS, AND THE CMB Finn Larsen University of Michigan Quantum Black Holes at OSU Ohio Center for Theoretical Science September

Monday, Apr. 2, 2007PHYS 5326, Spring 2007 Jae Yu 1 PHYS 5326 – Lecture #12, 13, 14 Monday, Apr. 2, 2007 Dr. Jae Yu 1.Local Gauge Invariance 2.U(1) Gauge.

“Time-reversal-odd” distribution functions in chiral models with vector mesons Alessandro Drago University of Ferrara.

Constraints on renormalization group flows Based on published and unpublished work with A.Dymarsky,Z.Komargodski,S.Theisen.

Curvature operator and gravity coupled to a scalar field: the physical Hamiltonian operator (On going work) E. Alesci, M. Assanioussi, Jerzy Lewandowski.

Quantum Field Theory in de Sitter space Hiroyuki Kitamoto (Sokendai) with Yoshihisa Kitazawa (KEK,Sokendai) based on arXiv: [hep-th]

Higher Derivative Scalars in Supergravity Jean-Luc Lehners Max Planck Institute for Gravitational Physics Albert Einstein Institute Based on work with.

The nonabelian gauge fields and their dynamics in the finite space of color factors Radu Constantinescu, Carmen Ionescu University of Craiova, 13 A. I.

Wednesday, Apr. 23, 2003PHYS 5326, Spring 2003 Jae Yu 1 PHYS 5326 – Lecture #24 Wednesday, Apr. 23, 2003 Dr. Jae Yu Issues with SM picture Introduction.

Takaaki Nomura(Saitama univ) collaborators Joe Sato (Saitama univ) Nobuhito Maru (Chuo univ) Masato Yamanaka (ICRR) arXiv: (to be published on.

Announcements 10/22 Today: Read 7D – 7F Wednesday: 7.3, 7.5, 7.6 Friday: 7.7, 9, 10, 13 On Web Exam 1 Solutions to Exam 1.

Derivation of the Friedmann Equations The universe is homogenous and isotropic  ds 2 = -dt 2 + a 2 (t) [ dr 2 /(1-kr 2 ) + r 2 (dθ 2 + sinθ d ɸ 2 )] where.

1 Noncommutative QCDCorrections to the Gluonic Decays of Heavy Quarkonia Stefano Di Chiara A. Devoto, S. Di Chiara, W. W. Repko, Phys. Lett. B 588, 85.

Finite Temperature Field Theory Joe Schindler 2015.

The Geometry of Moduli Space and Trace Anomalies. A.Schwimmer (with J.Gomis,P-S.Nazgoul,Z.Komargodski, N.Seiberg,S.Theisen)

Renormalized stress tensor for trans-Planckian cosmology Francisco Diego Mazzitelli Universidad de Buenos Aires Argentina.

Gauge invariant Lagrangian for Massive bosonic higher spin field Hiroyuki Takata Tomsk state pedagogical university(ТГПУ) Tomsk, Russia Hep-th

Computational Methods in Particle Physics: On-Shell Methods in Field Theory David A. Kosower University of Zurich, January 31–February 14, 2007 Lecture.

One particle states: Wave Packets States. Heisenberg Picture.

Discrete R-symmetry anomalies in heterotic orbifold models Hiroshi Ohki Takeshi Araki Kang-Sin Choi Tatsuo Kobayashi Jisuke Kubo (Kyoto univ.) (Kanazawa.

3 DERIVATIVES.  Remember, they are valid only when x is measured in radians.  For more details see Chapter 3, Section 4 or the PowerPoint file Chapter3_Sec4.ppt.

2 Time Physics and Field theory

1 Renormalization Group Treatment of Non-renormalizable Interactions Dmitri Kazakov JINR / ITEP Questions: Can one treat non-renormalizable interactions.

1 Localization and Critical Diffusion of Quantum Dipoles in two Dimensions U(r)-random ( =0) I.L. Aleiener, B.L. Altshuler and K.B. Efetov Quantum Particle.

Two-dimensional SYM theory with fundamental mass and Chern-Simons terms * Uwe Trittmann Otterbein College OSAPS Spring Meeting at ONU, Ada April 25, 2009.

Monday, Mar. 10, 2003PHYS 5326, Spring 2003 Jae Yu 1 PHYS 5326 – Lecture #14 Monday, Mar. 10, 2003 Dr. Jae Yu Completion of U(1) Gauge Invariance SU(2)

9/10/2007Isaac Newton Institute1 Relations among Supersymmetric Lattice Gauge Theories So Niels Bohr Institute based on the works arXiv:

1 Superstring vertex operators in type IIB matrix model arXiv: [hep-th], [hep-th] Satoshi Nagaoka (KEK) with Yoshihisa Kitazawa (KEK &

The Importance of the TeV Scale Sally Dawson Lecture 3 FNAL LHC Workshop, 2006.

The nonperturbative analyses for lower dimensional non-linear sigma models Etsuko Itou (Osaka University) 1.Introduction 2.The WRG equation for NLσM 3.Fixed.

Martin Schnabl Institute of Physics, Prague Academy of Sciences of the Czech Republic ICHEP, July 22, 2010.

Quasi-Classical Model in SU(N) Gauge Field Theory A.V.KOSHELKIN Moscow Institute for Physics and Engineering.

} } Lagrangian formulation of the Klein Gordon equation

Solution of the NLO BFKL Equation (and a strategy for solving the all-order BFKL equation) Yuri Kovchegov The Ohio State University based on arXiv:

2006 5/19QCD radiative corrections1 QCD radiative corrections to the leptonic decay of J/ψ Yu, Chaehyun (Korea University)

Boundary conditions for SU(2) Yang-Mills on AdS 4 Jae-Hyuk Oh at 2012 workshop for string theory and cosmology, Pusan, Korea. Dileep P. Jatkar and Jae-Hyuk.

Natsumi Nagata E-ken Journal Club December 21, 2012 Minimal fields of canonical dimensionality are free S. Weinberg, Phys. Rev. D86, (2012) [ ].

Intro to SUSY II: SUSY QFT Archil Kobakhidze PRE-SUSY 2016 SCHOOL 27 JUNE -1 JULY 2016, MELBOURNE.

Ariel Edery Bishop’s University

Physics 222 UCSD/225b UCSB Lecture 10 Chapter 14 in H&M.

What is the GROUND STATE?

Adnan Bashir, UMSNH, Mexico

Effective Theory for Mesons

Adnan Bashir, UMSNH, Mexico

Hysteresis Curves from 11 dimensions

Gauge invariant flow equation

Off-shell Formulation of Supersymmetric Field Theories

Presentation transcript:

Sypersymmetries and Quantum Symmetries Dubna 2007 K.Stepanyantz Moscow State University Department of Theoretical Physics New identity for Green function in N=1 supersymmetric theories

N=1 supersymmetric theories N=1 supersymmetric Yang-Mills theory with matter is described by the action where and are chiral scalar matter superfields, is a real scalar gauge superfield, and The action is invariant under the gauge transformations We investigate quantum corrections to the two-point Green function of the gauge superfield and to some correlators of composite operators exactly to all orders of the perturbation theory.

Quantization We use the background field method:, where is a background field. Using the background gauge invariance it is possible to set. Backlground covariant derivatives are given by The gauge is fixed by adding the following term: The corresponding ghost Lagrangian is Also it is necessary to add the Nielsen-Kallosh ghosts In order to calculate quantum corrections we also introduce additional sources Differentiation with respect to additional sources allows calculating vacuum expectation value of some copmposite operators.

Higher derivative regularization To regularize the theory we use the higher covariant derivative regularization. (A.A.Slavnov, Theor.Math.Phys. 23, (1975), 3; P.West, Nucl.Phys. B268, (1986), 113.) We add to the action the term Then divergences remain only in the one-loop approximation. In order to regularize them, it is necessary to introduce Pauli-Villars determinants into the generating functional where the coeffecients satisfy the condition The regularization breaks the BRST-invariance. Therefore, it is necessary to use a special subtraction scheme, which restore the Slavnov- Taylor identities: A.A.Slavnov, Phys.Lett. B518, (2001), 195; Theor.Math.Phys. 130, (2002), 1; A.A.Slavnov, K.Stepanyantz, Theor.Math.Phys. 135, (2003), 673; 139, (2004), 599.

Calculating matter contribution by Schwinger-Dyson equations and Slavnov-Taylor identities + Schwinger-Dyson equation for the two-point Green function of the gauge field can be graphically presented as Feynman rules are (massless case for simplicity): A propagator: Vertexes (obtained by solving the Slavnov-Taylor identities): +contributions of the quantum gauge field and ghosts

Exact beta-function and new identity Substituting the solution of Slavnov-Taylor identities to the Schwinger-Dyson equations (in the massless case) we find Gell-Mann-Low function is then given by We obtained that (We did not calculate contribution of the gauge field and did not write contribution of Pauli-Villars fields). Then the Gell-Mann-Low function differs from NSVZ beta-function in the substitution

New identity in N=1 supersymmetric Yang-MIlls theory with matter HOWEVER, explicit calculations with the higher derivative regularization in the three- and four-loop approximations (A.Soloshenko, K.Stepanyantz, Theor.Math.Phys. 134, (2003), 377; A.Pimenov, K.Stepanyantz, Theor.Math.Phys. 140, (2006), 687.) show that all in integrals, defining the two-point Green function of the gauge field in the limit p 0, has integrads which are total derivatives. This can be only if the following identity takes place (massless case for simplicity): This identity is also valid in non-Abelian theory (K.Stepanyantz, Theor.Math.Phys. 150, (2007), 377). It is nontrivial only in the three-loops. In the massive case this identity is much more complicated, but can be wriiten in the simple functional form: where the sources are assumed to be expressed in terms of fields.

Three-loop verification of new identity in non-Abelian theory New identity and factorization of the integrands to total derivatives can be verified for special groups of diagrams (A.Soloshenko, K.Stepanyantz, Theor.Math.Phys. 140, (2004), 1264.) A way of proving in the Abelian case was scketched in K.Stepanyantz, Theor.Math.Phys. 146, (2006), 321. In the non-Abelian case there is a new type of diagrams: It is also necessary to attach a line of the background gauge field to the line of the matter superfield by all possible ways. The result is again an integral of a total derivative! Therefore, the new identity is also valid in this case. The corresponding function f can be found by calculating diagrams of the type chiralnonchiral

Structure of quantum correction in N=1 supersymmetic Yang-Mills theory Are integrads, defining the two-loop function of N=1 SYM, also reduced to total derivatives with the higher covariant derivative regularization? (A.Pimenov, K.Stepanyantz, hep-th/ ) Two-loop Gell-Mann-Low function of N=1 SYM (without matter) is defined by the diagrams A wavy line corresponds to the quantum gauge field, dashs correspond to Faddeev-Popov ghosts, dots correspond to Nielsen-Kallosh ghosts, and a cross denots a counterterm insersion. Usual diagrams are obtained by adding two external lines of the background field by all possible ways.

Structure of quantum correction in N=1 supersymmetic Yang-Mills theory In the limit p 0 two-loop contribution is where The integrand is again a total derivative in the four dimensional sperical coordinates! Really, Therefore, this seems to be a general feacture of all supersymmetric theories, althouht the reaon is so far unclear. The corresponding two-loop Gell-Mann-Low function coincides with the well known expression With the higher derivative regularization there are divergences only in the one-loop approximation. (similar to M.Shifman, A.Vainstein, Nucl.Phys. B277, (1986), 456.)

Conclusion and open questions With the higher derivtive regularizations integrals, defining the two-point Green function of the gauge field in the limit p 0, can be easily taken, because the integrands are total derivatives. It is a general feature of N=1 supersymmetric theories. Why it is so? There is a new identity in both Abelian and non-Abelian N=1 supersymmetric theories the matter superfields, for example, in the massless case It is not a consequence of the supersymmetric or gauge Slavnov-Taylor identities. The corresponding terms in the effective action are invariant under rescaling. What symmetry leads to this identity? New identity is nontrivial starting from the three-loop approximation.