A Review of Solitons in Gauge Theories. David Tong

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Transcription:

A Review of Solitons in Gauge Theories David Tong

Introduction to Solitons Solitons are particle-like excitations in field theories Their existence often follows from general considerations of topology and symmetry An example: the KdV equation u t 3 2 uu x 1 4 u xxx =0 Animation by A. Kasman

Solitons in Nature Solitons are one of the most ubiquitous phenomena in physics On the tabletop Superconductors, Superfluids, BECs, Quantum Hall Fluids In the sky Magnetic Monopoles, Cosmic strings In quantum field theory Instantons, Monopoles, Vortices, Duality and Strongly Coupled Phenomena In mathematics Integrability of PDEs Topological Invariants

Solitons in Nature And among the most important.

Instantons BPST U(N) Gauge Field S = R d 4 x 1 2e 2 Tr F μν F μν Instanton Equations: Instanton Action: F μν =? F μν S = 4π2 k e 2 The Instanton is a co-dimension 4 object, localized in (Euclidean) space time The scale size of the instanton is a parameter of the solution, a Goldstone mode arising from conformal invariance.

Magnetic Monopoles t Hooft, Polyakov Adjoint Scalar S = R d 4 x 1 2e 2 Tr F μν F μν + 1 e 2 (D μ φ) 2 Vacuum: hφi = ~ φ ~H so that U(N) U(1) N Monopole Equations: Monopole Mass: B i = D i φ M = 4π e 2 ~ φ ~g The monopole is a co-dimension 3, particle-like object

What Happened to the Instanton? The conformal invariance of the theory is broken by the vacuum expectation value hφi = ~ φ ~H The instanton shrinks to a pointlike, singular object. No smooth instanton solution now exists.

Another Deformation: The Higgs Phase Fundamental Scalars S = R d 4 x 1 2e 2 Tr F μν F μν + 1 e 2 (D μ φ) 2 + P N f i=1 D μq i 2 P N f i=1 q i φ2 q i e2 2 Tr (P N f i=1 q iq i v2 ) 2 D-term, with FI parameter A zero-energy vacuum requires N f N c We take the vacuum expectation values hφi =0 hq a i i = vδa i The gauge group is now broken completely: U(N) 0

Vortices in Superconductors The theory lies in the Higgs phase. It is like a non-abelian superconductor. In a real superconductor, the Meissner effect means that magnetic flux cannot propagate freely. It forms collimated flux tubes, or strings. These are solitons They are supported by the winding phase of q.

Vortices Nielsen and Olesen, phase of q i Vortex Equations: (B 3 ) a b = e2 ( P i qa i q ib v2 δ a b ) (D z q i ) a =0 Vortex Tension: z = x 1 + ix 2 T vortex =2πv 2

Vortex Moduli Space B? q? Suppose we have an Abelian vortex solution,. We can trivially embed this in the non-abelian theory. When N f = N c ( 0 B = B? 0... ( q = ( q? v... v ( Different embeddings moduli space of vortex SU(N) diag /SU(N 1) U(1) = CP N 1

Vortex Dynamics The low energy dynamics of an infinite, straight vortex string is the d=1+1 sigma model with target space C CP N 1 CP N 1 Size of is r = 2π e 2 This means that when the 4d theory is weakly coupled, the 2d theory is also weakly coupled.

What Happened to the Instanton Now? Hanany and Tong, 04 In the Higgs phase, the instanton can nestle inside the vortex string. hqi v hqi 0 The configuration is ¼-BPS F 12 F 34 = e2 2 (P i q iq i v2 ) F 14 = F 23 F 13 = F 24 D z q i =0 D w q i =0

The Trapped Instanton From the worldvolume perspective of the vortex string, the trapped instanton looks like a sigma-model lump (or worldsheet instanton). The sigma-model lump has action S =2πr = 4π2 e 2 = S inst The moduli space of lumps is a submanifold of the moduli space of instantons, defined by the fixed point of a U(1) action. ADHM Construction for Instantons AD Construction for Vortices/ Lumps N=(4,4) U(k) vector multiplet + adjoint hypermultiplet + N fund. hypermultiplets throw away half the fields N=(2,2) U(k) vector multiplet + adjoint chiral multiplet + N fund. chiral multiplets + N anti-fund chiral multiplets

Final Deformation: Adding Masses S = R d 4 x 1 2e 2 Tr F μν F μν + 1 e 2 (D μ φ) 2 + P N f i=1 D μq i 2 P N f i=1 q i (φ m i) 2 q i e2 2 Tr (P N f i=1 q iq i v2 ) 2 add masses Vacuum: hφi =diag(m i1,m i2,...,m in c ) and hqi v µ Nf N c isolated vacua The theory now has a mass gap for all Nf

Domain Walls Abraham and Townsend 91 ~φ = ~m ~φ = ~m 0 Domain Wall Equations: D 3 φ = e2 2 (P i q iq i v2 ) D 3 q i =(φ m i )q i Domain Wall Tension: T = v 2 ~ φ ~g

What Became of the Vortices? The internal moduli space of vortices is lifted by the masses, leaving behind only isolated, diagonal solutions. ( 0 )... B = B? From the perspective of the vortex worldsheet, this can be understood as a inducing a potential on, leaving N vacua. CP N 1 There is now the possibility of a kink on the worldsheet. It has mass M kink = r m 1 m 2 = 4π hφi e 2 = M mono

Confined Monopoles Tong 03 The kink in the vortex worldsheet is a confined magnetic monopole B ( 1 0 ( B ( 0 1 ( The configuration is again ¼-BPS: B 1 = D 1 φ B 2 = D 2 φ B 3 = D 3 φ + e2 2 (P i q iq i v2 ) D 1 q i = id 2 q i D 3 q i = (φ m i )q i

Kinks vs Monopoles Hanany and Tong, 05 There is a relationship between the moduli space of domain walls (or kinks) and the moduli space of monopoles The moduli space of domain walls is a submanifold of the moduli space of monopoles, defined by the fixed point of a U(1) action. The domain wall moduli space contains the information about which walls can pass, and which cannot. Nahm Construction for Monopoles (Almost) Trivial Construction for Kinks D y X i i 2 ²ijk [X j,x k ]=δ(y) throw away half the fields D y X i = δ(y)

D-Branes Gauntlett, Portugues, Tong and Townsend, 00 Shifman and Yung, 03 The same BPS equations, with different boundary conditions, also have solutions describing vortex strings ending on domain walls There is an extra, negative energy density localized where the string meets the wall. It is a boojum. It has the negative mass of half a magnetric monopole. Sakai and Tong 05

D-Branes There exists an analytic solution for a single string ending on a domain wall (in the e 2 limit). Other numerical solutions have been found. 10 10 5-10 0-5 5 0-5 -10-20 -10 0 10 20 Isozumi, Nitta, Ohashi and Sakai 04

Are They Really D-Branes? The most important feature of D-branes is the existence of an openstring description of their dynamics. In particular, D-branes in Nature do not share this feature. For example: The fluid dynamics system describing the weather in Wyoming admits D-brane solitons Only a crazy person would suggest an open-string description of cloud dynamics.

D-Branes in Field Theory Tong 05 The domain walls are D-branes for the vortex string. The classical scattering of two domain walls is described by a cigar-like moduli space There also exists an open string description. The string between two walls gives rise to a chiral multiplet and associated Chern-Simons terms on the walls. The d=2+1 quantum dynamics reproduces the classical scattering of domain walls.

What Happened to the Instantons? For generic masses, there is no where for them to hide. They shrink to zero size But for degenerate masses, they can nestle inside domain walls e.g. U(2) with four flavors q 1,q 2 v q 3,q 4 v This configuration is not BPS m/e 2 v 2

Instantons as Skyrmions Eto, Nitta, Ohashi, Tong 05 There is a U(2) flavour symmetry in the field theory which descends to a symmetry on the wall. The collective coordinate of the wall is a U(2) group valued field, g = P exp ³ i R + = dx3 A 3 (x 3 ) The low-energy dynamics of the wall is the Skyrme model, complete with four-derivative term Instantons in the bulk become skyrmions on the wall. This gives a physical realization of an old idea due to Atiyah and Manton

Summary of Classical BPS Solitons Pure Yang-Mills Instanton Yang-Mills + Adjoint Scalar Monopole Yang-Mills + Massless Fundamental Scalars Vortex String Trapped Instanton Yang-Mills + Adjoint Scalar + Massive Fund. Scalars Domain Wall Confined Monopole D-Brane Domain Wall Skyrmion

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