Supersymmetry

Download Report

Transcript Supersymmetry 

LIE SUPERALGEBRAS AND
PHYSICAL MODELS
My. Brahim SEDRA
Ibn Tofail University
Faculty of sciences, Physics Department, LHESIR,
Kenitra
WORKSHOP DE RABAT 6-8 JUIN 2013
1
Acknowledgements
For invitation to present a talk.
2
1. Opening
A brief comment about
Supersymmetry
is requested !
Before that: What is the contexte?
3
Structure de l’atome
Mécanique
Quantique
Electron
Interaction
électromagnétique
Noyau
-10
10
4
m
Strucure du noyau
Proton
Interaction forte
Neutron
-14
10
5
m
Structure des nucléons
Proton :
2 quarks up
1 quark down
Interaction forte
Neutron :
1 quark up
2 quarks down
-15
10
6
m
What happens at these very small scales of
the matter?
 Classical physics is no longer valuable
 Quantum physics:
Major Properties:
-
7
Spin
Incertainty (Heisenberg Principles)
Duality: particles/waves
Also quantum physics is not enough!!
 Quantum field theory!
Mixture of quantum physics with relativity !
…
 String theory,
8
that's the contexte
…
9
Susy: What is it?




In nature there are bosons and fermions
Bosons: particles having integer value of the spin
Fermions: particles having half integer value of the spin
Susy: a mechanism that associates to each boson a
fermion.
Susy is broken at the present
scale of the univers !
 Susy assumes that in nature (universe) the number of
bosonic states should be the same as the number of
fermionic states.
 By virtue of susy, bosons and fermions should have the
same MASSE.
10
 Susy theory assumes also that the super partner of the
electron is a boson called the selectron: m (e)=m(se).
 However, there is no experimental (or observational)
indication about the existence of the selectron.
Interpretation !
The difficulty to observe the selectron can have two causes:
1. The selectron is very heavy !
or
1. There should exists an unknown mechanism that makes a
screen on it.
Thus, the observation of the selectron requests higher
technology .
11
C/C: Since the masse of partners is not
equilibrate, the susy is broken.
Comment 1
Boson de Higgs :
C’est une particule soupçonnée être à l'origine
de l’attribution des masses à toutes les
particules de l'univers physique
12
Comment 2
On 4 July 2012:
CERN has announced in a conference that a
new bosonic particle has been identified .
Probably it’s the Higgs!
The CERN is not yet completely assured
about it!
(Des études complémentaires seront nécessaires
pour déterminer si cette particule possède
l'ensemble des caractéristiques prévues pour le
13
boson
de Higgs).
2. What’s about Lie superalgebras?
 The importance of LSA in physics deals,
among other, with the connection with
supersymmetry (briefly described before).
 In constructing supersymmetric integrable
models, the request of integrability implies
several solutions for the Cartan matrix Kij.
 In contrast to the standard (bosonic) LA, we
don't have a unique Cartan matrix in the
LSA.
14
Definition and Properties
A Lie superalgebra (LSA) L is a Z 2  graded vectorspace
L  L0  L1
over thefield (R or C) with a (supr) bracket[,} given by
a, b  ab   1
ab
ba
where a is thedegree of a :

a  deg a  
 1 if a is odd, aL1
0 if a is even, aL0
15
The superbracket is shown to satisfy:
a) The supersymmetry:
a, b  1degadegb b, a
a) The super Jacobi Identity
1 a  c a, b, c 1 c  b c, a, b 1b  a b, c, a  0
Remark:
The restriction of L to the even part L0 gives a standard
Lie algebra with a, b  a, b satisfying the antisymmetry
and the Jacobi identity.
16
Superbracket and Physics !
Consider:
a, b  1
deg adegb
b, a
and let B and F be Fermionic and Bosonic operators respectively
such that



with
17
B deg B 0
F deg F 1
B, B   B
B, F   F
F , F   B
Example
Let L be t heHeisenbergLSA defined as t heset

j

j
of raising and loweringoperat orsb and b ,
j  1,2,...,r.
These operators satisfy the following relations
b
b
b

j
, b
k

j
, b
k

j
, b
k
   .1, and
  0,
b , 1  0, b , 1  0, 1, 1  0.
  0. T hen
jk

j

j
1 b j , b j , j  1,..., r
defines a LSA of
18
dim ension(1  2r )
3. What is new in LSA?
Two type of
Simple Roots
FERMIONIC
(ODD)
DIFFERENT DYNKIN DIAGRAMM !!
19
LSA with odd simple roots play an important
role in Susy Integrable models.
These integrable models are defined through a
zero curvature condition
D  A , D  A   0
20
The important result (Literature):

There are classes of LSA whose Cartan matrices lead
to integrable models in such way that the simple roots
is chosen to be purely fermionic (odd).
 The constraint of integrability, leads to some explicit
solutions of the Cartan matrix. As an example
A(n|n-1)=sl(n+1|n),
B(n|n)=osp(2n+1|2n)
B(n-1|n)=osp(2n-1|2n),
D(n+1|n)=osp(2n+2|2n)
D(n|n) =osp(2n|2n),
21
D(2|1; a)
LSA
Sl(n+1/n)
These
are
1
2
2,3,...,2n  1
osp(1/2)
3/2
osp(3/2)
3/2, 2
osp(2n-1/2n), n≥2
1
3,4,7,8,11,12,...,4n  5,4n  4,4n  1
2
osp(2n+1/2n), n≥2
1
3,4,7,8,11,12,...,4n  1,4n 
2
Osp(2/2)≈sl(2/1)
1, 3/2
Osp(2n/2n) , n≥2
1
3,4,7,8,11,12,...,4n  5,4n  4,4n  1, n
2
Osp(2n+2/2n)
D(2/1,a)
22
SPIN OF CONSERVED CURRENTS
1
3,4,7,8,11,12,...,4n  1,4n , n  1
2
2
3/2, 3/2,2
4. How things work in physics?
 Integrable models are systems of non linear
differential equations .
 Solving these equations is not an easy job.
 To avoid the non linearity, we use:
Operators
belonging to some
The famous: Lax technique
Lie algebra
structure
 The principal idea of the LT :
 We start from a non linear diff. Equation with
some fixed degrees of freedom.
 We assume the existence of a Lax pair, defined in
some Lie algebra structure.
 If the Lax pair exists, the integrability is assured.
23
Bosonic case
– To illustrate the previous arguments, let’s consider the
following physical model:
 The 2d Conformal Liouville Field Theory
S     d 2 z    exp(2 ) 
where is a scalar bosonicfield.
 The equation of motion is
  2 exp(2 )  0
 This is a n.l.d.eq. That can be solved by the
following Lax pair:

 h ,e 2 e
Az     he
Az exp  2  f
with
 h , f 2 f
su (2)  
e , f h

 We underline that the Lax pair satisfy the zero
curvature condition
Fzz  Az  Az  Az , Az   0
Fermionic case
– The super(symmetric) case consists in considering
similar steps:
 The 2d super Liouville Field Theory

S     d zd  D D  exp()
2
2

where :
-  is superfield,
- D, D are spinors,thesuper derivatives
-  theGrassmann variables
 As in the bosonic case, the Lax pair exists in this
case in order to ensure the integrability of the
model.
 The Lie symmetry is given by the Superalgebras
Osp(1|2)
osp(1 2)  h, e2 , f 2 0  e1 , f1 1
Rank  1
dim  5
Dynkin DiagramD : 
(onesimple root )
Results
MBS (and collaborators):
http://inspirehep.net/search: M.B.Sedra.
More on Lie superalgebras and Physical Models:
MBS (Thèse de doctorat d’Etat 1995) Et references dedans
28
References
1. M.Scheunert, The theory of Lie superalgebras, Lecture Notes
in math (1979);
2. J.Wess and J. Bagger, supersymmetry and supergravity,
princeton series in physics, 1983,
3. H. Nohara and all, Toda field theories, CFT (1990, 1991)
4. M.B. Sedra,
• ADSTP (2011), with K. Bilal, A. Boukili, M. Nach
• CJP, (2009) with A. Boukili, A. Zemate
.......
•
•
•
•
•
•
29
Nucl.Phys. B513:709-722,1998
J.Math.Phys.37:3483-3490,1996.
Mod.Phys.Lett.A9:3163-3174,1994,
Mod.Phys.A9:1994.
Class.Quant.Grav.10:1937-1946, 1993.
J.Math.Phys.35, 3190,1993
Thanks
30