Physics Beyond The Standard Model Arunansu Sil Department of Physics Indian Institute of Technology, Guwahati, India 30 th April, 2012 BUE, Cairo University, Egypt
Dec 31, 2015
Physics Beyond The Standard Model
Arunansu Sil
Department of Physics
Indian Institute of Technology, Guwahati, India
30th April, 2012 BUE, Cairo University, Egypt
The Standard Model: present status and open problems
The Standard Model of Particle Physics: a mathematically consistent theory which describes strong, weak and
electromagnetic interactions at low energies; highly constrained theory. compatible with (almost) all experimental results.
Why then Beyond Standard Model ?
Theoretical issues: It has 19 free parameters 1. three gauge couplings
2. two parameters in the Higgs sector
3. nine quaks and charged lepton mass
4. three mixing angles and one CP-violating phase in the quark system
5. the QCD parameter 𝜃
Why BSM contd..
In the SM, if we extrapolate the behavior of the forces at higher energies:
the strength of the 3 forces become similar though never exactly the same.
It provides a strong hint toward the long standing goal of unifying the forces of nature.
Perhaps Grand Unification Theory [will be discussed ]
In the SM, quantum corrections apparently make the Higgs boson mass huge. This poses a serious conceptual problem (called hierarchy problem). [will be discussed in the context of Supersymmetry]
Other open problems/less-elegant features:
Non-zero neutrino mass: neutrinos mass can not be accommodated in SM as no right handed neutrino is present in the SM structure: so No Dirac mass.
Neutrino experiments: at least 2 of the 3 three neutrinos are massive ~ 1eV or less.
Open problems of SM contd. solution: new physics can generate dim-5 operator L = yLLHH /M + h.c. M= scale for the new physics i.e. mass of the field that was integrated out. Only three possibilities: introduction of i) a singlet field: right handed neutrino [Type I see-saw] ii) a scalar triplet [Type-II ..] iii) a fermionic triplet [Type III ..]
[This can arise naturally in GUT models]
Charge quantization: can not explain the fractional charge of quarks. [answer from GUT]
No family structure: Why three generations of matter?
Gravity: SM does not include gravity; not even understood whether gravity is to be treated as a gauge theory, since it has not been quantized as the other interactions.
(Extra dimension, String theory)
Questions contd..Cosmic Pie
Dark Energy and Cosmological constant problem: It has been known recently that the expansion of our universe is accelerating and what causes it (Dark Energy) cannot be explained in the SM particle. It requires Vacuum energy density ~ 10-12 eV2
In SM, expected vacuum energy ~ 1048 eV2
almost 60 orders of magnitude difference !
Solution: quintessence or cosmological constant. [Nothing known so far]
Open problem in SM contd.
Almost 25% of our universe is made up with invisible Dark Matter (non baryonic) that cannot be particles within the SM.
Evidence from galactic rotation curve etc. , has to be very weakly interacting particle.
Questions contd..
If there is Supersymmetry, dark matter candidates comes naturally.
There is good evidence that in the very early stage (within first fraction of second after the big bang), the universe went through a stage of extremely rapid expansion, called Inflation. The field responsible for inflation cannot be the SM ones.
[will be discussed]
The idea that universe began from big bang, with a huge burst of energy indicates that it should have evolved into equal parts of matter and antimatter CP symmetry. However we could see mostly particles ! This matter-antimatter asymmetry cannot be explained in the Standard Model.
With the extensions of the SM, we have better understanding of some of
the queries listed above, however those also led to new questions that
could not be formulated earlier.
Grand Unified theories
Standard Model is based on GSM : SU(3)C X SU(2)L X U(1)Y
The SM has 3 gauge interactions described by the corresponding carriers Ga
µ (a = 1 … 8) ; Wiµ (i = 1 … 3) ; and Bµ
Dµ = ∂µ + ig3 ∑a=1,8 Gaµ λa/2 + igw ∑a=1,3Wa
µ σa/2 + igy Bµ Y/2
g3,w,y : coupling for each three interactions (unrelated parameters).
λa: Gell-Mann matrices for SU(3); σa = Pauli matrices for SU(2) and Y: hypercharge operator.
It has also three types of 9 Yukawa matrices
Sin2θw = g2Y /(g2
W + g2Y);
as couplings are dependent on energy scale, µ: Sin2θw (µ) = αY(µ) / [αw(µ)+ αY(µ)]
Grand Unification contd.
The idea of GUT: to reduce all the gauge interactions to one single gauge group with a
single coupling constant.
Also running of the gauge couplings give hint for unification.
Since at low energy, SM is performing extremely well, GUT should break down to
SM group. Breaking of that larger group into GSM by Higgs mechanism.
SM couplings run as they depend on the energy scale, µ [use of RGE]. We want to study
whether we achieve α1 (Mx) = α2 (Mx) = α3 (Mx) = αU
Choice of the gauge group:
1. SM gauge group should then be a subgroup of the grand unified gauge group,
2. all the SM fermions should be included in the GUT matter representations remembering
that list of non-SM fields are minimum with the specific choice.
3. GSM consists of total 12 generators, four of them be simultaneously diagonal (Rank 4).
So the minimal choice for the GUT group should be based on a Rank 4 simple group.
Finally SU(5) being Rank 4, enables us to consider only SM fields.
Starting with SU(5)
Each family (one generation) fits nicely into the SU(5) multiplets:
1. In the SM, there are 15 left-handed two-component fermion fields in each family (generation): so it fits nicely in the SU(5) multiplet chosen.
2. We identify the first three of the SU(5) indices as the colour indices and the remaining two as SU(2)L indices.
SU(5) contd.Dµ = ∂µ + ig5 ∑a= 1, 24 Aa
µ λa /2
Gauge bosons: SU(5) adjoint representation has dimension 52 – 1 = 24 and
Its SU(3) X SU(2) decomposition:
24 = (8,1) + (1,3) + (1, 1) + (3, 2) + (3*, 2)
12 extra gauge fields: X and Y bosons
SU(3) gluons W B-field
<H> <Φ>
Spontaneous symmetry breaking: SU(5) ----> GSM ----> SU(3) X U(1)
Minimal choice for Higgs sector: two scalar representations 24H and 5H .
identified with H and Φ = T (since 24 is an adjoint reps, it does not break rank) Ф
__
Yukawa sector: LY = 5F Y5 10F 5*H + 1/8 ε5 10F Y10 10F 5H + h.c. SU(3) Color Triplet
Running and unification
RGE at 1-loop: αi-1 (µ2) = αi
-1 (µ1) – bi /4π ln(µ22 / µ2
1), µ1 > µ2
bi coefficients are group theoretically derived.
Low energy results: α-1 (MZ) ≈ 128 (α = αw Sin2θw )
αs (MZ) = 0.1184(7)
Sin2θw (MZ) = 0.23116(13)
By evaluating how the couplings evolve to high energy scale, one obtains:
Some features of SU(5)
Conclusion: with the bottom-up approach, we see that the SM does not unify exactly within minimal
SU(5). The same observation can be found in Top-bottom approach: impose unification at some scale and run the couplings down to SM scale.
With α-1 (MZ) ≈ 128 and αs (MZ) = 0.1184(7), ΛGUT ~ 6.7 x 1014 GeV with α5
-1 = 41.5
But, Sin2θw (MZ) turns out to be 0.208, so this fails.
Inclusion of Supersymmetry will improve it:
Nice features: Unification of all the interactions within a simple group partial unification of the matter with the two multiplets explanation of electric charge quantization. [eigenvalues of the generators of a simple non-abelian group are
discrete; quarks carry 1/3 unit of the lepton charge as they have 3 colours]
Problems: Lepto-quarks, di-quarks and proton decay: X and Y bosons can mediate proton decay.
u e+
lc q
X X
q qc d uc
B = -1/3 B = 2/3 u u 𝜋0
Doublet triplet splitting problem Neutrino mass can not be accommodated
Supersymmetry Supersymmetry (SUSY): a symmetry between bosons and fermions.
Need for Supersymmetry: (the problem of quadratic divergencies in SM)
two-point function receives a contribution from the fermion loop:
considering q1 = q2 = 0 and k1 = -k2 = k say, with λf Hff
πfHH
(0) = -
fermion-antifermion contribution to the = -
self-energy of the higgs boson in the SM
N(f) = 3 for top quarks = -
1st term: quadratically divergent ! Term is proportional to the cut-off of the theory, Λ.
For Λ ~ MPl, then, MH2 = MH, tree
2 + cg2/4π2 MPl2
f
ff
ff
mk
ii
mk
iitr
kdN
)()()2(2 4
4
222
22
4
42
)()2( f
fff
mk
mkkdN
222
2
224
42
)(
21
)2()(2
f
f
f
f mk
m
mk
kdfN
Solution of quadratic divergence Therefore extreme fine tuning is needed (need to cancel in all order)
Solution through SUSY:The problem is solved by additional contributions to πf
ΦΦ.
Contribution from the 2nd diagram:
Therefore quadratic divergences can be
made to cancel, if required also for the scalar potential to be bounded from
below
We can achieve complete cancellation between fermion and bosonic contributions, if in addition we
have
RL ff
ff
HH mkmk
kdfN
~~
~
22224
4~ 11
)2(')()0(
ff
RL fNfNfN2
~~
'
)()()(
ffmm ~
SUSY formalism If Q is the generator of the symmetry which turns a bosonic into a fermionic state
Q must carry half-integer spin (fermionic and hence anticommutating algebra).
SUSY Algebra:
Weyl spinor index:
left handed: α = 1, 2 right handed:
Mass dim. Q = ½
Dim: ½ 1 3/2
Superfield formalism:
4D spacetime superspace
fermionic coordinate (dim: -1/2)
SUSY contd.. Chiral superfield: SM fermions are chiral (their left and right-handed components transfer
differently under SU(2) X U(1))
Transformation law:
dim: 1 1 -1/2 3/2 -1 2spin: 0 0 1/2 0
Wess-Zumino model
Kahler potential:
Superpotential:
Canonical Kinetic term:
Mass, interaction terms
F has no kinetic terms; auxiliary field.
= 0
(F-flat condition)
where Fi are solutions of equation of motion:
Scalar potential: >0 (positive definite)
SUSY vacuum: Vmin = 0
Vector superfield:
MSSM Gauge invariant superpotential:
Yukawa couplings µ-term
B/L number violating terms:
Proton decay:
R-parity: forbids
Under R‐parity Even Odd Neutral LSP: Candidate for Dark matter
SM fields SUSY partners
SUSY breaking SUSY must be broken (but SOFTLY)! Otherwise
1. F-term should be nonzero
2. Needs to be softly broken to maintain
the cancellation of quadratic divergences.
SUSY is broken in a Hidden Sector
gravity/gauge interaction etc.
Spurions:
Effective interaction between
X and MSSM fields:
Hidden SectorFx
MSSM
SUSY breaking contd..
Sfermion mass:
A-term:
Gaugino mass:
For gravity mediation, M = MPl
(In case of gauge mediation, this can be replaced be the messenger mass)
SUSY Breaking model building
Most common approach to mediate the supersymmetry breaking to the MSSM sector: 1. Gravity mediation; F1/2 ~ 1012 GeV2. Gauge mediation; low energy susy breaking.
Here we will focus upon the supersymmetry breaking sector(based on Metastable SUSY introduced breaking by ISS)
Conventional picture of Dynamical Supersymmetry Breaking (DSB) The idea is to use an asymptotically free gauge theory like QCD, so that
the smallness of the SUSY breaking scale can be explained dynamically…
Msusy~ MCutoff exp(c/g2(MCutoff)) V Kahler potential is hard to
control! Metastable SUSY breaking
overcomes this….
Vacuum Energy VDSB > 0 Ф
SQCD
Gauge group Flavour
SU(NC) Nf
SQCD Duality (electric)
Local SU(Nc); Nf flavours Qi, Q’j
Coupling becomes ~ O(1) at the scale Λ
Global : SU(Nf) x SU(Nf) x U(1)B x U(1)R
Q : Nf 1 Q’ : 1 Nf
Superpotential: Introduce quark mass (ISS approach) [Intriligator, Seiberg, Shih, 2007]
WUV = Tr m Q Q’ ; m « Λ
Breaks Chiral symmetry.
R(Q) = R(Q’) =1
Duality contd..
1. Local SU(Nf - Nc) ;
Nf flavours qi, q’j + singlet N2f “mesons” Φij = Q’i Qj / Λ
2. Coupling gm ~ O(1) , i.e. becomes strong at Λ
It would be IR free for Nc + 1 < Nf ≤ 3 Nc /2 β function: b0 = 2Nf – 3Nc < 0 3. The running of the gauge coupling of g SU(Nf – Nc):
4. Same global group. g SU(Nc)
SU(Nf -Nc)
Λ E
fc NNEg E
e23
)(
82
2
WWUVUV = Tr m Q Q’ = Tr m Q Q’
Duality continued…(magnetic)
4. Superpotential:
WIR = Tr (q’Φq) (Yukawa int.)
+ Tr (mΦΛ) (quark mass) + P Λ3 [det Φ/ΛNf]1/P ; P = Nf – Nc (Non Perturbative )
RIR (Φ) = 2 , RIR (q) = - RIR(q’)
5. The Kahler potential for the IR free fields is smooth near the origin and can be taken to be canonical,
222 |'||||| qqTrK
ISS bottom-up
Minimal example with Nf = 7 and Nc = 2
From Rank condition
So Supersymmetry is broken by rank condition with Vacuum energy
V = Nc µ4
Φ = 0 0 , q= q+ , q’ = q’+ , q’+q = µ2 IP 0 Φ+ 0 0
The pseduo moduli Φ+ is lifted by 1-loop effective potential. The local Non-SUSY Vacuum is therefore:
0' 2*
bac
bcaa
b
qqW
F ab
Magnetic
SU(7) X U(1)B X U(1)R global
SUSY Breaking Vacuum Φ = 0 0 , q= q’T = µ2.Ip 0 0 0 .INc
The non-perturbative superpotential gives negligible contribution to the effective potential around this vacuum and can be ignored here.
Add the N.P. term
This form is exact and uniquely determined by the symmetries of the theory and generated by the SU(Nf -Nc) gaugino condensation.
The Susy Minimum is given by:
WNP = Λs3(det Φ / ΛΛ77
ss ) )1/21/2
Restoration of Supersymmetry
Φ0 = <Φ> = µ[Λ/µ]X = µ/εx , x = (3Nc -2Nf)/Nc
<q> = <q’> = 0, ε = µ/Λ So we find the SUSY vacuua in the magnetic theory, staying below its cut-off; Φ0 < Λ.
V
m QQ’ 1 loop correc.
Wdyn
0 Φ0 Φ
Metastability
Lifetime of metastable vacuum:
Γ = e-s4 , s4 = ΔΦ4 / V+ ≈ ε-4x » 1
By choosing µ « Φ0 < Λ , it is possible to ensure the metastability
of the non-susy minimum.
ISS contd.
Local SU(5), with Nf = 7, Qi (fundamental), Q’i (anti-fundamental)
Superpotential: W = mQQ’ µ2 = Λs m since Φ = QQ’/Λs
Chirality breaking (UV) Susy breaking (IR)Choice of m is bit adhoc! We want to generate it dynamically
through inflation…. Coupling like f(X) QQ’ mQQ’
Addition of the N.P. term in the superpotential allows for SQCD completions.
Electric
GMSB and dISS
SUSY R-symmetry Gaugino mass by R ≠0, 2 fields Messengers qi>2 in 5 of SU(5)GUT
W = qi Φij qj’ - µ2 TrΦ + mq1 q2
------------------------------------------------------------------------------------------------------------------------------
SU(7)flavour SU(2) x SU(5) Ξ SU(5)GUT
IR UV------------------------------------------------------------------------------------------------------------------------------------------
WdISS= mqdet q1q2 WdISS= Be /M2pl
Bm /ΛS3 Ξ Be = det Q SU(5)
For Nc=2, det qi ≈ q2 breaks baryon number it fixes R(q) = 1
pl
s
q Mm
2
3
GMSB contd.
Now <Φ> ≠ 0 , R-symmetry is broken. FΦ ~ mq Λs = µ2; Fq ~ mqµ mgaugino≠0 since <q> ≠ 0 Metastability requires µ ~ mq « Λs
for mgaugino ~ TeV, µ ~ 109 GeV [Abel et. al]
mq = µ2/Λs ~ TeV, Λs ~ TeV
What could be the origin of it?
Perhaps Inflation !
E ~ 100 GeV (corresponds to time t ~ 10-10 sec considering the evolution of the universe)
Perhaps the early universe was the ultimate particle accelerator, and will provide the first glimpse of physics at the scale of Grand Unified Theories (GUTs), or even the Planck scale.
An interesting question is whether SUSY plays a fundamental role too at the early stages of the evolution of the universe and, more specifically, during Inflation !
Inflation: Inflationary Universe theory is an add-on to the standard Big-bang Cosmology: introduced as a resolution to the Horizon and the Flatness problem .
It corresponds to a period of accelerated expansion of the very early universe. a(t) ~ exp(Ht).
Modeling of Inflation
A slowly rolling scalar field:
Go back to Friedmann equation: which gives a(t) ~ exp(Ht)
i.e. exponential expansion of the Universe.
Slow Roll parameters :
0
2.
2
3
8V
G
a
aH
0303 '.
'...
VHVH
2'2
2
V
VmplV
Vmpl
''2
Can SUSY play any role ? Indeed!
Vacuum Energy during Inflation: the level of density and temperature fluctuations observed in the present universe, δH = 1.94×10-5, require
the inflaton potential to be extremely flat, e.g. in Chaotic inflation model, V = c Φ4
c ~ 10-13 to be consistent with observations. Also the inflaton should be of the order of the Planck mass during inflation.
This is where supersymmetry comes to rescue.
For example in Supersymmetric Hybrid Inflation model, no such small parameter
is required.
How to realize inflation in a supersymmetric framework?
Consider the superpotential:
INFLATON WATERFALL FIELD RESPONSIBLE FOR REHEATINGScalar Potential:
For S > M and 0 =א , local minimum with vacuum energy V ~ k2M4 : responsible for Inflation!
End of Inflation: when Sc < M, the mass term of S becomes negative, and the system ends V Inflation up in the supersymmetric minimum at
M and S = 0 = <א>
0 Χ
NfMkSW ,)( 22
....222222 MkSkV
Motivation
On the other hand we know that the world is not globally supersymmetric: In Nature, supersymmetry must be a broken symmetry.
We wanted to study whether there could be a relation between the Inflation
vacuum energy and supersymmetry breaking.