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Non-Relativistic Quantum Chromo Dynamics
(NRQCD)Heavy quark systems as a test of non-perturbative effects in the Standard
Model
Victor Haverkort en Tom Boot, 21 oktober 2009
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Topics of Today1. Motivation for NRQCD2. NRQCD
a. Philosophyb. Energy scales in heavy quark systems
3. Non-Relativistic version of the QCD Lagrangiana. Componentsb. Power counting; relative importance of componentsc. Origin of the correction terms
4. Application of NRQCD: Annihilation– Use NRQCD to describe annihilation of heavy quarkonia
(charmonium)
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1. Motivation
• Lagrangian density of QCD– Symmetry group: SU(3)
• Looks simple!
Don’t forget
: 4 component spinor
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1. Motivation
• It´s not!
Hmm, maybe not so simple…
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1. Motivation
• Standard way of calculating probabilities: Feynman Diagrams – Relies on perturbation theory: expansion in orders
of the coupling constant– Very long and difficult calculations if many
diagrams have to be taken into account• Method for calculations: Lattice QCD
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1. Motivation
• Solution: choose a particular energy region and select only relevant degrees of freedom– Effective Field Theory (EFT)– Is this allowed? Compare results with lattice QCD
• NRQCD selects an energy scale at which relativistic degrees of freedom do not appear in leading order terms– No expansion in the coupling constant so all diagrams
are included– Therefore we look for non-perturbative effects in the
Standard Model
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2a. NRQCD Philosophy
• Heavy Quark systems– Bound state of quark-antiquark– For example: Charmonium (or Bottomonium)– What is the scale parameter that selects relevant degrees
of freedom?
From comparison of hadron masses
From the charmonium level scheme
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2a. NRQCD Philosophy
• Heavy Quark systems– Bound state of quark-antiquark– For example: Charmonium– What is the scale parameter that selects relevant degrees
of freedom?
From comparison of hadron masses
From the charmonium level scheme
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2b. Energy scales in heavy quark systems
1. M: heavy quark mass; rest energy2. Mv: momentum of the charm quark3. Mv2: kinetic energy of the charm quark
• Because v<1: Mv2 < M v < M
• Now we will discuss these scales in more detail
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2b. Energy scales in heavy quark systems
• M: heavy quark mass; rest energy
• Processes which happen above this energy M:– Well described by perturbation
theory (Why?)– Example: Formation of high
energy jets and asymptotically free quarks
strong coupling constant vs. energy
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2b. Energy scales in heavy quark systems
• Leading order terms in the Lagrangian will have an energy ~ kinetic energy of the bound state
• This value is obtained by looking at the splitting between radial excitations– C.f. harmonic oscillator
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2b. Energy scales in heavy quark systems
• Momentum
• Sets size of the bound state – Heisenberg uncertainty principle
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2b. Energy scales in heavy quark systems
• Assume scales to be well separated
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3. Non-Relativistic Version of the QCD Lagrangian
• Recipe:– Introduce UV-cut off Λ to separate energy region >
M• Excludes explicitly relativistic heavy quarks and gluons
and light quarks of order M– Non-relativistic region:
• decoupling of quarks-antiquarks• Covariant derivative splits up in time component and
spatial component• Result:
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3a. Non-Relativistic Version of the QCD Lagrangian
Light quarks and gluonsGluon Field Strength Tensor
This describes the free gluon field and the free light quark fields
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3a. Non-Relativistic Version of the QCD Lagrangian
Heavy quarks-antiquarks
Annihilates heavy quark2 component spinor
Creates heavy antiquark2 component spinorKinetic term
This is just a Schrődinger field theoryReproduce relativistic effects with correction terms
are the time and space components of
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3a. Non-Relativistic Version of the QCD Lagrangian
Correction terms• And last but not least
• These terms are allowed under the symmetries of QCD• First we will explain the ordering of the Lagrangian• Then we will explain the exact origin of the terms
electric color field
magnetic color field
spin operator
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3b. Power CountingWavefunction
• Dimensionless (probability)
• Use Heisenberg to relate momentum to position
• So the quark annihilation field scales according to
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3b. Power CountingTime and spatial derivatives
• Recall thatgives an expectation value for the kinetic energy
• And then• From the field equations:
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3b. Power CountingScalar, electric, magnetic field
• For the scalar field, the color electric field and the color magnetic field:
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3b. Power CountingExample: 2nd correction term
What order is this?How does it compareto the leading orderterms?
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3b. Power CountingConclusion
• The correction terms are of orderand are suppressed by a factor ofwith respect to the leading order terms
• Correction terms are all possible termsbut have a more fundamental origin
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3c. Origin of the correction termsKinetic energy correction
• First correction term
• This is a correction to the energy
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3c. Origin of the correction terms Field interaction corrections
• Second and third correction term– Correction to the interaction of a quark with a scalar
field• Fourth correction term
– Correction to the interaction of a quark with a vector field
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Summary
• QCD calculations using perturbation theory are hard
• For heavy quark systems degrees of freedom can be separated to make calculations simpler
• Diagrams up to every order in g are included so we can test non-perturbative effects
• We have to add correction terms to maintain correspondence to the full theory
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After the break
• Annihilation: a process we can describe using an extended version of NRQCD and which can be compared to measurements
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Annihilation
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Conclusions before the break
• Until some cut-off energy we can use NRQCD to describe strong interaction
• Now can we apply NRQCD to annihilation processes of heavy quarkonia in order to check the theory with experiment?
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Overview
• Goal: Use NRQCD to desribe annihilation of heavy quarkonia (charmonium)
1.Describe annihilation of heavy quarkonia2.Argue that we can use NRQCD3.Find the contribution order of annihilation4.Compare with experiment5.Conclusions
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• J/Ψ to light hadrons
• We need at least 3 gluons• Different light hadrons can form• Complicated process
Example of annihilation
J/Ψ gluonP -1 -1S 1 1
light
hadrons
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Annihilation of heavy quarkonia
• Process of heavy quarks going into light quarks
• Light quark - heavy quarks interaction• Lagrangian is separated
• We need an extra correction
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• What does this correction look like?• Can it be nonrelativistic?
• … this is quite relativistic
Annihilation of heavy quarkonia
..9999.02/
2
2/2
/
duc
duc
du
MMc
MM
c
vquark mass
u/d 1.5-3.3 MeV
c 1.27 GeV
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Annihilation of heavy quarkonia
• What do we do?• Use nice trick, optical theorem:
Γ: decay rate, H: heavy hadrons, LH: light hadrons
If we know the scattering amplitude of we get the annihilation decay rate
of HLH!
HscatteringHLHH Im2)(
QQQQ
(1)
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• Optical theorem from the literature:
σ: cross section, k: wavenumber, f: scattering amplitude, f(0) means forward scattering
usc: scattered waveui: incident waveuf: final waver: distance to scattering centre
Optical theorem
)0(Im4 fk
),()exp( f
r
ikruuu ifsc
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• Proof:• Start with scattering amplitude:
l = number of partial wave, Pl = Legendre polynomial
al: effect on l’th partial wave, 0 ≤ ηl ≤ 1, amplitude, δl = phase shift
• ηl=1: elastic, no change in amplitude
• ηl<1: inelasticWe are going to make use of this
0
)(cos)1)(12(2
1)(
lll Pal
ikf (2)
lill ea 2
Optical theorem
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Optical theorem
• We want to calculate the total cross section
• Differential cross section:
• For the elastic cross section:
2
02
2)(cos
2
1)12(
1)(
)( l
l
l Pi
al
kf
d
d
0
2
2
21)12()(
llel al
kdf
inelel
12
4 '' ldPP llll
using:
with δ the delta function
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Optical theorem
• Analogue for the inelastic part:
• In total:
0
2
2)1)(12(
llinel al
k
02
0
22
2
)Re1)(12(2
)11)(12(
ll
lll
alk
aalk
(3)
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Optical theorem• If we fill in for the scattering amplitude (2),
θ=0 (so Pl(1)=1) and take imaginary part:
• We can identify this with (3):
0
)Re1)(12(2
1)0(Im
llal
kf
)0(Im4
fk
Optical theorem!
0
)(cos)1)(12(2
1)(
lll Pal
ikf
02
0
22
2
)Re1)(12(2
)11)(12(
ll
lll
alk
aalk
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Optical theorem
• We have:
• If we now use:and (follows from dimension analysis)
• We get: • This corresponds to (1):
)0(Im4
fk
2
k λ = wavelength
Γ=annihilation rate
)0(Im2 f
HscatteringHLHH Im2)(
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• How do we evaluatewithin NRQCD?
• First look at annihilation process:
Scattering
HscatteringH
At what length scale does this happen?
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Scattering
• pgluon = M• Trace back the interaction vertex• Uncertainty principle tells us: fm
Mdx 1.0
1
fm1.0charmonium of size
Annihilation is a local process (1/M)
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Scattering
• Because annihilation is local we need local scattering interactions:
4-fermion operators
These have the form:
antiquark ofcreation
quark ofon annihilati
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Scattering
• Extra correction term:
• Scattering is described by• We are interested in the order of contributions• General form:
fermioncorrectionlightheavy 4LLLLL
fermion4L
HH fermion4L
n
ndn
fermion OM
fn
)()(44L
On(Λ): local 4-fermion operatorfn(Λ): coef. of local operatordn: mass scaling dimensionn: rank of color tensor Λ: energy scale
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Scattering
• O has contributions in powers of M and v• Mass dimension compensates• Example:
So dL is proportional to M4
• note: Lagrangian density
gives M6v6 so d=6
n
ndn
fermion OM
fn
)()(44L
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n
ndn
fermion OM
fn
)()(44L
Scattering
• Ordering of local operators can be done in mass dimension
• Lowest order: d=6, all terms allowed are:
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Scattering
• All terms scale as v3 so v compressed wrt Lheavy
• Similar for d=8 terms: v3
compressed
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Scattering
• This seems more important than Lcorrection
• But now:
• Coefficients fn
• Calculated by setting perturbative QCD equal to NRQCD
• Have imaginary parts• for d=6 and d=8 terms: αs
2
n
ndn
fermion OM
fn
)()(44L
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Compare to experiment
• So in theory: • Energy splittings (from Lheavy) are order Mv2
• Relative contribution of annihilation06.0)3.01(55.024.0)()( 2322 vMavMa
SS
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For ηc: Γ=27MeVΔE: 400MeVΓ/ ΔE = 0.07
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Summary
• In order to describe annihilation of heavy quarkonia we need an extra correction term to NRQCD lagrangian
• Because the interaction is local we can use the optical theorem which says we can use local scattering operators
• The contribution of this extra correction term for annihilation agrees with experiment
• We can use NRQCD to obtain physical predictions
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Literature
• “Rigorous QCD Analysis of Inclusive Annihilation and Production of Heavy Quarkonium” Bodwin, Braaten, Lepage arxiv: hep-ph/9407339v2 (1997)
• “Improved Nonrelativistic QCD for Heavy Quark Physics”Lepage, Magnea, Nakhleharxiv: hep-lat/9205007v1 (1992)
• - “IHEP-Physics-Report-BES-III-2008-001-v1”Different contributors; editors: Kuang-Ta Chao and Yifang Wanghttp://arxiv.org/abs/0809.1869v1
• Particle data grouphttp://pdg.lbl.gov/