quark structure of the pion - kek · traditional interpretation of the nucleon form factors f...
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![Page 1: Quark Structure of the Pion - KEK · Traditional interpretation of the nucleon form factors F 1(Q2)= Z d3xeiQ·x⇢(r) ⇢(r)= X †(r) (r) However, the initial and final momenta](https://reader036.vdocuments.mx/reader036/viewer/2022081408/6060045dba037c3ba7548c39/html5/thumbnails/1.jpg)
Hyun-Chul Kim
RCNP, Osaka University &Department of Physics, Inha University
Quark Structure of the Pion
Progress of J-PARC Hadron Physics, Nov. 30-Dec. 01, 2014
Collaborators: H.D. Son, S.i. Nam
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2
Interpretation of the Form factors
Electromagnetic form factors
Non-Relativistic picture of the EM form factors
Schroedinger Eq. & Wave functions
Charge & Magnetisation Densities
3-D Fourier Transform
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3
Interpretation of the EMFFs
Traditional interpretation of the nucleon form factors
F1(Q2) =
Zd
3xe
iQ·x⇢(r) ⇢(r) =
X †(r) (r)
However, the initial and final momenta are different in a relativistic case.Thus, the initial and final wave functions are different.
Probability interpretation is wrong in a relativistic case!
We need a correct interpretation of the form factors
G.A. Miller, PRL 99, 112001 (2007)
Belitsky & Radyushkin, Phys.Rept. 418, 1 (2005)
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Interpretation of the EMFFs
Form factors
Lorentz invariant: independent of any observer.
Infinite momentum framework
Modern understanding of the form factors
GPDs
⇢1(b) =X
q
e
2q
Zdxfq�q̄(x, b)
F (q2) =
Zd2beiq·b⇢(b)
Transverse Charge densities ⇢(b)
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Hadron Tomography2 Generalised Parton Distributions
x bx
by
b⊥
x bx
by
xp
∼ 1Q2
b⊥
x bx
by
xp
∼ 1Q2
a | Form factor
0
ρ(b⊥)
b⊥
b | GPD, ξ = 0x
b⊥
q(x, b⊥)R
dx!! ∆→0 ""
c | Parton density
0
q(x)
x
Figure 2.1 | A simplified sketch of the different phenomenological observables and theirinterpretation in the infinite momentum frame: a | The form factor as a charge density inthe perpendicular plane (after a Fourier transform, Sec. 1.2). b | A probabilistic interpre-tation for GPDs in the case of vanishing longitudinal momentum transfer, ξ = 0, with aresolution ∼ 1/Q2. c | A parton distribution for the forward momentum case (Sec. 1.3).For a detailed explanation see text. [Pictures inspired by [17]]
(conventionally the z-direction) they can be seen as Lorentz contracted ‘discs’ rather thanspherical objects.1 We will later argue that this infinite momentum frame is necessary forthe GPDs. For the moment, we thus think of a two-dimensional distribution with respectto b⊥ in the transverse plane, sketched in Fig. 2.1.a. The z-direction is also suppressed infavour of the fractional (longitudinal) momentum x of the partons.
The second process led to parton distribution functions (PDFs) q(x) with the momentumfraction x carried by the parton. They give the probability of finding the parton q withthis momentum inside the hadron and they are sketched in Fig. 2.1.c. One can also give aresolution ∼ 1/Q2 that can be resolved inside the hadron. So for different Q2 partons ofa ‘different size’ can be probed, consequently the parton content of the hadron changes.
To achieve a deeper understanding of the distribution of the quarks inside the hadron, itwould be nice to combine the two cases, i.e. know the distribution in the transverse planefor quarks with a given momentum fraction. This is exactly one interpretation of GPDs.During the discussion of the form factor and the PDFs, we already mentioned the similarityof the matrix elements appearing in Eqs. (1.5) and (1.10). The initial and final states ofthe two processes differed only in their momenta (after applying the optical theorem).There are indeed processes with different asymptotic states that can be related to the twoaforementioned, thus coining the term generalised distributions. We will later considerthe problems arising from the complete freedom of the two momenta. For the moment,note that a density interpretation is possible if the longitudinal momentum transfer ξvanishes. A Fourier transform of the remaining transverse momentum transfer then yields
1Neglecting relativistic corrections, this would not be necessary for the form factor where we have elasticscattering with momenta down to zero.
10
D. Brömmel, Dissertation (Regensburg U.)
Transverse densities of Form factors GPDs Structure functions
Momentum fraction
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Generalised Parton DistributionsProbes are unknown for Tensor form factorsand the Energy-Momentum Tensor form factors!
Pion
Pion
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Generalised Parton DistributionsProbes are unknown for Tensor form factorsand the Energy-Momentum Tensor form factors!
Form factors as Mellin moments of the GPDs
Pion
Pion
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Experimentally, we know about the pion
• Pion Mass = 139.57 MeV • Pion Spin = 0
What we know about the Pion
Theoretically
• pseudo-Goldstone boson • The lowest-lying meson
(1 q + 1anti-q + sea quarks + gluons + …)
The structure of the pion is still not trivial!
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xP
8
The spin structure of the Pion
x
y
zb�
Vector & Tensor Form factors of the pion
u
d̄
Pion: Spin S=0
Internal spin structure of the pion
h⇡(p0)| ̄�3�5 |⇡(p)i = 0
Longitudinal spin structure is trivial.
What about the transversely polarized quarks inside a pion?
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The spin distribution of the quark
Spin probability densities in the transverse plane An0: Vector densities of the pion, Bn0: Tensor densities of the pion
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The spin distribution of the quark
Spin probability densities in the transverse plane An0: Vector densities of the pion, Bn0: Tensor densities of the pion
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The spin distribution of the quark
Spin probability densities in the transverse plane An0: Vector densities of the pion, Bn0: Tensor densities of the pion
Vector and Tensor form factors of the pion
h⇡(pf )| †�µQ̂ |⇡(pi)i = (pi + pf )A10(q2)
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µ � 600MeV� � 0.3 fm, R � 1 fm
Dµ = @µ � i�µVµ
Nonlocal chiral quark model
The nonlocal chiral quark model from the instanton vacuum
• Fully relativistically field theoretic model.• “Derived” from QCD via the Instanton vacuum.• Renormalization scale is naturally given.•No free parameter
Gauged Effective Nonlocal Chiral Action
Musakhanov & H.-Ch. K, Phys. Lett. B 572, 181-188 (2003) H.-Ch.K, M. Musakhanov, M. Siddikov Phys. Lett. B 608, 95 (2005).D. Diakonov & V. Petrov Nucl.Phys. B272 (1986) 457
Se↵ = �NcTr lnhi /D + im+ i
pM(iD,m)U�5
pM(iD,m)
i
Dilute instanton liquid ensemble
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Nonlocal chiral quark model
Gauged Effective Nonlocal Chiral Action
Musakhanov & H.-Ch. K, Phys. Lett. B 572, 181-188 (2003) H.-Ch.K, M. Musakhanov, M. Siddikov Phys. Lett. B 608, 95 (2005).D. Diakonov & V. Petrov Nucl.Phys. B272 (1986) 457
Se↵ = �NcTr lnhi /D + im+ i
pM(iD,m)U�5
pM(iD,m)
i
U
�5 = U(x)1 + �5
2+ U
†(x)1� �5
2= 1 +
i
f⇡�5(⇡
a�
a)� 1
f
2⇡
(⇡a�
a)2 + · · ·
F (k) = 2t
I0(t)K1(t)� I1(t)K0(t)�
1
tI1(t)K1(t)
�
t =k⇢̄
2
M(iD,m) = M0F2(iD)f(m) = M0F
2(iD)
"r1 +
m2
d2� m
d
#
d ⇡ 0.198GeV
M0 ⇡ 0.35GeV : It is determined by the gap equation.
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EM Form factor of the pion
h⇡(pf )| †�µQ̂ |⇡(pi)i = (pi + pf )A10(q2)
EM form factor (A10 )
S.i. Nam & HChK, Phys. Rev. D77 (2008) 094014
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EM Form factor of the pion
h⇡(pf )| †�µQ̂ |⇡(pi)i = (pi + pf )A10(q2)
EM form factor (A10 )
: Local vertices
S.i. Nam & HChK, Phys. Rev. D77 (2008) 094014
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EM Form factor of the pion
h⇡(pf )| †�µQ̂ |⇡(pi)i = (pi + pf )A10(q2)
EM form factor (A10 )
: Local vertices
: Nonlocal vertices
S.i. Nam & HChK, Phys. Rev. D77 (2008) 094014
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��r2⇥ = 0.675 fm
��r2⇥ = 0.672± 0.008 fm (Exp)
EM Form factor of the pion
S.i. Nam & HChK, Phys. Rev. D77 (2008) 094014
M(Phen.): 0.714 GeV
M(Lattice): 0.727 GeV
M(XQM): 0.738 GeV
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Tensor Form factor of the pion
S.i. Nam & H.-Ch.K, Phys. Lett. B 700, 305 (2011).
⌦⇡+(pf )
�� †(0)�µ⌫ (0)��⇡+(pi)
↵=
pµq⌫ � qµp⌫
m⇡B10(Q
2)
p = (pf + pi)/2, q = pf � pi
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Tensor Form factor of the pion
Brommel et al. PRL101
S.i. Nam & H.-Ch.K, Phys. Lett. B 700, 305 (2011).
B10(Q2) = B10(0)
1 +
Q2
pm2p
��p
p-pole parametrization for the form factor
RG equation for the tensor form factor
B10(Q2, µ) = B10(Q
2, µ0)
↵(µ)
↵(µ0)
� 433�2Nf
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Tensor Form factor of the pion
S.i. Nam & H.-Ch.K, Phys. Lett. B 700, 305 (2011).
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Tensor Form factor of the pion
S.i. Nam & H.-Ch.K, Phys. Lett. B 700, 305 (2011).
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18Polarization
Unpolarized Polarized
spin
Spin density of the quark
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Spin density of the quark
Results are in a good agreement with the lattice calculation!
Significant distortion appears for the polarized quark!
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Spin density of the quark
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Stability of the pionIsoscalar vector GPDs of the pion
2�abHI=0⇡
(x, ⇠, t) =1
2
Zd�
2⇡eix�(P ·n)h⇡a(p0)| ̄(��n/2)/n[��n/2,�n/2] (�n/2)|⇡b(p)i
Zdx xHI=0
⇡ (x, ⇠, t) = A20(t) + 4⇠2A22(t)
The second moment of the GPD
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Stability of the pionIsoscalar vector GPDs of the pion
2�abHI=0⇡
(x, ⇠, t) =1
2
Zd�
2⇡eix�(P ·n)h⇡a(p0)| ̄(��n/2)/n[��n/2,�n/2] (�n/2)|⇡b(p)i
Zdx xHI=0
⇡ (x, ⇠, t) = A20(t) + 4⇠2A22(t)
The second moment of the GPD
: Generalized form factors of the pion
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Stability of the pionIsoscalar vector GPDs of the pion
2�abHI=0⇡
(x, ⇠, t) =1
2
Zd�
2⇡eix�(P ·n)h⇡a(p0)| ̄(��n/2)/n[��n/2,�n/2] (�n/2)|⇡b(p)i
Zdx xHI=0
⇡ (x, ⇠, t) = A20(t) + 4⇠2A22(t)
The second moment of the GPD
: Generalized form factors of the pion
h⇡a(p0)|Tµ⌫(0)|⇡b(p)i = �ab
2[(tgµ⌫ � qµqnu)⇥1(t) + 2PµP⌫⇥2(t)]
Energy-momentum Tensor Form factors (Pagels, 1966)
Tµ⌫(x) =1
2 ̄(x)�{i
!@ ⌫} (x) : QCD EMT operator
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Stability of the pionIsoscalar vector GPDs of the pion
2�abHI=0⇡
(x, ⇠, t) =1
2
Zd�
2⇡eix�(P ·n)h⇡a(p0)| ̄(��n/2)/n[��n/2,�n/2] (�n/2)|⇡b(p)i
Zdx xHI=0
⇡ (x, ⇠, t) = A20(t) + 4⇠2A22(t)
The second moment of the GPD
: Generalized form factors of the pion
h⇡a(p0)|Tµ⌫(0)|⇡b(p)i = �ab
2[(tgµ⌫ � qµqnu)⇥1(t) + 2PµP⌫⇥2(t)]
Energy-momentum Tensor Form factors (Pagels, 1966)
Tµ⌫(x) =1
2 ̄(x)�{i
!@ ⌫} (x) : QCD EMT operator
EMTFFs (Gravitational FFs)
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Stability of the pionIsoscalar vector GPDs of the pion
2�abHI=0⇡
(x, ⇠, t) =1
2
Zd�
2⇡eix�(P ·n)h⇡a(p0)| ̄(��n/2)/n[��n/2,�n/2] (�n/2)|⇡b(p)i
Zdx xHI=0
⇡ (x, ⇠, t) = A20(t) + 4⇠2A22(t)
The second moment of the GPD
: Generalized form factors of the pion
h⇡a(p0)|Tµ⌫(0)|⇡b(p)i = �ab
2[(tgµ⌫ � qµqnu)⇥1(t) + 2PµP⌫⇥2(t)]
Energy-momentum Tensor Form factors (Pagels, 1966)
Tµ⌫(x) =1
2 ̄(x)�{i
!@ ⌫} (x) : QCD EMT operator
EMTFFs (Gravitational FFs)
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Stability of the pion
H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
Time component of the EMT matrix element gives the pion mass.
The sum of the spatial component of the EMT matrix element gives the pressure of the pion, which should vanish!
(Based on the local model)
Zero in the chiral limit
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Stability of the pion
H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
Pressure of the pion beyond the chiral limit
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Stability of the pion
H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
Pressure of the pion beyond the chiral limit
Quark condensate
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Stability of the pion
H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
Pressure of the pion beyond the chiral limit
Quark condensate Pion decay constant
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Stability of the pion
H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
Pressure of the pion beyond the chiral limit
Quark condensate Pion decay constant
by the Gell-Mann-Oakes-Renner relation to linear m order
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Energy-momentum Tensor FFs
H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
in the chiral limit
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Energy-momentum Tensor FFs
H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
in the chiral limit
The difference arises from the explicit chiral symmetry breaking.
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Transverse charge density of the pion
H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
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26H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
Transverse charge density of the pion
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26H.D. Son & H.-Ch.K, to be published in PRD Rapid Comm.
Transverse charge density of the pion
The transverse charge density is divergent at b=0.
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HChK et al. Prog. Part. Nucl. Phys. Vol.37, 91 (1996)
Low-Energy Constants
Derivative expansions: pion momentum as an expansion parameter
Weinberg term Gasser-Leutwyler terms
Effective chiral Lagrangian
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Weinberg Lagrangian
H.A. Choi and HChK, PRD 69, 054004 (2004)
Gasser-Leutwyler Lagrangian
Effective chiral Lagrangian
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Gasser-Leutwyler Lagrangian
Low-energy constants in flat space
H.A. Choi and HChK, PRD 69, 054004 (2004)
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Gasser-Leutwyler Lagrangian
Low-energy constants in flat space
H.A. Choi and HChK, PRD 69, 054004 (2004)
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Effective chiral Lagrangian in curved space
Gasser-Leutwyler Lagrangian
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Effective chiral Lagrangian in curved space
Gasser-Leutwyler Lagrangian
Low-energy constants in curved space
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Effective chiral Lagrangian in curved space
Gasser-Leutwyler Lagrangian
Low-energy constants in curved space
They can be derived either by expanding the action by the heat-kernel method or expand the EMTffs with respect to t.
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Low-energy constants in curved space
Present Results
XPT Results (Gasser & Leutwyler)
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Summary & Conclusion
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Summary•We have reviewed recent investigations on the quark structures of the pion, based on the nonlocal chiral quark model from the instanton vacuum.
• We have derived the EM and tensor form factors of the pion, from which we have obtained the quark transverse spin densities inside a pion.
•We also have shown the energy-momentum tensor (gravitational or generalised) form factors of the pion.
•The pressure of the pion nontrivially vanishes because of the Gell-Mann-Oakes-Renner relation.
•We also have presented the higher-order transverse charge density of the pion.
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Outlook• The transverse charge and spin densities for the transition processes can be studied (K-pi transition is done, see the next talk by Hyeon-Dong Son).
• The excited states for the nucleon and the hyperon can be investigated (Generalisation of the XQSM is under way).
•Internal structure of Heavy-light quark systems(Derivation of the Partition function is close to the final result.)
• New perspective on hadron tomography
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Thank you very much!
Though this be madness,yet there is method in it.
Hamlet Act 2, Scene 2