large-n c resonance relations from partial wave analyses
DESCRIPTION
EuroFlavours 07, 14-16 November 2007 Univ. Paris-Sud XI - Orsay. Large-N C resonance relations from partial wave analyses. J.J. Sanz-Cillero (IFAE - UAB). Z.H. Guo, J.J. Sanz-Cillero and H.Q. Zheng [ JHEP 0706 (2007) 030 ]; arXiv:0710.2163 [hep-ph]. Organization of the talk: - PowerPoint PPT PresentationTRANSCRIPT
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Large-NC
resonance relations
from partial wave
analysesJ.J. Sanz-Cillero (IFAE - UAB)
EuroFlavours 07, 14-16 November 2007
Univ. Paris-Sud XI - Orsay
Z.H. Guo, J.J. Sanz-Cillero and H.Q. Zheng [ JHEP 0706 (2007) 030 ];
arXiv:0710.2163 [hep-ph]
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Organization of the talk:Organization of the talk:
• Dispersive calculation for -scattering at large NC
• Matching PT at low energies
• Resonance coupling relations and LEC predictions
• Testing phenomenological lagrangians and LEC resonance estimates
• Conclusions
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Former large-NC resonance analysis have looked at
a) Form factors,
b) 2-point Green-functions
c) 3-point Green-functions
• Scattering amplitudes are the next in the line:
There have been studies on forward scattering
We propose the analysis of the PW scattering amplitudes
• In forward scattering s, t and u-channels have similar asymptotics
In PW amplitudes Each has a clearly distinguishable structure
Motivation
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• In general, the description in terms of couplings of a lagrangian
usually does not provide an intuitive picture of the 1/NC expansion:
Expansion parameter in the hadronic 1/NC theory ?
Model dependence of a lagrangian realization ?
…
• However, maybe we can reach a better understanding/agreement
if we express resonance couplings
in terms of physical parameters (like masses and widths)
Moreover…Moreover…
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Dispersive Dispersive
calculation of calculation of --
scatering scatering
at large-Nat large-NCC
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
2
+ 0I I I IJ J J J
-4m
s dt s dtT (s) - T (0) = ImT (t) + ImT (t)
t - s t - s
• T-matrix dispersive relation for : [Guo, Zheng & SC’07]
Resonance inputs:
•Right-hand cut cut (s-channel)(s-channel)
•Left-hand cut (t- and u-channels)(t- and u-channels)
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• At large-NC s-channel narrow-width resonance exchanges:
For the right-hand cut:For the right-hand cut: TJI partial wave ONLY IJ
resonance
I 2J R R R
R
1ImT (t) = M Γ δ t-M
ρ2
R 2R
4m = 1-
Mρ
Right-hand cut
with0t
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• We substitute this ImT(t)
in the right-hand side dispersive integral and obtain
I sR R RJ 2
R R
1 s M ΓT (s) =
M - s ρ
which can be identified with the exchange
of a tree-level resonance R
in the s-channel
R
MR , R
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Crossing symmetry relations for right and left-hand cut:
I+J
I stJ II'2
J' I'
1+(-1)ImT (s) = (2J'+1)C
s-4m
2
2
4m -sI'
J J' J'2 24m
2t 2s × dt P 1+ P 1+ ImT (t)
s-4m t-4m
0s
24t m
Left-hand cut
(true for any s<0
for large-NC tree-level amplitudes)
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
TJI partial wave almost EVERY narrow-width state RJ’
I’
contributes in the t and u-channels
I+JI 2 2 stJ R II'2
1+(-1)ImT (s) = θ(s-M +4m ) × (2J'+1)C
s-4m
2R
J J' R R2 2 2R R
2M 2s 1 × P 1+ P 1+ × M Γ
s-4m M -4m
ρ
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
which can be identified with the exchange
of a tree-level scalar resonance
in the crossed-channel
• By placing ImT(s) in the left-hand cut disperive integral:
Explicit analytical expression TJI(s)tR
for the contribution from the exchange
of a resonance R in the t (and u) channels.
• For instance, for R=S and the partial wave T11:
2 2 2 2 2 2 2 2I tS S S S S S SJ 2 2 2 2 2 4 2
S S S
2 M Γ s+2M -4m s+M -4m 2m -M s+M -4msT (s) = - + ln + ln
3 2m (s-4m ) (s-4m ) M 8m M
ρ
S
MR , R
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
I I I sR I tRJ J J J
R R
T (s) - T (0) = T (s) + T (s)
• Putting the different contributions together gives
• In our analysis, only the first V and S resonances have been included.
• Problems when higher-spin resonances were included.
Final dispersive expression
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Matching Matching PT PT
at large-Nat large-NCC
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• We perform a chiral expansion
of the resonance contributions TsR and TtR
I sR 2 4 6JT (s) = (p ) + (p ) + (p ) + ... O O O
I tR 2 4 6JT (s) = (p ) + (p ) + (p ) + ... O O O
in powers of s and m2
• For T(s) and T(0) , we use the values provided by PT up to (p6)
(amplitudes expressed in terms of s, m
2
and m-independent constants)
MR , R
LECs
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• This produces a matching equation of the form,
I PT I PT I sR I tRJ J J J
R R
T (s) - T (0) = T (s) + T (s)
where we match left and right-hand side
order by order in (m2)m sn ,
LECs MR , R
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• We have taken the matching up to (p6):
At (p2) we match the terms
At (p4) we match the terms
At (p6) we match the terms
(m2) NOT PRESENT
(s) mod-KSRF relation
(m4) NOT PRESENT
(s m2) Reson. relation
(s2) L2, L3
(m6) NOT PRESENT
(s m4) r2 - 2rf
(s2m2) r3, r4
(s3) r5, r6
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Simultaneous analysis of the IJ=11,00,20 channels
Compatible system of 18 equations: rank 9
number of unknowns = 9
• One must take into consideration that MR and R
are the physical large-NC masses and they also depend on m
4
2
2RR
R33R R R
+ (m )mΓ Γ
= 1 + ,M M M
O
…
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Matching at (p2):
the (s1 m0) term Modified-KSRF relation
(constraint)(constraint)
• To exemplify the matching, we explicitly show this case:
V S
3 32V S
1 3Γ Γ + ... = + + ...
96 f 2M 9M s s
IJ=11 :
IJ=00 :
IJ=20 :
V S
3 32V S
1 9Γ 2Γ + ... = + + ...
16 f M 3M s s
V S
3 32V S
- 1 9Γ Γ + ... = - - + ...
32 f 2M 3M s s
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• The three channels provide exactly the same constraint
which is a modification of the KSRF relation
that takes into account S resonances and crossed exchanges:
V S
3 32V S
1 9Γ 2Γ = +
16 f M 3M
to be compared to the original result,
V2 3
V
6Γ1 =
16 f M
2
V
g MΓ =
48
with
[Kawarabayashi & Suzuki’66]
[Riazuddin & Fayazuddin’66]
The original KSRF relation is recovered
in our analysis of the IJ=11 channel
if we neglect the impact from S resonances and crossed V exchanges
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Matching at (p4):
the (s1 m2) term Novel resonance constraintconstraint
• The three channels provide exactly the same constraint:
This new relation provides a constraint between
the m2 corrections to masses and widths.
S V
S V5 5S V
2Γ 9Γ0 = +6 + +6
3M M
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Matching at (p4):
the (s2 m0) term PredictionPrediction for L2 and L3
• The three channels provide two compatible constraints for the LECs: V4
2 5V
ΓL = 12 f
M
S V43 5 5
S V
2Γ 9ΓL = 4 f -
3M M
where similar results in terms of widths and masses
were also found in previous works [ Bolokhov et al.’93]
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Matching at (p6):
(s m4), (s2 m
2), (s3 m0) PredictionPrediction for r3,4,5,6 and r2 -
2rf
• The three channels provide compatible constraints for the LECs:
S V6 6S S2 f S S7 7
S V
2 Γ Γ
r - r = 64 f 1+ + + f 7584+ + 3 6M M
with R and R given by the chiral corrections,
...3r = [Guo, Zheng & SC’07]
6
2 4
2 4RR
R R33R R R R
+ (m )m mΓ Γ
= 1 + + M M M M
O
4
2
2RR
R55R R R
+ (m )mΓ Γ
= 1 + M M M
O
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Origin of the relations
• Good high-energy behaviour
• Good low-energy behaviour
Once subtracted
dispersion relations
PT matching
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
On the consistency On the consistency
of of
phenomenological phenomenological
lagrangianslagrangians
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Linear Sigma Model [’60,’70,’80,’90…]
• Gauged Chiral Model [Donoghue et al.’89]
• Resonance Chiral Theory (RT) [Ecker et al.’89]
and extended versions of RT [Cirigliano et al.’06]
We analysed a series of different phenomenological lagrangians:
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• For sake of lack of time I will not explain
the first two cases in detail
(although they are exhaustively analysed in [Guo, Zheng & SC’07])
Nevertheless, the conclusion was that:
- Our dispersive predictions of the LECs
exactly agreed those obtained through the standard procedure
(integrating out the heavy resonances)
- We extracted constraints between resonance couplings
that were intimately related to the asymptotic high-energy behaviour
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
…Hence, I will focus on the last type of lagrangian.
First we will analyse
the original version of [Ecker et al’89],
the Minimal Resonance Chiral Theorythe Minimal Resonance Chiral Theory
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Non-linear realization for the Goldstones
• No assumptions on the vector and scalar nature
• Originally, only linear operators in the resonance fields were considered in the lagrangian:
RL μ μVd μ m + μ
i G = c S u u + c S + V u u +...
2
KinORL L L L
2(p )R T PT = + +
with the linear terms including only (p2 ) tensors,
[Ecker et al.’89]
• Procedure:Procedure: 1) First, we compute MR, R
2) Second, we check our relations
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
1.) We get the widths at LO in 1/NC:
33 22SV dV
V SV SV S 4 4
3 c M G M M =M , M =M , Γ = , Γ =
48 f 16 f
S
2d mm
SS 2 2dS
m 16 c c4 cΓ = Γ 1 + -6 + - +...
c fM
V
22Vd m
VV 2 22V S
m 16 c c MΓ = Γ 1 + -6 - +...
fM M
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Integrating out the resonances in the generating functional,
one gets the LECs corresponding to this action: 2V
2 2V
GL =
22dV
3 2 2V S
c3GL = -
2.) We compare the standard results and our LECs predictions:
[Ecker et al.’89]
• And using the dispersive predictions one gets a complete agreement: 2
V4 V2 5 2
VV
GΓL = 12 f =
M
22S V4 dV
3 5 5 2 2V SS V
c3G2Γ 9ΓL = 4 f = -
3M M
(SIMILAR AGREEMENT WAS FOUND IN THE ANALYSIS OF THE OTHER LAGRANGIANS)
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• From the modified-KSRF constraint we get,
2 2d V
2 2
2c 3G1 = +
ff
• And the S,V constraint yields,
2 2d V
m m2 2
4c 6G1- c = c
ff
But notice that for
both constraints are incompatible
mc 0
…and study the resonance relations:
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
What is the problem in this What is the problem in this case?case?
• If we introduce the operator cm <S +> ,
it must come together with other operators
(if it is introduced alone, wrong results)
• What is special in the cm operator?
It is an operator that couples the scalar to the vacuum
proportionally to mq
• This makes f and the S-, V- vertices m dependent
even at large-NC
• However, we will see that this m dependence
may be produced by other operators not considered
S
SV
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Extensions to Extensions to
Resonance Chiral Resonance Chiral
TheoryTheory
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
For a clearer understanding we will focus first on the scalar sector:
• Allowing a more general structure in the resonance lagrangian,
the scalar mass and width gain additional (m2)
corrections
from the extra resonance operators [Cirigliano et al.’06],
SL S μ S μ6 + μ 7 μ + = λ S , u u + λ S u u
SSL SS μ SS μ SS1 μ 2 μ 2 + = λ S S u u + λ Su S u + λ SS
SSSL SSS SSS μ0 1 μ = λ S SS + λ S S S
<R(p4)>
<RR(p2)>
<RRR(p2)>
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• In order to compute the amplitudes free of scalar tadpoles we perform the mq-dependent shift,
M(o)
m 0q 2
S
4 c B S S +
M
• This provides the contribution to the mass and S- vertex,
now free of S tadpoles.
The S- interaction, in the isospin limit shows the structure,
[SC’04]
L M effeff r μ eff r r μ r 2 r rd μ m + 0 q μ S
1 = c S u u + c S ( - 4B ) + S S - M SS +...
2
With the m dependent parameters
2effd d d 2
S
mc =c 1 + δc + ...
M
2S S S SS SS SSSm
d 6 7 1 2 1 md d
4c2Mδc = 2λ +λ + 2λ +λ - 2λ c
c c
and MSeff = MS + O(m
2), cmeff = cm + O(m
2),
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Likewise, the pion decay constant gets m corrections at large NC,
12
2- d m
2 2S
m 4c c f =f Z = f 1+ f +... , with f =
fM
• Hence, the ratio /M3 for the scalar becomes,
eff 2 2S d S m
23 4S dS
Γ 3c 4m c = 1+ -1
M 16 f cM
S
2
d 2d
f = 2 c - 4 f + f
c
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Following a similar procedure for the vector we would have an effective coupling,
leading to the ratio,
2effV V V 2
V
mG =G 1 + δG + ...
M
eff 2 3V V V
3 4V
Γ G =
M 48 f
V
2V
V 2S
M = 2 G - 4 f
M
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Finally, putting everything together one gets the KSRF and S,V constraints:
22d dV V
2 2 2 24 4 2V S S S
2c (2 c -4 f)3G 2 G 4 f 1 2 f - + + = 0
ff fM M M M
22dV
4 4 2
2c3G 1 + =
ff f
which can be easily combined in the single form
effeff 2 2dV
4 4 2
2c3G 1 + =
ff f
But what is the meaning of this?
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• At high energies the amplitude behaves like
Oeffeff 2 2
1 0dV1 2 2 2
2 c 3 G sT (s) = 1 - - + s
96 ff f [ SIMILAR RESULT FOR
IJ=00,20 ]
It is then clear now that the KSRF and S,V constraints
are equivalent to demanding a good behaviour
at high (and low) energies
Chiral lagrangians
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
ConclusionsConclusions
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• New dispersive method for the the study
of LECs and resonance constraints at large-NC
• Easy implementation of high & low-energy constraints
independent of the realization of the resonance lagrangian
• Successfully checked for a wide set of different
phenomenological lagrangians
• Useful tool for future studies of other scattering amplitudes
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
1.)1.) Linear Sigma Linear Sigma
ModelModel
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Only Scalar + Goldstones (no Vectors)
• For our first check we use the LM, where the scalar and the Goldstones are introduced in a linear realization:
• Simple model with useful properties that give a first insight of the meaning of these constraints.
• Procedure: 1) First, we compute MS, S
2) Second, we check our relations
22 2 2 2 2 2 2 2
L M
1 1 1 = + σ + μ +σ - λ +σ +f m σ
2 2 4 L
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Renormalizability
• Chiral symmetry
Good high-energy behaviour
Good-low-energy behaviour
No place for further constraints
However, renormalizability is not the keypoint,
as we will see in the next example.
The KSRF and S,V constraints are trivially fulfilled for any value of
and
S
32S
1 2 Γ =
16 f 3 MKSR
F
S,V 0S =
[ T(s) ~ O(s0) when s∞ ]
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
2.)2.) Gauged Chiral Gauged Chiral
ModelModel
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Only Vector + Goldstones (no Scalars)
• The and a1 are introduced as gauge bosons
in the (p2) PT lagrangian :
2 2 2μ † †o
G M μ
f m f = D U D U + U+ U
2 2
L
μ μ 2 μ μμ μ o μ μ
1- L L + R R + M L L + R R 4
However, due to the -a1 mixing,
one finds a highly non-trivial interaction,
which makes the calculation of the -scattering
rather involved
[Donoghue et al.’89]
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Integrating out the resonances in the lagrangian,
one gets the corresponding LECs at large-NC : 2 4
2 4V
g fL =
2 4
3 4V
3 g fL = -
• If we now use the dispersive predictions we get exactly the same:
2V
V V
g MΓ =
2 4V4
2 5 4VV
g fΓL = 12 f =
M
2 4
V43 5 4
VV
3 g f9ΓL = 4 f = -
M
with
(p(p44) LECs :) LECs :
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• The S,V constraint is trivially obeyed since we find
0
2
5V V
V 2 3V V m
M Γ d = = -6
Γ dm M
• This is not so for the KSRF constraint, which gives
V
32V
1 9Γ =
16 f M
2
2 2
V
3 g f 1 =
M
Origin of these constraints? Observe the -scattering amplitude at s∞ :
2
2 21 01 2
V
3 g fsT (s) = 1 - + s
96 f M
O [ SIMILAR RESULT FOR
IJ=00,20 ]
Resonance Resonance constraints :constraints :
V + 6
2V
V V
g MΓ =
= (m0) + 0 x (m
2)
TRIVIAL S,V relationKSRF relation
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• Through the explicit integration of the heavy resonances in the generating functional one gets the LECs corresponding to this action:
2V
2 2V
GL =
22dV
3 2 2V S
c3GL = -
• We also get the widths at LO in 1/NC,
33 22SV dV
V SV SV S 4 4
3 c M G M M =M , M =M , Γ = , Γ =
48 f 16 f
S
2d mm
SS 2 2dS
m 16 c c4 cΓ = Γ 1 + -6 + - +...
c fM
V
22Vd m
VV 2 22V S
m 16 c c MΓ = Γ 1 + -6 - +...
fM M
Large-NC resonance relations from partial-wave analyses
J.J. Sanz-Cillero
• If we now use the dispersive predictions we get exactly the right results for the LECs:
2V4 V
2 5 2VV
GΓL = 12 f =
M
22S V4 dV
3 5 5 2 2V SS V
c3G2Γ 9ΓL = 4 f = -
3M M
In complete agreement
with the original lagrangian calculation [Ecker et al.’89]