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The Nambu-Jona-Lasinio model and the chiral anomaly
ANNALS
OF PHYSICS
193, 287-325
(1989)
The Nambu-Jona-Lasinio Model and the Chiral Anomaly* M. WAKAMATSU~ Instiiute of Theoretical D-8400 Regensburg, Received
Physics. Federal September
University Republic
of Regenshurg,
qf German?
21, 1988
An approximate bosonization of the Nambu-Jona-Lasinio model is shown to lead to either form of two low energy effective Lagrangians: i.e., the massive Yang-Mills form or the hidden local symmetry form of Bando et al. The specific underlying quark Lagrangian restricts the freedom in obtaining the anomalous effective action on one and the other scheme. This enables us to show the equivalence of the two schemes not only for the physics of the nonanomalous sector but also for the physics of the anomalous sector. Our model in either representation however breaks low energy theorems for some of the anomalous processes. In pursuit of its origin, we investigate the general structure of the hadronic currents in the present model, putting special emphasis upon the underlying Lagrangian at the quark level. As an interesting byproduct of the present analysis. we gain a new insight into the dynamical meaning of the parameter a, which appears as a free parameter in the hidden symmetry model of Bando et al. I(” 1989 Academic Press, Inc.
1. INTRODUCTION Growing attention has recently been paid to the low energy effective Lagrangians of QCD which incorporate vector (and axial-vector) mesons in addition to the Goldstone pion field [l-3]. This renewal of interest in the low energy effective Lagrangians owes greatly to the conjecture that, at low energy and in the limit of large number of colors IV,, QCD reduces to a nonlinear effective theory of weakly interacting mesons [4,5]. Since baryons emerge as topological solitons in such a theory, their properties are intimately connected with the physical parameters of the meson sector [6-91. There are two popular ways of introducing vector (and axial-vector) mesons into the original chiral Larangian, i.e., the non-linear sigma model. The first one is the so-called massive Yang-Mills approach [ 10-121. The guiding principles are chiral symmetry and non-abelian gauge symmetry: the latter is “minimally” broken due to mass terms inserted by hand. The second approach, which has recently received increasing attention is the hidden local symmetry approach due to Bando er al. * Work supported in part by BMFT, Grant MEP 0234 REA. ’ Permanent address: Department of Physics, Osaka University,
Japan.
287 0003-4916189
$7.50
Copyright :K-’ 1989 by Academtc Press. Inc All rghts of reproduclmn in any form reserved
288
M. WAKAMATSU
[13, 143. They suggested that the vector mesons p, o, K*, and 4 are dynamical gauge bosons associated with the hidden [U(3),,],,,,, symmetry in the U(3), x U(3),/U(3), nonlinear chiral Lagrangian. Under the assumption that the composite gauge boson acquires a kinetic term, they obtained an effective Lagrangian compatible with the vector meson phenomenology which is manifest, e.g., in the KSFR relation [15, 163, the universality of the p couplings, the p-dominance of the pion electromagnetic form factor etc. [12]. In consideration of the phenomenological success of both approaches, we naturally come to the following question. Is there any fundamental relationship between these two apparently different schemes? An answer to this question was recently given by Meigner and Zahed [ 171 and also by Yamawaki [IS] at a formal level; it was given by us at a dynamical level in a recent paper [19] (hereafter referred to as (I)). To be explicit, it has been revealed through several recent studies [19-221 that either form of two low energy effective meson Lagrangians, i.e., the massive Yang-Mills one or the hidden symmetry one of Bando et al. [13, 143, can be derived from a single quark theory, i.e., the generalized Nambu-Jona-Lasinio (NJL) model, as a result of an approximate bosonization procedure [20,21]. A crucial observation there was that the field variables corresponding to the vector meson (and also the axial-vector meson) in both schemes are related to each other through a chiral transformation which depends on the Goldstone pion field. (It is sometimes called the Stiickelberg transformation in the literature [17, 181.) Although the forms of these two effective Lagrangians are quite different, it was claimed that the predictions of the two schemes are identical as far as the mass relations and the (non-anomalous) on-mass-shell vertices are concerned [3]. Then, a natural question is whether or not the above equivalence between the two schemes can be extended to the physics of the anomalous sector that concerns intrinsicparity violating processes. The physics of the chiral anomaly, especially in the presence of the hadronic vector and axial-vector fields, is rather involved, and there still remain some open questions [23-341. A standard prescription adopted in the massive Yang-Mills scheme [23-321 is to assume that the intrinsic parity violating processes originate in the gauged Wess-Zumino-Witten action [35, 361 (in the Bardeen subtracted form [37]) in which the gauge fields are identified with the phenomenological vector meson (and possibly the axial-vector meson too). The vertices involving the external gauge fields are assumed to be present in the non-anomalous part only, precisely in the form of a direct coupling between the vector meson and the external gauge fields [ 121. This immediately leads to the vector meson dominance of the intrinsic parity violating processes (as well as the intrinsic parity conserving ones). The above procedure is known to give a good phenomenological description but it is generally believed to have two unpleasant features [27, 29, 33, 343. First, in this theoretical framework, we are obliged to introduce the axial-vector meson as a gauge field simultaneously with the vector meson in order to preserve U(n) x U(n), symmetry. But the gauging of the anomalous axial-vector channel has a danger that the equations of motion may be mutually inconsistent, as was pointed out by
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289
Kaymakcalan, Rajeev, and Schechter [27--291. Second, the introduction of the axial-vector meson in this way forces us to choose Bardeen’s form of the anomaly because the left-right symmetric form no longer respects the vector current conservation. The Bardeen form of the anomaly, however, explicitly breaks the chiral U(n) x U(n), symmetry. Being aware of the above difficulties, Fujiwara et al. treated the anomaly problem in a different way in the hidden symmetry approach [33]. (See also Ref. 34).) The anomaly is assumed to sit in the part of the effective action that includes the Goldstone bosons and the external gauge fields alone, which is nothing but the gauged Wess-Zumino-Witten action in its original version. The vertices which contain the internal (or hadronic) vector meson are assumed to be included in the chiral gauge invariant (anomaly-free) but intrinsic parity violating part of the effective action, It should be emphasized that this part containing several arbitrary coefficients can be fixed only phenomenologically [33]. In a recent paper [38], Scoccola, Rho, and Min performed a comparative analysis of the anomalous process, K+ Kp -+ 3n, using both the massive Yang-Mills scheme (they call it the external gauging scheme) and the hidden symmetry scheme of Fujiwara et al. [33]. In the hidden symmetry scheme, the above 5-Goldstone vertex is saturated by the contribution of the Wess-Zumino action which depends on the Goldstone fields alone. Any other contributions from the vector meson mediated diagrams exactly cancel among themselves in the low energy limit [33]. On the other hand, in the massive Yang-Mills scheme (it is important to remember that for the purpose of comparison they had to eliminate the axial-vector field in this scheme in a particular way explained later), Scoccola et al. found that the prediction based on the Wess-Zumino term, which is known to reproduce the low energy theorem, receives an intolerably large modification due to the vector meson mediated processes. According to their analysis, there appears to be no natural way in the massive Yang-Mills scheme to suppress additional significant contributions from vector mesons. From this fact, they concluded that the massive YanggMills scheme is not consistent with QCD anomalies, and only the hidden symmetry scheme is acceptable as a consistent framework. In this paper, we wish to reexamine this conclusion. Our conclusion is in fact that neither of the schemes is superior to the other. It is not a problem of scheme (or representation) but rather how to treat the chiral anomaly. Let us now clarify this point in the rest of the paper. The paper is organized as follows. In Section 2, the two forms of effective Lagrangians, i.e., the massive Yang-Mills and hidden symmetry ones, are derived through an approximate bosonization of the generalized Nambu-Jona-Lasinio model. The description of this derivation is divided into three subsections. In the first subsection, we give a precise definition of the effective meson action based on the proper-time regularization scheme of the fermion path integral. Then, the nonanomalous and anomalous parts of the effective action are separately discussed in the following two subsections. Section 3 shows a comparative study of several non-
290
M. WAKAMATSU
anomalous processes using both the massive Yang-Mills and hidden symmetry schemes. The corresponding analysis of the anomalous processes are given in Section 4. In Section 5, we shall analyze the general structure of the hadronic currents in the present model, paying special attention to the underlying Lagrangian at the quark level. Concluding remarks are given in Section 6.
2. BOS~NIZATION 2.1. Definition
OF THE NAMBU-JONA-LASINIO
MODEL
of Effective Meson Actions
The starting point of our analysis is the following Lasinio (NJL) model [ 3942, 20, 211: .2-
YNJL = W‘ drq + 2G, 1
generalized Nambu-Jona-
1
((4T”q)’
+ (qiy’ T”q)2}
Cl=0
rl-
2G2
c 0=0
1 {GWT”d2
+
@“WW2}.
(2.1)
Here q are the quark fields, n is the number of the flavor degrees of freedom, and T, are generators of the flavor U(n) group normalized as tr(TaTb) = IS,,. (The color indices of quarks are not explicitly shown.) Throughout the present study, we shall neglect the bare quark masses, for simplicity. In this limit, the above Lagrangian has exact global U(n), x L(n), symmetry. Naturally, the NJL model cannot be a “true” substitute for the QCD Lagrangian, but there are several good reasons to assume that it might be a good low energy approximation to the QCD Lagrangian. It correctly describes the spontaneous chiral symmetry breaking of the QCD vacuum. Furthermore, owing to the approximate bosonization techniques we can develop a clear understanding about the relationship between the NJL model and some low energy effective meson Lagrangians, as far as the physics of the nonanomalous sector is concerned [19-22, 433. Then, we expect that it should provide useful information also for the physics in the anomalous sector. In our treatment, the introduction of the electroweak interaction is uniquely done at the quark level, by gauging an appropriate subgroup of the flavor [U(n), x U(n),],,,,,, group [ 19,201. (Here we may have in mind, for instance, application to the standard SU(2), x U( 1) y electroweak interaction model.) In general, one may try to gauge an arbitrary subgroup H of U(n), x U(n),, with generators K”, e = 1, .... r. Each K” is a linear combination of generators TF and T> of U(n), and U(n),, Ku= T”,+ Ts. (Either Tz or T: may vanish for some value of a.) Thus, the electroweak interaction is introduced through the following minimal replacement of the quark kinetic part of the Lagrangian
NAMBU-JONA-LASINIO
where PRiL = $ (1-I y’), gauge fields. After introducing the scalar), V,(vector), A, valued) [19-22, 40-433,
and gp = -i%‘;T”,
291
MODEL
and Yp = -iU;1,TO,
are the external
color singlet collective meson fields S (scalar), P (pseudo(axial-vector) in the standard way (they are all matrixthe gauged NJL Lagrangian can be cast into the form:
-&trCS2+ 1
P21 -&
2
tr[Rt+
(2.3)
LfL] + YC,,.
Here and hereafter we interchangeably use the vector and axial-vector notation (V,, A,) and the right- and left-handed notation (R, = V,, + A,,, L,, = V,, - A,,). Let us furthermore introduce the change of the field variables as S+iP=
(2.4)
in terms of a hermitian matrix C and a unitary matrix 5 [19-221. The latter is parametrized as t(x) = einCx)uain terms of the Goldstone pion field n(~). (A more general parametrization S + iP =
-&tr[(R,-~~)2+(L,,-~~)2]-~tr~2+~,, 2
I
11 ,
(2.6)
292
M. WAKAMATSU
where @(g, L’) is the integration measure for the transformed fermionic part of the generating functional is given by
fields (2.4) and the
Z~~,~,R,,L,)=SYq~rlexp
(2.7)
where N, is the number of colors of quarks and iD = z’y”(a, + R,P,
+ LpPJ
- (&tP,
+ <+Zt+PL).
It is now convenient to perform a chiral (or Weinberg) as
Corresponding
rotation
(2.8 1
of the quark fields
XR(X)= 5(x) cl&)?
(2.9a)
XL(X) = 5’(x) 4Ax).
(2.9b)
to this chiral rotation, @m
the fermion integral measure changes as = (J(~))Nc~x~~,
(2.10)
where (J(<))Nc is the Jacobian of the transformation (2.9) [20, 21, 44, 453. (The functional dependence of J on R, and L, is not explicitly shown, for notational brevity.) Performing the fermion integration, we then have Z,j& Z, R,, L,) = (J(S))Nc(det iDS)Nc,
(2.11)
where (2.12)
iDc=iy”(a,+ji,P,+z,P,)-C.
Here the chirally rotated vector and axial-vector defined by E, = W,
(right- and left-handed) fields are
+ a,) 5+,
2, = <+(L, + a,) r.
An important
relation
(2.13a) (2.13b)
obtained from Eqs. (2.7) and (2.11) is (det iD)Nc= (J(S)fNc(det iDr)Nc.
(2.14)
The apparently closed expression (2.7) or (2.11) for the fermion part of the generating functional is only formal. It contains divergences which must be removed by some regularization procedure. We adopt here the proper-time regularization scheme, which is known to automatically preserve vector gauge invariance [ 19-221. It is well known that the presence of a yVys coupling makes the Dirac operator iD in Eq. (2.8) (an analytic continuation to the euclidean action is implicit in the argument below) non-antihermitian and log det iD acquires an imaginary part which is
NAMBU-JONA-LASINIO
MODEL
293
not invariant under a chiral transformation [20, 211. To be explicit, the precise definition of log det iD in the proper-time regularization scheme is given as follows [20,21]: log(det iD)Nc = N,. log jdet iD[ + id,
(2.15)
N,. log ldet iDI = 9 Tr’ log DtD = $ s,‘,, 4 Tr’ em rotn,
(2.16a)
where
and d = N,.Im(log
det iD) = - 2 Im [,I,: $ Tr’ e -T(zD)2.
(2.16b)
Here ,I is the intrinsic cutoff of the present theory, Tr = j d4 x tr and a prime indicates that a trace over Dirac indices is included. As is well-known [20, 211. the real part of log(det iD)“‘< contributes to the non-anomalous part of the effective action, while the imaginary part of it gives the anomalous effective action. These two parts of effective action are evaluated in the following two subsections. 2.2. The Non-Anomalous Effective Action As was pointed out by several authors [20,21], minant is chiral gauge invariant, i.e., I det iDI = (det iDi I.
the modulus of the quark deter(2.17)
This quantity, which is related to the non-anomalous part of the effective action, can be straightforwardly evaluated by using the heat-kernel expansion, which is essentially a gradient expansion (i.e., an expansion in powers of derivatives of collective meson fields). It is immaterial which form of the Dirac operator, i.e., the original one iD or the chirally rotated one iD 5, is used in this evaluation (at least assuming infinite summation of the heat-kernel expansion). Dhar-ShankarrWadia [ 203 and Ebert-Reinhardt [21] chose to calculate 1det iD1, whereas Ball [22] and we (in (I)) chose ldet iDC I. We do not repeat here the analysis in (I), but show only its outline. First, truncate the heat-kernel expansion at terms of second order. Second, neglect the quantum fluctuation of the scalar field C around its (chiral symmetry breaking) vacuum expectation value, which amounts to setting m . Z with Z a n x n unit matrix and m the constituent quark mass. (The /!I- (U value of m may be determined as a solution of the NJL gap equation, which depends on the intrinsic cuttoff /1 of the theory [20,21].) Third, introduce the coupling constant g,. by the relation (2.18)
294
M. WAKAMATSU
where T(a, x) is the incomplete gamma function defined by T(a, x) = 1: dt e-‘F1. Then, examining the coefficients of the bilinear terms of the field variables in the resultant effective Lagrangian, we have the following relations: M’, = M$ + 6m2,
(2.19)
Here M, and MA are respectively the vector and axial-vector meson masses, while m is the constituent quark mass. Finally, defining the quantity u by the relation M2
a=
-1
( )
(2.20)
1-v
AI:
’
we are led to the following form of effective Lagrangian:
(2.21) where
i?,, = a,R, - a,& + cRp, R,], Z,, = a,Z, - a,& + [Z,, L",-J,
(2.22a) (2.22b)
and
D,5=a,tl+&-5& D,~t=a,~t+~,~t-~t~p.
(2.23a) (2.23b)
In I, this effective Lagrangian was shown to agree with the extended hidden symmetry Lagrangian of Bando et al. with special parameter choice [14] (more precisely, a gauge fixed form of it). The original version of their hidden symmetry Lagrangian [ 131 that contains no axial-vector meson, can be obtained in the following way. Since the axial-vector meson mass MA is much larger than the vector meson mass M,, and since we are interested in the low energy limit, let us assume that the kinetic term of the axial-vector meson can be ignored. In this case, by setting tr & = tr & = tr r$ with rflV = a, vV - a, P+ [VP, FYI, the 2, becomes a redundant field constrained by the equation of motion:
A&=
(2.24)
NAMBU-JONA-LASINIO
MODEL
295
We then arrive at
This form precisely coincides with the gauged version of the hidden symmetry Lagrangian given by Bando et al. [ 131, except that in the present approach the free parameter a of their model is uniquely given by a = ( 1 - M:,/Mi ) -’ in terms of the physical masses of the vector and axial-vector mesons. The value of a = 2, which led them to remarkable phenomenological success, is therefore inseparably connected with the Weinberg mass relation M, =&My [56] in our treatment. Obviously, the Weinberg mass relation is not an exact theoretical prediction of the NJL model. The relation given by this model is Mi = M’,.+ 6m’ (see Eq. (2.19)) with HI the constituent quark mass. The Weinberg mass relation follows if and only if M,,=JZm, which yields with 44, N 770MeV the constituent quark mass m N 315 MeV and the axial-vector meson mass M,, =&M,, N 1090 MeV. It is interesting to see that the above value of m is roughly comparable with the typical value of the constituent quark mass. Now we realize that the identification of the chirally rotated vector field 8, (and possibly the axial-vector field all) as a physical field in the bosonization procedure of the NJL model gives a microscopic foundation of the hidden symmetry approach. As mentioned before, we could alternatively evaluate the heat-kernel expansion based on the original Dirac operator iD. This would lead to another representation of the non-anomalous effective action, as a functional of the original vector and axial-vector fields V, and A, together with the Goldstone field. Practically, it is simpler to do the same thing in another way [19]. That is, by using the explicit relation (2.13) between the field variables, we can express Eq. (2.21) in terms of Vlc, A!,, and U (or R,, L,, and U). The result is
+ a-la r3 4 tr(D, ZJDpUt),
(2.26)
where D,U=d,U+L,U-
UR,,
D, Ut = a, Ut - UtL, -I- R, Ut.
(2.27a ) (2.27b)
296
M. WAKAMATSU
Although it appears that the pion kinetic term does not have its proper normalization, that is not the case. Due to the presence of the mixing term tr APPrc, A, is still an unphysical field. The elimination of this mixing term requires the introduction of the physical field Al through the relation A, + i( l/a)( l/f,) 8,x. After this diagonalization, the pion kinetic term emerges with the correct normalization. For the sake of completeness, let us rewrite the Lagrangian (2.26) in more conventional form [l-3, 10, 111. This can be done through the introduction of the unrenormalized quantities (related to the pion field) as follows:
n(x) = ,Tz k(x),
fr=JZfl,
(2.28)
with Z=-
U-l a
Then, we are led to another equivalent 1 P”)=-tr[V2 @2,
(2.29)
’
form of the Lagrangian
(2.26) as
PV+A2 PV]+5? ext
- a,fi2 tr( VP - VP)’ - a, f,” tr(A, - dP)* 1
+-f4" I2 tr(D PUDpUt) '
(2.30)
where u(x) = eiz’@)lfr and a, = UZ = a - 1. If we identify the p and A i meson with VP and A, (more precisely AL) instead of VP and a,(aL), respectively, Eq. (2.30) is just the massive Yang-Mills Lagrangian of Schwinger [lo] and of Wess and Zumino [ 111 except that it includes the electroweak couplings precisely so as to implement the exact current-field identities [ 121. Now we have confirmed that either form of the (non-anomalous) effective action, i.e., the hidden symmetry one or the massive Yang-Mills one, can be derived from a single quark Lagrangian, i.e., the NJL model. A basic ingredient which relates these two schemes is the chiral rotation (2.13) which depends on the Goldstone pion field. Although the appearances of these two effective Lagrangians are quite different, the physical predictions are identical, as will be illustrated by several examples in Section 3. The rest of this subsection is devoted to the question how to interpret the massive Yang-Mills Lagrangian [ 183. Let us first forget about the presence of electroweak gauge fields (that is, we set VP = dP =O). The idea of the massive Yang-Mills approach is to introduce the hadronic right- and left-handed fields (Rr and L,) as gauge fields of the flavor U(n), x U(n), symmetry, which transform as 4i-4
+ kh(-wu~)
L,(X) -g,(w,(x)
+ a,) d(x),
(2.31a)
+ a,) d,(x),
(2.31b)
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MODEL
297
where gR(x) and gL(x) are the elements of the gauged (or local) flavor U(n), x U(n), group. Although the kinetic terms are invariant under this gauge transformation, the mass terms are not. It is usually said that the gauge invariance is “minimally” broken due to the mass terms [ 1-3, 10, 111. However, the transformation properties (2.31) of the fields R, and L, do not follow from the present treatment in which these fields are introduced as collective meson field such that R,,(x) - qR(x) ypqR(x) and L,(x) - qL(x) yrqL(x), respectively. The transformation properties of R,, and L, suggested by this fact are R,,b) --+g,J-x) R,,(x) dJ.4~
(2.32a I
L,,(-x) + gL(-y) L,(-u) gm,
(2.32b)
rather than Eq. (2.31). Under this transformation, the mass terms are invariant, but the kinetic terms are not. This consideration reconfirms that the theory has only global U(n), x U(n), chiral symmetry (i.e., g, and g, must be restricted to x independent ones), which is certainly a symmetry of the original NJL model. (In any case, QCD is a color gauge theory but not a flavor gauge theory.) It is also instructive to see how the situation changes in the presence of the external gauge fields. A simple situation follows if we assume full “external” gauging of the flavor U(n), x U(n), symmetry, which amounts to introducing 2n2 external (or electroweak) gauge bosons in the present context. By definition, the external gauge fields transform as
under the gauged U(n), x U(n), transformation. Then, owing to the redefinition (2.5) together with Eqs. (2.32) and (2.33) the transformation laws of the new hadronic vector and axial-vector fields are just given by Eq. (2.31). That is, the new R,, and L, transform as gauge fields under the (externally) gauged U(n), x U(n). transformation (precisely in the same way as the external gauge fields %!P and 9’, do). Because of this fact, the generalized mass terms -uf 5 tr( I’,, - $,)I and --af z tr(A,- c$)2 in Eq. (2.26) are obviously gauge invariant [18]. Thus, in a licitious world where there exist 2n2 external gauge fields corresponding to the full flavor U(n), x U(n), symmetry, the notion of the massive Yang-Mills Lagrangian now becomes legitimate. (Curiously enough, what we have obtained is the “gauge invariant” massive Yang-Mills Lagrangian.) However, this conversely makes us conclude that in the real world where there are restricted number of external gauge fields, i.e., the photon, W’ and Z bosons, the notion of the massive Yang-Mills scheme cannot be justified in any strict sense. Summarizing the argument, we conform that the flavor symmetry is a global one, and simple-minded gauging of it has little meaning. The hadronic fields V, and A,, in our model are simply spin 1 composite particles of a quark and an antiquark,
298
M. WAKAMATSU
and they are not to be interpreted as Yang-Mills gauge fields, even though the formal appearance of the Lagrangian is that of the massive Yang-Mills model. 2.3. The Anomalous Now we turn to First, we point out the imaginary part Eq. (2.14), since
Effective Action the discussion about the anomalous part of the effective action. that the Jacobian 5(l) of the transformation (2.9) is related to of the (euclidean) effective action [20,21]. This is clear from
ZV,log J(r) = iN,(Im(log
det iD) - Im(log det iD5)}.
(2.34)
Here we have used the fact that the modulus of the quark determinant is chiral gauge invariant, i.e., Eq. (2.17). It is also clear from Eq. (2.34) that the Jacobian J(l) is a pure phase. For actual evaluation of J(c), more useful is the following formula which shows a response of J(t) under a small chiral (axial) variation of < from <=g to t=g+6g: NJ,
logJ(g)~N,(logJ(g+~g)-logJ(g)} = -iN,(Im(log
det iD g+ag) - Im(log det iDg)>
= -id,A(g). Here, the definition as
(2.35)
(2.16b) of A has been used. Noting
that Ljg G iDg is expressed
~‘g=(gPL+g+pR)~g=‘(gPL+g+pR),
(2.36)
we can show that &J$~Ijg+&-~Ez = f pgg+ -g+sg, Bq - f (g(dgg+ + g+dg), fig}.
(2.37)
On the other hand, using Eq. (2.16b), we have (2.38) Here, use has been made of the equality [bg, e-‘(‘g)2] = 0 and the cyclic properties of the trace. Then, by using Eq. (2.37), we find 6,A(g) = -NC Im Tr’{y’(Ggg+
+g+dg) eP(Bg)2/n2}.
(2.39)
The evaluation of the trace of y-matrix is long and tedious. The answer was already given by Dhar, Shankar, and Wadia [20] and also by Ebert and Reinhardt [21]. It is written in the form:
NAMBU-JONA-LASINIO
299
MODEL
N,.hA log J(g) = -i6,d d(g) = iTr(hg’
+ gt& 1GAL;,
where G,(LY,, RR,) is the chirally rotated Bardeen anomaly tional Ge(LI,, R,,) is given in the following form Ge(L,,,
RJ=s
( 2.40 )
R”, 1,
[20, 21, 471. The func
F;,+;F:+;A4-;(Fb,A2+AFL.A+A2Fv)
,
(2.41
1
with F,,=dV+
V’+A’,
(2.42a )
F,,,=dA+
VA+AV.
(2.42b)
Here we adopt the notation of differential forms [48851]. (The vector and axialvector fields are l-forms defined as V = V,dx@ and A = A, dxp and the l-form d= dxp8, denotes the exterior derivative.) The Jacobian J(5) itself can be obtained by integrating Eq. (2.40) between g = 1 and g = 5. The most elegant way of performing this integration is to use the differential geometric method [48-511. The independence of the final result on the integral path is assured by the WessZumino self-consistency condition for the anomalous action. This condition requires that the U(n), x U(n), group properties are maintained even in the presence of the anomaly [47-511. It is also understood as a generalized Bose symmetry in the -perturbative context [52]. This means that the axial-vector vertices (and also the vector vertices) appearing in the quark l-loop diagrams are treated symmetrically among themselves. The integration constant of the above integral is given by Im(log det iLIt), which was shown to vanish in the soft momentum limit by Dhar, Shankar, and Wadia [20] and also by Ebert and Reinhardt [21]. Then, N,. log J( 5) just gives the imaginary part of the fermion determinant, which is in turn to be interpreted as representing an anomalous action. The final answer can be written in several equivalent forms. For our later consideration, it is especially convenient to write it in the following form [Sl ]: r wzwC& L,,, &I = -iN,. log 4;) = W’o(L, R)-
W(‘(l, w),
(2.43)
where
where c’ = -i(N,./24z’)
WdL, R) = c’ jB5&(L, R),
(2.44)
i? = 5(R + d) 5+,
( 2.45a )
L = t+(L + d) i’.
(245b)
and
300
M. WAKAMATSU
Equation (2.45) is nothing but the differential form notation of Eq. (2.13). In Eq. (2.44), BS is a five-dimensional manifold with space-time as its boundary. The quantity c&+ , is the so-called Chern-Simons secondary form defined by c&+,(L,
R) = (n + 1) s,’ ds tr(A’(s) F”(s)),
(2.46)
where A’(s) = (d/ds) A(s) with A(s) = L + s(R - L),
(2.47a)
F(s) = dA(s) + A2(s).
(2.47b)
The particular choice of the integration path specified by Eqs. (2.46) and (2.47a) corresponds to vector gauge invariant regularization scheme [SO, 511. The quantity W’(L, R) is therefore invariant under vector gauge transformation. The standard process of obtaining the anomalous action in this formulation goes as follows [SO, 511. Using the vector gauge invariant property of W”(L, R), we obtain WO(L, R) = T((, 5) WO(Z, 8) = W’(L,
where T(gL, gR) defines the action U(n),,
R”),
of an element
(2.48)
g = g, P, + g,P,
E U(n),
x
and RU = U(L + d) UT,
(2.49)
U(x) = 5’(x) = $i=(x)/fn.
(2.50)
with
Then, we can rewrite Eq. (2.44) as r ,+/&U;
L,, R,] = W’(L,
R) - W’(L,
R”).
(2.51)
This form has the advantage that the effective action is represented in terms of the conventional unitary matrix U(x) and the vector and axial-vector fields V= i (R + L), A = i(R - L). Skipping the intermediate steps, we write down the final expression of this Wess-Zumino-Witten action. (For detail, refer to the review articles, for example, by Zumino [49] or by Petersen [Sl 1.) It is given as rwzwc
u; L, 3
$,I = c‘ jB5w;( UT dU, 0)
-c’s
sICp4(0,L,RC’)+p~(0,U+dU,R)-(U=1)1,
(2.52)
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MODEL
301
where (2.53 I
-&,tr(UtdU5,
ot(UtdU,O)=
~~(0, L, R) = $tr[(LR
- RL)(F,
+ FR) (2.54)
- L3R - LR3 + $ LRLR].
We point out that the resultant anomalous action is just the same as the one u priori assumed in the massive Yang-Mills treatment of the chiral anomaly [Z, 27-291. A key ingredient leading to this result is the redefinition (2.5) of the internal vector and axial-vector fields. As was already mentioned, this redefinition works so as to eliminate the couplings between the quarks and the electroweak gauge fields. As a consequence, we get the anomalous action as a functional of the hadronic vector and axial-vector fields (and also the Goldstone field) instead of the external gauge fields. Then, our next question is the anomalous action in the hidden symmetry scheme. What should be recognized here is the following fact. Since the anomalous action in our treatment (based on a fermion theory) is given as the Jacobian of the chiral transformation or equivalently as the imaginary part of log(det iD)N,, its determination is essentially unique, once the regularization of the fermion path integral is unambiguously defined. This means that, in order to obtain the corresponding anomalous action in the hidden symmetry scheme, we have only to rewrite the WesssZumino-Witten action which was already given as a functional of U, L, and R, in terms of the field variables U, t, and R with use of the relations (2.13 ) or (2.45). A brute force evaluation would be a cumbersome task. Fortunately, there is a simple way of doing it. Of fundamental importance is the symmetrical role played by the original (L, R) and the chirally rotated (2, R) left- and right-handed fields in the definition (2.43) of the Wess-Zumino-Witten action. This equation together with the relations (2.45) and their inverse relations, R = t+( ii + d) 5,
(2.55a)
L = <(L + d) it,
(2.55b)
enables us to express the Wess-Zumino-Witten r wzw= W’(L,
R)-
W’(t(L+d)
action in two equivalent forms as t+, S+(R+d)
5)
= - [ W”(~, iT) - W”((+(.t + d) 5, [(ii + d) <+)I.
(2.56)
Note that the two functional forms of rwzw (one as a functional of L, R, and rc, the other as a functional of z, R, and II) are very similar aside from the overall sign difference and the interchanged role of 5 and <’ (or n and -7-r). Now we can make use of an important property of the function W”( L, R) [48-5 11: it is antisymmetric under the exchange of L and R, i.e., W”(L, R)= -W’(R,
L).
(2.57)
302
M.WAKAMATSU
From this equality, there follows a well-known property of the Wess-ZuminoWitten action [35, 361: it is antisymmetric under the simultaneous exchange of L w R and U c) Ut (or n ++ --71). Then if, for example, the first line of Eq. (2.56) has vertex pieces such as dV”‘A” (1, m, n = integer, I+ n = odd), it is easy to see that the second line of Eq. (2.56) has corresponding
(2.58) vertex pieces
- (-71)‘PLP.
(2.59)
This provides us with a simple rule of constructing the anomalous action in the hidden basis, in which the chirally rotated fields P and 2 are identified as the physical particles. More precisely, an additional complication arises from the A,-n mixing. This must be removed by the following redefinition of the axial-vector fields
in the massive Yang-Mills
scheme, and J=A’-i-.-.
in the hidden difficulty.
symmetry
a-l a
1 f,
d*’
scheme. That can however be handled
without
any
3. PHYSICS OF THE NON-ANOMALOUS SECTOR In this section, we shall investigate some physical implications of our effective Lagrangians, concerning first the physics of the non-anomalous sector. The main objective is to show the equivalence of the massive Yang-Mills Lagrangian (2.26) and the hidden symmetry Lagrangian (2.21). Here we confine ourselves to the simple case where the photon is the only external gauge field, which amounts to setting (3.1) where gP = - i&@;7’ with & the relevant charge operator and g;“’ the photon field. The effective action (2.26) in the massive Yang-Mills scheme is expanded in powers of the pion field n(x), by taking care of the Al-x mixing (2.60a). Then, we find
NAMBU-JONA-LASINIO
303
MODEL
where (3.3) (3.4) (3.5) 1 1 Yt.,, = 2 tr VII[7c, P7c] - 7 7 tr(a,, V,. - C!,,V,)[?%
a f,s;,
Y
?7r],
(3.6)
tr(8, V, - 8, V,,)[A’p, 8x1 +2i--
1 1
afd2,.
tr(a,A:
- a,AI)[
V’, c?‘x] (3.7)
- 2i
(3.8) T,, = 9k,,(L3,) .Pyv = 2a e f
- a e2f ‘, tr a:,
(3.9 1
', tr BP VP.
(3.10)
On the other hand, in the hidden symmetry scheme, we have P)
= g + Pv + T& + Pv,, + Pb..4n +~~++~v+~~nn+~~.4n+~;~C.nn+
“.,
(3.11 )
where (3.12) (3.13) (3.14) a-1’
PL,,, = a tr Fp[n, P7c] -
7
(
1 -tr(a~,a,-a,,~~)[a~~,avn],
> f", g:..
(3.15)
304
M. WAKAMATSU
2Fva, = -2i -u-l
7 1 tr(ap 8, - 8, FJ[A”‘“, Prc] a fngv u-l 1 -2i -tr(a,J: - a,J;)[ VP:“,Prc], a fd;?y (3.17) (3.18) (3.19) (3.20)
(3.21) Note that, in both schemes, the vector and axial-vector meson masses are given as M2, = afig; and Mf4 = (a2/(a - l))ffgc. At first sight, the two forms of effective Lagrangians, i.e., Eqs. (3.2 j(3.10) and Eqs. (3.11)-(3.21), look quite different. (Note in particular the difference between the VW coupling strengths in the two schemes in the general case of a # 2. This turns out to play an important role in the following study.) Only with the special choice a = 2, many corresponding terms of the two schemes coincide with each other. But, even in this case, we do not have complete correspondence between the two schemes. Some couplings existing in one scheme are simply missing in the other. (One example is the nrcVV coupling in the massive Yang-Mills scheme.) Nevertheless, we will show below by several examples that both schemes give identical predictions independently of the value of a as far as the on-mass-shell (or physical) vertices in the low energy domain are concerned. The first example concerns the coupling between the external photon and the Goldstone pion in the soft momentum limit. In the massive Yang-Mills Lagrangian, there is no direct photon-pion coupling. The photon couples to the pion only through the vector meson. Assuming the low energy (zero-momentum) approximation for the vector meson propagator [2629], i.e., dab Gzi(vector) N i g”” MZ,
(3.22)
V
where M$ = af ‘, gt, coupling becomes
the effective yrcrt vertex through r,,, = 2etr .C@Jrc,Prc].
the vector meson mediated (3.23)
Here we have used the VT-UCcoupling given by Eq. (3.6). On the other hand, in the hidden symmetry scheme, the direct photon-pion coupling vanishes only when a = 2. (In other words, the vector meson dominance holds only for this special
NAMBU-JONA-LASINIO
MODEL
305
value of a [ 131.) In the general case of a # 2, the effective y?rrcvertex in this scheme is (3.24) Here the first and second terms (in the brackets) are the contributions from the direct “~nz coupling and that from the vector meson mediated coupling, respectively. Note that the answers of both schemes are the same irrespective of the value of a. (This is a trivial example, since the electromagnetic charge of hadrons should receive no renormalization in any realistic model of strong interactions.) The second example is the 7~7~scattering amplitude in the low energy limit. The effective 47c vertex in the massive Yang-Mills scheme is (3.25) Here the first contribution comes from the second term of Eq. (3.12), while the second is the contribution of the vector meson exchange diagram resulting from the coupling L?&,,, . Here Eq. (3.22) is assumed again. (The contribution of the second term of LZV,, to the effective 4n vertex contains higher derivatives of the pion field compared with Eq. (3.25), and can be neglected in the soft pion limit.) The effective 4rr vertex in the hidden symmetry scheme is similarly evaluated as (3.26) In either case, the vector meson exchange contribution cancels a part of the direct 47~interaction one [53]. Note that this cancelation is independent of the parameter a and the final answers are the same in both schemes, i.e., I‘,,=F,,=+tr[7r,d,,n]’ . It
(3.27)
which precisely reproduces the low energy theorem prediction. Instead of carrying out exhaustive study, we shall be satisfied by giving one more interesting example. This concerns the 7c*--71’ mass difference in our effective meson theories [ 543. Since we are treating ideal chiral symmetric limit, this mass difference is of purely electromagnetic origin. (In the following, we consider the SU(2), x SU(2), flavor symmetry, by setting n = 2 and neglecting U( 1) symmetry.) In the massive Yang-Mills scheme, three Feynman diagrams illustrated in Fig. 1 contribute to this mass difference. An elementary calculation shows that
M. WAKAMATSU
306
(A)
(B)
ICI
FIG. 1. The Feynman diagrams that contribute Yang-Mills scheme.
to the n’-no
where PA, RB, and S$ are respectively diagrams (A), (B), and (C), given by
the contributions
3
SB = e2M~M~,
A
[ q2(q2-M:y+M;q2
SEC= e2M~M~,(M~,
- Adi)
from the Feynman
1 ’
[
3
I
q2(q2-M:,)(q2-M~)2-M391M~q2
Here ,J is the gauge parameter of the photon propagator P’(photon)=
mass difference in the massive
4
1 .
(3.31)
given by
1
-$+(2-l)?. g”y
In the above derivation, we have neglected the small photon mass of the order of e2, since it only gives corrections of order e4 to 6Mi. (Note that we are working in an unphysical basis in which the direct y-V coupling still remains. We can perform this calculation alternatively in the physical basis, in which this coupling is eliminated and the photon is exactly massless.) On the other hand, the Feynman diagrams that contribute to the z*-z” mass difference in the hidden symmetry scheme are illustrated in Fig. 2. A similar calculation shows that
(a)
(b)
(c)
td)
(e)
FIG. 2. The Feynman diagrams that contribute to the n’-x0 mass difference in the hidden symmetry scheme.
NAMBU-JONA-LASINIO
(6Mf),,=
-ig$
MODEL
{Fa+F4+~.+FJ+.3J,
307 (3.33)
where 2
i.
(3.34
e2_;, 4-
(3.35 (3.36) (3.37) (3.38)
As was expected, the answers of both schemes are again the same, i.e., Fd + FB + .F(. = F. + 4 + E + .Fd + 9;, = 3e’
M:,M; q2(q2-M:Jq2-M;)-
(3.39)
Note that the result is independent on the gauge parameter 2 of the photon propagator. This is natural since our Lagrangians have electomagnetic gauge invariance. Performing the momentum integration, we arrive at an elegant formula: (3.40)
which was first derived by Das, Guralnik, Mathur, Low, and Young [SS] by using the current algebra technique supplemented by the Weinberg spectral sum rule [56]. Assuming the Weinberg mass relation M,, = 4 M,, (and by using M,, = 770 MeV), this formula gives M,t - M,o =
@Mf,), 2 5.20 MeV, M,+ + M,o
(3.41)
which is surprisingly close to the experimental value 4.6 MeV [54]. Note that the answer so obtained is finite, even though we are evaluating l-loop diagrams. (This is true only in the exact chiral symmetric limit. It is known that, for finite pion mass, there appear logarithmically divergent corrections [57].) The cancellation of the high momentum contributions between the Feynman diagrams (B) and (C) or
308
M.WAKAMATSU
(d) and (e) are the cause of the above result. This illustrates an important role of the A, meson as a chiral partner of the p meson. From the phenomenological viewpoint, both forms of our effective Lagrangians with the explicit A, degrees of freedom have their obvious limitation. For example, it is known that a strong momentum dependence of the pnrc coupling comes from the redefinition (2.60) of the A, field, which modifies the successful KSFR relation and also makes the effective A I yrr vertex vanish in contrast with experiment [l-3]. To remedy this situation, Bando et al. proposed to add higher derivative terms in their effective Lagrangian entirely on phenomenological ground [SS]. Recall that the necessity of such higher order terms has been recognized for a long time in the massive Yang-Mills scheme [ 1,2]. Since the purpose of our present analysis is not to construct a phenomenologically complete model but to analyze the theoretical structures of the two widely-used effective meson Lagrangians, we do not go into the detail of this problem. We only comment that the predictions of the two schemes are identical also for the above problems, even though they are phenomenologically unsatisfactory.
4. PHYSICS OF THE ANOMALOUS
SECTOR
Now we turn to the discussion of the anomalous part of the effective action as derived from the NJL model. We start with the Wess-Zumino-Witten action in the massive Yang-Mills representation obtained in Section 2: r(a) E r
wzwcu; L, RI =r,,cu1+
{LCU; L, RI -r(Ju=
1; L, RI}, (4.1)
where I’,,[U]
= CjB5 tr(Ut diJ)5,
rcCG; L, RI = 5C S, ,i
ri[ U; L R],
l-1
with cc
N 240x2.
--i---.-L
(4.4)
The vertices Ti are given by rI = -tr URU+(LdL+dLL)-(L-R, r2 = -tr URUtL3
- (perm),
I-,= tr URUt(dUUt)2L
-(perm),
u.
Ut),
(4.5) (4.6) (4.7)
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309
MODEL
f4 = tr dUUt( LdL + dLL) - (perm),
(4.8)
f 5 = tr dUUt L3 - (perm),
(4.9)
r6 = -tr(dUUt)3L r, = tr URU’
- (perm),
LdUUt
(4.1 I)
L - (perm),
Ts = -tr lJRUtdUUtdL
(4.12)
- (perm),
Ts = - $tr RdUtURdUtU-
f,,,=
(4.10)
(4.13)
(perm),
(4.14)
$tr(LURU’)‘,
where U(s) = J?(““~. For practical consideration, we must expand the above action in powers of n(x). This can be done by using the following identities,
u~U+=B+~[~,8l-~[n,[n,B,l-~~n,In.[~,81]]+ ..., T: IT -. n
(4.15a) (4.15b)
and Udu+ = -;
*
dn +f
R
[n, dn] + $
U+dU=~d~+~In,d~]-~In, x x
T[
[n, [n, dn]] [r,dn]]+
n
+ ... .
,
(4.16a) (4.16b)
This gives, in the lowest powers of z(x), 5
tr(Ut dU)s - tr = $$ d[tr n(dn)4]. K
(4.17 I
Then, using Stoke’s theorem, we find fwz[
U] - 32Ciz
1
(4.18)
The second term of Eq. (4.1) is a complicated functional of the fields V, A, and n. Furthermore, the axial-field here is not still a physical one, because of the ,4-n mixing term contained in the non-anomalous part of the effective action. The physical field A’ is defined by Eq. (2.60a), i.e., A = A’ + i( l/a)( l/f,) dn. Fortunately, after a detailed inspection, it can be verified that the propagation of the axial-vector field
310
M. WAKAMATSU
does not contribute to the anomalous processes which we shall study below at the tree level. This allows us to set A’ = 0, or (4.19) which simplifies practical calculations considerably. It should be emphasized that our elimination procedure of the axial-vector field is different from the one of Scoccola et al. [ 381. They set A = 0 instead of A’ = 0, after proving that this elimination procedure is equivalent to the one of Schechter et al. with use of the Stiickelberg transformation [29, 341. We will come back to this point later. Introducing Eq. (4.19) into the second term of Eq. (4.1), we find r(~)=r,+r,+r,+r
(4.20)
ZT
where rwz
= 32C f. tr x(&)~,
(4.21)
f:
tr7r(drr)4,
(4.22) (4.23) (4.24)
T,=SCEtrdVdVrc.
fn
Here and hereafter, we omit the space-time integration symbol, for brevity. In order to obtain the anomalous effective action in the hidden symmetry scheme, we need not repeat tedious calculations. We have only to recall the argument given at the end of Section 2. (See Eqs. (2.56), (2.58), and (2.59), in particular.) The only one thing we must be careful about is that the definition of the physical axial-vector field is now given by Eq. (2.60b) in this scheme and therefore we should set
J= -i a-l --drc,
1
a fn
(4.25)
corresponding to Eq. (4.19). Then, after some algebra, the effective anomalous action in this scheme is found to be
F-@’ =F:wz + r;, + Fy+i-z,
(4.26)
NAMBU-JONA-LASINIO
311
MODEL
where
(4.29 ) (4.30) We immediately note that if a = 2 the functional forms of the anomalous actions in both schemes are exactly the same. However, we will show below that the physical equivalence of the two schemes holds irrespective of the value of u. Now, let us investigate some physical implications of the anomalous actions (4.20) and (4.26). First, the op7c vertex is given by Tz or Fz in each scheme. The standard definition of the coupling constant g,,,, given as
tr dVdVn, l-z= ropn= -2(g,,,,/g~~)
(4.31 )
leads to the prediction 3d g cop*= -- 8rc2.fn’ which has good phenomenological support [2,3, 22-331. The prediction of the hidden symmetry scheme is just the same, since the functional forms of Tz and Fz are identical. The well-known rr” + 2y decay occurs through the vector meson mediated process (no + po + 27) illustrated in Fig. 3, because the coupling between the external photon field and the hadronic fields is contained only in the nonanomalous part of action. This is again a common feature of the two schemes in our treatment. An elementary calculation with use of the couplings (4.24) and
FIG.
3.
The Feynman
diagram
that contributes
to the no + 2y decay
in our model
312
M. WAKAMATSU
(3.10) together with the zero-momentum approximation propagator leads to the effective ~yy vertex: 3e2 Lr(~"+2Y)--y-
4T.Lfn
for the vector meson
tr dS9dS?n,
which precisely reproduces the low energy theorem. Next we shall analyze the y + 371 process. Since the y -+ 371 process takes place necessarily through the o meson in the present models, it is simpler to treat the w -+ 371 process in the soft-pion limit (q, = 0). In the massive Yang-Mills action, both of f y and Tz contribute to this amplitude. We recall that the second and third terms of ry, which depend on the parameter a, comes from the A i-71 mixing effect. To stress the role of the axial-vector meson, we show in Fig. 4a the corresponding Feynman diagrams. Here, the second and third diagrams do not mean propagation of the physical A, meson but they are to be understood to give graphic representations of the A,-n mixing effects. On the other hand, the action r, contributes to the above process through the vector meson mediated diagram illustrated in Fig. 4b. The resultant effective vertex is (3/a) tr V(drc)3. Then, adding up the two contributions, we have in the massive Yang-Mills approach: I-,,(0 + 37c)- &{(l-i+$)+i}tr We can similarly
V(dn)3.
obtain the effective vertex in the hidden symmetry scheme as
Fe&3 + 371)~--&{(1-3($)+~(~)2)+~{tr
v(dn)3.
(4.35)
Here the .first and second terms result from p, and iiZ, respectively. We find that, despite the difference of the individual contribution, the final predictions of the two schemes are identical independently of a, (4.36)
FIG.
4.
The Feynman
diagrams
that contribute
to the process
w --t 371.
NAMBU-JONA-LASINIO
MODEL
313
Unfortunately, this result breaks the low energy theorem in the order of l/a’. (Note that this term originates from the A 1-n mixing effect of second order; the third diagram of Fig. 4a.) The low energy theorem insists that the coefficient of tr P’(&c)~ or tr 8(~&)~ in the brackets of Eq. (4.36) must be 1. Nonetheless, the cancellation among the terms of order l/a is a noteworthy feature. In the massive Yang-Mills scheme, such terms come from the vector meson mediated diagram (Fig. 4b) and the A ,-n mixing effect of the first order (the second diagram of Fig. 4a). Both terms just cancel. In this sense, the A,-7~ mixing effect plays an important role. There obviously exists a mechanism which suppresses additional contributions from vector mesons in this scheme [2, 27, 291. Had we neglected the A,-n mixing and simply set A = 0 in the Wess-Zumino-Witten action, we would have (4.37)
which breaks the low energy theorem even worse than before. (Here, the first and second terms are the contributions from the direct o -+ 3n coupling and the vector meson mediated process, respectively.) According to Scoccola et al. [38], the above elimination procedure (i.e., setting A = 0) is equivalent to the one of Schechter et al. with use of the Stiickelberg transformation [29, 341, which amounts to setting R = <+( p+ d) i”.
(4.38a) L = 5( P+ d) i”‘.
(4.38b)
in the effective action in the massive Yang-Mills basis. Here v is to be interpreted as the physical vector meson field. (More precisely, the equivalence proof by Scoccola et al. relies upon the fact that the Wess-Zumino-Witten action is chiral gauge invariant in the absence of the axial-vector degrees of freedom, and cannot be applied without special care to the non-anomalous part of the action which is not generally chiral gauge invariant.) Thus, our analysis above indicates that the Stiickelberg elimination of the axial-vector meson results in losing an important cancellation mechanism between the contributions of the vector and axial-vector mesons to the anomalous process y + 37r. Accordingly, the discrepancy of the massive Yang-Mills scheme is exaggerated too much. This throws a little doubt upon this elimination procedure of the axial-vector field. We recall that it was criticized also by Yamawaki [18]. This elimination method amounts to dropping one physical degrees of freedom (the A, meson) by hand, but the problem is that this brings about some inconsistency with its equation of motion. We comment that our (standard) elimination procedure of the axial-vector meson is nothing inconsistent with the equation of motion. We should point out that our prediction (4.34) for the w -+ 37r amplitude is nothing new. It was already given by Kaymakcalan et al. in their massive Yang-Mills
314
M. WAKAMATSU
treatment of the problem [27]. (See also Ref. [2, 343.) This is easily understood, because we already know that the effective action resulting from the NJL model is formally identical to theirs (but for the non-minimal terms in the non-anomalous part of their Lagrangian). What is new in our results is that the hidden symmetry scheme, if treated mutually consistently with the massive Yang-Mills scheme, gives the same answer. The feature described above can be demonstrated even more clearly in our next example, the anomalous process K+K- -+ 3~. In the following, n(x) should be understood to represent generically the Goldstone fields belonging to the octet representation of flavor SU(3). The effective 5Goldstone vertex in the massive Yang-Mills scheme turns out to be I’,,(K+
K- + 3~) ‘v
(4.39) Here the first and the second terms are the contributions of the contact diagram in Fig. 5a. (The first comes from the Wess-Zumino term, and the second from r, in Eq. (16b), which is entirely due to the A,--71 mixing effect.) The third and fourth terms are the contributions of the vector meson mediated diagrams illustrated in Figs. 5b and c. Adding up all the contributions, we eventually find f,,(K+K-
--t 371) N {l+5(&&i)]bz.
The low energy theorem requires that the answer should be Twz C59-613. We again see that it is violated in our model. This breaking however happens only in the higher orders of l/u. In particular, the terms of order l/a and l/a2 exactly cancel among themselves. This again shows the important role of the axial-vector field, which appears through the A i-71 mixing. Simply setting A = 0 (or equivalently using ‘\
(a) I’
‘\ ,’ ,y;--I ‘\
,’ \
(d FIG.
5.
The Feynman
diagrams
that contribute
to the process
K+K-
+ 3x.
NAMBU-JONA-LASINIO
MODEL
the Stiickelberg elimination) in the gauged Wess-Zumino-Witten justified. Had we done so, we would have found
315
action is not
(4.41) Setting a = 2, this precisely reproduces the result of Scoccola et al. [37], which leads to an intolerably large violation of the low energy theorem. Unfortunately, the parameter a dependent correction in Eq. (4.40) is far from small for a ‘v 2. A direct experimental check of the low energy theorem is highly desirable. For the sake of completeness, we have analyzed the same amplitude based on the effective action in the hidden symmetry basis. The answer is as follows:
Here the first and second terms come from the contact diagram, and the third and fourth ones from the vector meson mediated diagrams. If we add up all terms, we find after a series of cancellations: R,,(K+K--
+3n)
-{1+5(&$)}r,,,.
(4.43)
which precisely coincides with the answer (4.40) of the massive Yang-Mills scheme. From the analysis so far, we have therefore convinced ourselves that the two schemes, i.e., the massive Yang-Mills and hidden symmetry schemes, are physically equivalent as long as they are treated with mutual consistency. This conclusion may be self-evident, from the viewpoint that these effective Lagrangians are two different but equivalent bosonic representations of a single fermion theory, i.e., the NJL model. Alternatively, the above equivalence may be thought of as a special example of the well-known theorem due to Kamefuchi-O’Raifeartaigh-Salam [63] (See also Ref. 64).), which claims that the on-shell S-matrix is invariant under the change of field variables. (Strictly speaking, their exact proof was given only for point transformations, i.e., transformations which do not involve time derivatives of the fields. On the other hand, the transformation (2.13) relating the field variables of the two schemes generally includes time derivatives. However, they also suggested that their theorem may be generalized to include such cases as well.) To be more rigorous, our demonstration on the equivalence of the two schemes is far from complete. The explicit examples given here are concerned with the processes which contain the Goldstone bosons and the photon as external particles. (The only exception is the statement given at the end of Section 3 that the on-massshell prcn vertices are exactly the same in both schemes.) They are those amplitudes
316
M. WAKAMATSU
which are determined by the symmetry structure of the Lagrangians and might not be sensitive to the different dynamical structure possible for the heavy states, i.e., the p and A, mesons. Although we believe that the equivalence still holds for such processes as containing the heavy mesons at least after properly incorporating the quantum loop effects, the direct check of it might not be straightforward. This is because we are treating effective Lagrangians which are not renormalizable in the usual sense, and therefore we have no convincing method of handling divergences which appear in the evaluations of loop diagrams. (This should be contrasted with the processes studied in this paper. For these processes, the equivalence holds at the tree level.) Despite this insufficiency, it is hoped that the present analysis has achieved a partial success in clarifying several questions concerning the conceptual relation between the two popular approaches to low energy effective models for mesons.
5. THE ANOMALOUS SYMMETRY BREAKING AND CURRENT NON-CONSERVATION In the previous sections, we have advocated the viewpoint that the massive Yang-Mills and (extended) hidden symmetry schemes are two different but equivalent bosonic representations of a single quark theory. That parameter a is independent of this equivalence is a noteworthy feature of the present analysis. To avoid confusion, however, we should emphasize that the extended hidden symmetry Lagrangian obtained here from the generalized NJL model is different from the corresponding model Lagrangian of Fujiwara et al. [33], which contains no A, degrees of freedom. (Remember that it is the Lagrangian adopted by Scoccola et al. in their comparative analysis of the two schemes [38].) It is known that this model satisfies all the low energy theorems [33]. This is certainly related to the fact that it does not contain the explicit AI degrees of freedom. The more essential reason is however an assumption made in their construction of the anomalous action. As was mentioned in Section 1, it was a priori assumed that the anomaly sits in the part of the effective action that includes the Goldstone field and the external gauge fields alone, and that the other part containing the hadronic vector field is anomaly free. This latter part can be fixed only through phenomenology. We have no objection against such an approach, since it is consistent with the general belief that the only dynamical anomaly in QCD is the U( 1 )A axial current anomaly. What is not clear to us however is a microscopic (quark-level) basis of such an ad hoc model construction. This should be contrasted with our treatment, in which the anomalous action is essentially uniquely determined (up to the regularization scheme arbitrariness), once we start with the definite fermion Lagrangian, i.e., the NJL model. However, the violation of the low energy theorems for some anomalous processes is an unpleasant feature of our model. The reason why our model breaks some of the low energy theorems is basically a known subject from the previous studies [27-29, 33, 343. We have only to remember the fact that one of our effective Lagrangians derived from the
NAMBU-JONA-LASINIO
317
MODEL
generalized NJL model formally coincides with the massive Yang-Mills model generalized by Kaymakcalan et al. so as to include the anomalous part [27-291. Nonetheless, we think it instructive to perform a reanalysis of the problem on the basis of the NJL model. This is because for this special model we have translation rules (although of approximate nature) between the quark language and the collective meson language. This enables us to clarify the general structure of the hadronic currents in a transparent fashion. For example, we can get an interesting insight into the origin of the current-field identities a la Sakurai [ 121. We can also answer the question whether the presence of anomalies is really inconsistent with the equations of motion for the “massive” vector and axial-vector fields [27]. Let us start with the expression (2.6) of the generating functional. (In consideration of the equivalence of the two schemes, only the effective action in the massive Yang-Mills represenation will be discussed below.) After neglecting the quantum fluctuation of the scalar field, it reduces to
II (5.1)
. ~[iy”(a,
+ R, P, + L, PL) - m( UPR + U+ P,)]
= exp
q
(5.2)
The basic currents are defined in terms of the right and left variations of the action T, = -i log Z/: (53a) (53b) From Eqs. (5.1), (5.2), and (2.19), we have (5.4)
318
M. WAKAMATSU
which is also expressed in the following form:
where r strong= r,-
2
tr[Ri
+ L:],
(5.6)
V
is the strong interaction
part of the action and (5.7a) (5.7b)
are the hadronic currents which couple to the external gauge fields. We see that the currents .I;” and Jk are exactly proportional to the hadronic fields R, and L,. This is just the current-field identities a la Sakurai [12]. Undoubtedly, it is a consequence of the specific nature of the NJL model, i.e., the four-fermion form of interactions together with the field redefinition (2.5) Now, the anomalous conservation equations for the currents (5.3) can be obtained by investigating the change of an action under the following V(n), x U(n), gauge variation: R, + g.0,
+ a,) st,,
(5.8a)
L, + gdL,
+ a,) gt,
(5.8b) (5.8~)
u+gJJ& First consider the infinitesimal
right variation, g,=@4
i.e., +ieR.
(5.9)
The changes of the fields R,, L,, and U under this variation
6,R, = 4a,,& &Lp=O,
(5.10a)
+ CR,, e,l)
(S.lOb) (5.1Oc)
6, u = -iUO,.
The change of an action r under the right variation
are given as
is then
(5.11)
NAMBU-JONA-LASINIO
319
MODEL
where we have performed a partial integration derivative D,(R) operating on a matrix M by D,(R)M=a,M+
and introduced
the covariant (5.12)
[R,, M].
The standard argument goes as follows [47, 51, 651. By setting r=f,-(Eq. (5.2)), and imposing the equation of motion for the Goldstone field Sr/SU = 6r,/6U = 0. we obtain S,r,-=
i =
I
d4x tr 8, D,,(R) 2 I’
d4x tr !3,Dp(R)j,t.
s
(5.13)
Here use has been made of the definition (5.3a) of the current j:. hand, the gauge variation of r’ by definition gives the anomaly: S,r,=
On the other
(5.14)
1 d4.x fr tl,G,.
After a similar consideration about the left variation, we are thus led to the following anomalous conservation laws for the currents jf and ji : D@(R)j,R = G,,
(5.15)
D”(L)j,L
(5.16)
= G,.
The explicit form of the anomaly depends on the regularization scheme. If we adopt the vector gauge invariant scheme as in the present analysis, the anomaly is the so-called Bardeen form [47-5 1,651: G,=
-G,=G,(R,,
L,,).
(5.17)
Now we come to the following question: what is the relation between the above “covariant” conservation (or non-conservation) laws for the currents j,” and jb and the “ordinary” conservation (or non-conservation) laws for the symmetry currents dictated by the presence of global (or rigid) symmetries? This can be seen as follows. The equations of motion for the hadronic fields result from the stationary requirement of rstrong under arbitrary variations of R,, L,, and U. On the other hand, the gauge variation (5.19) is a special case of such arbitrary variations. Then. it follows that ’ R rstron,
=
6 L rstrong
=
O.
(5.18)
This, combined with Eq. (5.6) as well as Eqs. (5.3), leads to the following equations:
320
M. WAKAMATSU
DG(R)(j:-gR,)=O,
(519a)
D@(L) (ji-zL,.)=O. Then, using the identities P(R) R, = PR, and P(L) L, = PL,, as well as the definition (5.7), we now see that the covariant conservation Eqs. (5.15) and (5.16) for the currents j,” and j,” are equivalent to the following ordinary conservation equations for the currents J;1” and Jt : dpJRP = G R? PJL P = G L’ Especially, in the vector gauge invariant
(5.20a) (5.20b)
scheme, Eqs. (5.20) reduce to
apJ;=o,
(5.21a)
PJ; = G,( VP,A,),
(5.21b)
where JL = $(J,” + J,“) and J;1” = i(J,” -J,“). Remember that these are the currents which couple to the external gauge fields. Equations (5.21) are completely consistent with the symmetry breaking pattern of the present model such that (We recall that the Bardeen subCub),’ U(n)Rl,l,,,, + CUtn)Vx u(1),41,,,,,,. tracted term in our effective action explicitly breaks the global axial symmetry [27-291.) The conservation of the vector current JF which couples to the external photon field ensures the electromagnetic gauge invariance. The explicit breaking of the global chiral symmetry however leads to the non-conservation of the axialvector current even in the massless pion limit. As is evident from the above derivation, there is no inconsistency between the presence .of anomalies and the equations of motions for the “massive” vector and axial-vector fields. This again shows that the massive Yang-Mills theory should not be confused with true gauge theories [27]. For true gauge theories, the presence of anomaly in the source current of the gauge field cannot be consistent with the equation of motion, that is, the two equations D”j, = G and DpF,,v =j, cannot hold simultaneously unless G = 0. It might be also interesting to see what happens if we adopt the left-right symmetric regularization scheme, although we do not think that this regularization scheme is consistent with the derivative expansion with large constituent quark masses adopted in this paper for obtaining the non-anomalous part of the effective action [66]. It is well known that the anomalies in this scheme can be expressed as total derivatives of a certain functional in the following manner: GR = G(R,) = a”A,(R,),
(5.22a)
G, = -G(L,)
(5.22b)
= -PA,(L,).
NAMBU-JONA-LASINIO
MODEL
321
This means that, if we introduce the new currents by J,” E J:” - A,( R,,),
(525a)
3; = Jk + d,(L,,),
(5.23b
then they are conserved:
aflJRP = 0 ’ aq = 0.
(5.24a (5.24b
The presence of conserved currents was naturally expected from the fact that this regularization scheme preserves the global chiral symmetry. These symmetry currents however differ from the currents J,” and .I: which couple to the external gauge fields. Because of this fact, the electromagnetic gauge invariance is lost in this regularization scheme. This is undoubtedly the reason why the left-right symmetric form of the Wess-Zumino-Witten action supplemented by the vector meson dominance assumption leads to incorrect prediction for the decay amplitude
n"+2y [27]. One interesting feature of this regularization scheme is that it reproduces the low energy theorems for the amplitude K+K- -+ 37~. That is, adopting the gauged Wess-Zumino-Witten action in the left-right symmetric form, we obtain
f&K+K--
--+3x)-
= rwz,
(5.25)
instead of Eqs. (4.39) and (4.40). Thus, despite the presence of the anomalies, the low energy theorem for this purely hadronic process is intact in this scheme. This suggests the importance of respecting the global chiral symmetry in the construction of models of strong interactions. (It should be recalled however that this scheme considerably underestimates the hadronic o + 3n decay rate [27], though this is not such a process as given any constraint by low energy theorems.) Summarizing the arguments, the generalized NJL model with its axial-vector four-fermion coupling necessarily leads to a dynamical anomaly, which is not predicted by QCD [33, 34, 381. The presence of anomaly means that it is impossible to regularize the theory so as to preserve all the classical symmetries of the original Lagrangian. Adopting the vector gauge invariant regularization scheme, the electromagnetic gauge invariance is preserved but the global chiral symmetry is broken at the strong interaction level. The violation of the low energy theorems for the processes y + 3n and Kf K- + 37r seems to be related to this “explicit” (not “spontaneous”) breaking of the global chiral symmetry. On the
322
M.WAKAMATSU
other hand, adopting the left-right symmetric regularization scheme, the global chiral symmetry is preserved, but the current which couples to the external electromagnetic field is not conserved any more. It seems that we cannot escape from the above difficulties as far as we start from the generalized NJL model with its axial-vector four-fermion coupling. Then the problem again reduces to the relevance of the A, degrees of freedom in low energy effective meson theories. This is an old but still poorly understood problem [l-3]. We have already seen that the inclusion of the explicit A, degrees of freedom causes some troubles also for the non-anomalous part of the action. The problem of the strong momentum dependence of the prm coupling coming from the ,4,-n mixing effect is a typical example. (From a purely phenomenological viewpoint, this difficulty is circumvented by adding higher derivative effective action by hand.) However, we have also seen that the A, meson plays desirable roles as a chiral partner of the p meson. This happens for instance in our effective Lagrangian approach to the problem of the rr*-?I’ mass difference. The partial cancellation, between the contributions of the p meson mediated diagrams and the A,-rr mixing effects, which was observed in some anomalous processes is also a noteworthy example. It is a difficult problem to understand the reason why the A, degrees of freedom, which in some instances play preferable roles as expected from its nature as a chiral partner of the p meson, must do harm in other occasions.
6. CONCLUDING
REMARKS
Through several explicit examples, we have demonstrated that the massive Yang-Mills Lagrangians and the extended hidden symmetry Lagrangians can be thought of as two different but equivalent bosonic representations of a single quark theory, i.e. the generalized Nambu-Jona-Lasinio model. On the other hand, from the comparative analysis of the anomalous process K+K- + 3n, using both the massive Yang-Mills and hidden symmetry schemes, Scoccola et al. [3g] concluded that the massive Yang-Mills scheme is not consistent with QCD anomalies, and only the hidden symmetry scheme is acceptable as a consistent framework. The conclusions of these two researches are however not contradictory. The hidden symmetry model adopted by Scoccola et al. [38] is that of Fujiwara et al. [33], who constructed the anomalous action on the basis of the original hidden symmetry model of Bando et al. [13]. This model contains no A, degrees of freedom and is clearly different from the extended hidden symmetry model derived here from the generalized NJL model. The reason why Scoccola et al. obtained different answers in the two schemes is now quite obvious. It is simply because they are handling two different models in two different representations. It would be certainly true that among the above models only the hidden symmetry model of Fujiwara et al. is consistent with the dynamical anomaly structure of QCD. As can be learned from the work of Jain et al. [34], however, a consistent model can be constructed also in the massive Yang-Mills representation. Clearly, it is not a
NAMBU-JONA-LASINIO
MODEL
323
problem of scheme (or representation) but rather how to treat the dynamical anomaly. We believe that our demonstration here gives another support on such a viewpoint, i.e., the representation independence of effective meson theories, despite the fact that our model in either representation has its intrinsic problem in order for it to be regarded as a consistent effective theory of QCD. Probably, one of the greatest advantages of the original version of the hidden symmetry approach [ 131 (or the non-linear realization of the chiral symmetry with the vector meson [46]) is its natural possibility of introducing the p meson without including the A, meson. However, as seen from the present analysis. the microscopic (quark-level) foundation of such a construction appears highly nontrivial. Specializing to the NJL model with its four-fermion couplings, the introduction of the vector and axial-vector couplings is an inseparable operation, because of the requirement of the global chiral symmetry. Also from more general viewpoint of QCD, there seems to be no essential difference (at least conceptually) between the vector and axial-vector mesons as composite particles of a quark and an antiquark. Nonetheless, this primitive candidate (the generalized NJL model) for an effective low energy theory of QCD seems to contain an inconsistency due to the presence of dynamical chiral anomaly which is not owned by QCD Lagrangian itself. Can this deficiency be cured by the introduction of some other hadronic degrees of freedom to this simplest model so as to cancel the anomaly? Or, does it make little sense at all to consider the collective vector and axial-vector mesons which couple to quark loops? It is hoped that future studies will solve these questions on the basis of the underlying quark-gluon dynamics.
ACKNOWLEDGMENTS The author express his gratitude to W. Weise for critical reading of the manuscript and for encouraging discussions. He also thanks N. Kaiser, M. Schaden, H. Forkel, and A. Hosaka for many helpful discussions. Stimulating discussions with U.-G. MeiDner and N. N. Scoccola are greatly acknowledged.
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59s. 193.2-6
OF PHYSICS
193, 287-325
(1989)
The Nambu-Jona-Lasinio Model and the Chiral Anomaly* M. WAKAMATSU~ Instiiute of Theoretical D-8400 Regensburg, Received
Physics. Federal September
University Republic
of Regenshurg,
qf German?
21, 1988
An approximate bosonization of the Nambu-Jona-Lasinio model is shown to lead to either form of two low energy effective Lagrangians: i.e., the massive Yang-Mills form or the hidden local symmetry form of Bando et al. The specific underlying quark Lagrangian restricts the freedom in obtaining the anomalous effective action on one and the other scheme. This enables us to show the equivalence of the two schemes not only for the physics of the nonanomalous sector but also for the physics of the anomalous sector. Our model in either representation however breaks low energy theorems for some of the anomalous processes. In pursuit of its origin, we investigate the general structure of the hadronic currents in the present model, putting special emphasis upon the underlying Lagrangian at the quark level. As an interesting byproduct of the present analysis. we gain a new insight into the dynamical meaning of the parameter a, which appears as a free parameter in the hidden symmetry model of Bando et al. I(” 1989 Academic Press, Inc.
1. INTRODUCTION Growing attention has recently been paid to the low energy effective Lagrangians of QCD which incorporate vector (and axial-vector) mesons in addition to the Goldstone pion field [l-3]. This renewal of interest in the low energy effective Lagrangians owes greatly to the conjecture that, at low energy and in the limit of large number of colors IV,, QCD reduces to a nonlinear effective theory of weakly interacting mesons [4,5]. Since baryons emerge as topological solitons in such a theory, their properties are intimately connected with the physical parameters of the meson sector [6-91. There are two popular ways of introducing vector (and axial-vector) mesons into the original chiral Larangian, i.e., the non-linear sigma model. The first one is the so-called massive Yang-Mills approach [ 10-121. The guiding principles are chiral symmetry and non-abelian gauge symmetry: the latter is “minimally” broken due to mass terms inserted by hand. The second approach, which has recently received increasing attention is the hidden local symmetry approach due to Bando er al. * Work supported in part by BMFT, Grant MEP 0234 REA. ’ Permanent address: Department of Physics, Osaka University,
Japan.
287 0003-4916189
$7.50
Copyright :K-’ 1989 by Academtc Press. Inc All rghts of reproduclmn in any form reserved
288
M. WAKAMATSU
[13, 143. They suggested that the vector mesons p, o, K*, and 4 are dynamical gauge bosons associated with the hidden [U(3),,],,,,, symmetry in the U(3), x U(3),/U(3), nonlinear chiral Lagrangian. Under the assumption that the composite gauge boson acquires a kinetic term, they obtained an effective Lagrangian compatible with the vector meson phenomenology which is manifest, e.g., in the KSFR relation [15, 163, the universality of the p couplings, the p-dominance of the pion electromagnetic form factor etc. [12]. In consideration of the phenomenological success of both approaches, we naturally come to the following question. Is there any fundamental relationship between these two apparently different schemes? An answer to this question was recently given by Meigner and Zahed [ 171 and also by Yamawaki [IS] at a formal level; it was given by us at a dynamical level in a recent paper [19] (hereafter referred to as (I)). To be explicit, it has been revealed through several recent studies [19-221 that either form of two low energy effective meson Lagrangians, i.e., the massive Yang-Mills one or the hidden symmetry one of Bando et al. [13, 143, can be derived from a single quark theory, i.e., the generalized Nambu-Jona-Lasinio (NJL) model, as a result of an approximate bosonization procedure [20,21]. A crucial observation there was that the field variables corresponding to the vector meson (and also the axial-vector meson) in both schemes are related to each other through a chiral transformation which depends on the Goldstone pion field. (It is sometimes called the Stiickelberg transformation in the literature [17, 181.) Although the forms of these two effective Lagrangians are quite different, it was claimed that the predictions of the two schemes are identical as far as the mass relations and the (non-anomalous) on-mass-shell vertices are concerned [3]. Then, a natural question is whether or not the above equivalence between the two schemes can be extended to the physics of the anomalous sector that concerns intrinsicparity violating processes. The physics of the chiral anomaly, especially in the presence of the hadronic vector and axial-vector fields, is rather involved, and there still remain some open questions [23-341. A standard prescription adopted in the massive Yang-Mills scheme [23-321 is to assume that the intrinsic parity violating processes originate in the gauged Wess-Zumino-Witten action [35, 361 (in the Bardeen subtracted form [37]) in which the gauge fields are identified with the phenomenological vector meson (and possibly the axial-vector meson too). The vertices involving the external gauge fields are assumed to be present in the non-anomalous part only, precisely in the form of a direct coupling between the vector meson and the external gauge fields [ 121. This immediately leads to the vector meson dominance of the intrinsic parity violating processes (as well as the intrinsic parity conserving ones). The above procedure is known to give a good phenomenological description but it is generally believed to have two unpleasant features [27, 29, 33, 343. First, in this theoretical framework, we are obliged to introduce the axial-vector meson as a gauge field simultaneously with the vector meson in order to preserve U(n) x U(n), symmetry. But the gauging of the anomalous axial-vector channel has a danger that the equations of motion may be mutually inconsistent, as was pointed out by
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289
Kaymakcalan, Rajeev, and Schechter [27--291. Second, the introduction of the axial-vector meson in this way forces us to choose Bardeen’s form of the anomaly because the left-right symmetric form no longer respects the vector current conservation. The Bardeen form of the anomaly, however, explicitly breaks the chiral U(n) x U(n), symmetry. Being aware of the above difficulties, Fujiwara et al. treated the anomaly problem in a different way in the hidden symmetry approach [33]. (See also Ref. 34).) The anomaly is assumed to sit in the part of the effective action that includes the Goldstone bosons and the external gauge fields alone, which is nothing but the gauged Wess-Zumino-Witten action in its original version. The vertices which contain the internal (or hadronic) vector meson are assumed to be included in the chiral gauge invariant (anomaly-free) but intrinsic parity violating part of the effective action, It should be emphasized that this part containing several arbitrary coefficients can be fixed only phenomenologically [33]. In a recent paper [38], Scoccola, Rho, and Min performed a comparative analysis of the anomalous process, K+ Kp -+ 3n, using both the massive Yang-Mills scheme (they call it the external gauging scheme) and the hidden symmetry scheme of Fujiwara et al. [33]. In the hidden symmetry scheme, the above 5-Goldstone vertex is saturated by the contribution of the Wess-Zumino action which depends on the Goldstone fields alone. Any other contributions from the vector meson mediated diagrams exactly cancel among themselves in the low energy limit [33]. On the other hand, in the massive Yang-Mills scheme (it is important to remember that for the purpose of comparison they had to eliminate the axial-vector field in this scheme in a particular way explained later), Scoccola et al. found that the prediction based on the Wess-Zumino term, which is known to reproduce the low energy theorem, receives an intolerably large modification due to the vector meson mediated processes. According to their analysis, there appears to be no natural way in the massive Yang-Mills scheme to suppress additional significant contributions from vector mesons. From this fact, they concluded that the massive YanggMills scheme is not consistent with QCD anomalies, and only the hidden symmetry scheme is acceptable as a consistent framework. In this paper, we wish to reexamine this conclusion. Our conclusion is in fact that neither of the schemes is superior to the other. It is not a problem of scheme (or representation) but rather how to treat the chiral anomaly. Let us now clarify this point in the rest of the paper. The paper is organized as follows. In Section 2, the two forms of effective Lagrangians, i.e., the massive Yang-Mills and hidden symmetry ones, are derived through an approximate bosonization of the generalized Nambu-Jona-Lasinio model. The description of this derivation is divided into three subsections. In the first subsection, we give a precise definition of the effective meson action based on the proper-time regularization scheme of the fermion path integral. Then, the nonanomalous and anomalous parts of the effective action are separately discussed in the following two subsections. Section 3 shows a comparative study of several non-
290
M. WAKAMATSU
anomalous processes using both the massive Yang-Mills and hidden symmetry schemes. The corresponding analysis of the anomalous processes are given in Section 4. In Section 5, we shall analyze the general structure of the hadronic currents in the present model, paying special attention to the underlying Lagrangian at the quark level. Concluding remarks are given in Section 6.
2. BOS~NIZATION 2.1. Definition
OF THE NAMBU-JONA-LASINIO
MODEL
of Effective Meson Actions
The starting point of our analysis is the following Lasinio (NJL) model [ 3942, 20, 211: .2-
YNJL = W‘ drq + 2G, 1
generalized Nambu-Jona-
1
((4T”q)’
+ (qiy’ T”q)2}
Cl=0
rl-
2G2
c 0=0
1 {GWT”d2
+
@“WW2}.
(2.1)
Here q are the quark fields, n is the number of the flavor degrees of freedom, and T, are generators of the flavor U(n) group normalized as tr(TaTb) = IS,,. (The color indices of quarks are not explicitly shown.) Throughout the present study, we shall neglect the bare quark masses, for simplicity. In this limit, the above Lagrangian has exact global U(n), x L(n), symmetry. Naturally, the NJL model cannot be a “true” substitute for the QCD Lagrangian, but there are several good reasons to assume that it might be a good low energy approximation to the QCD Lagrangian. It correctly describes the spontaneous chiral symmetry breaking of the QCD vacuum. Furthermore, owing to the approximate bosonization techniques we can develop a clear understanding about the relationship between the NJL model and some low energy effective meson Lagrangians, as far as the physics of the nonanomalous sector is concerned [19-22, 433. Then, we expect that it should provide useful information also for the physics in the anomalous sector. In our treatment, the introduction of the electroweak interaction is uniquely done at the quark level, by gauging an appropriate subgroup of the flavor [U(n), x U(n),],,,,,, group [ 19,201. (Here we may have in mind, for instance, application to the standard SU(2), x U( 1) y electroweak interaction model.) In general, one may try to gauge an arbitrary subgroup H of U(n), x U(n),, with generators K”, e = 1, .... r. Each K” is a linear combination of generators TF and T> of U(n), and U(n),, Ku= T”,+ Ts. (Either Tz or T: may vanish for some value of a.) Thus, the electroweak interaction is introduced through the following minimal replacement of the quark kinetic part of the Lagrangian
NAMBU-JONA-LASINIO
where PRiL = $ (1-I y’), gauge fields. After introducing the scalar), V,(vector), A, valued) [19-22, 40-433,
and gp = -i%‘;T”,
291
MODEL
and Yp = -iU;1,TO,
are the external
color singlet collective meson fields S (scalar), P (pseudo(axial-vector) in the standard way (they are all matrixthe gauged NJL Lagrangian can be cast into the form:
-&trCS2+ 1
P21 -&
2
tr[Rt+
(2.3)
LfL] + YC,,.
Here and hereafter we interchangeably use the vector and axial-vector notation (V,, A,) and the right- and left-handed notation (R, = V,, + A,,, L,, = V,, - A,,). Let us furthermore introduce the change of the field variables as S+iP=
(2.4)
in terms of a hermitian matrix C and a unitary matrix 5 [19-221. The latter is parametrized as t(x) = einCx)uain terms of the Goldstone pion field n(~). (A more general parametrization S + iP =
-&tr[(R,-~~)2+(L,,-~~)2]-~tr~2+~,, 2
I
11 ,
(2.6)
292
M. WAKAMATSU
where @(g, L’) is the integration measure for the transformed fermionic part of the generating functional is given by
fields (2.4) and the
Z~~,~,R,,L,)=SYq~rlexp
(2.7)
where N, is the number of colors of quarks and iD = z’y”(a, + R,P,
+ LpPJ
- (&tP,
+ <+Zt+PL).
It is now convenient to perform a chiral (or Weinberg) as
Corresponding
rotation
(2.8 1
of the quark fields
XR(X)= 5(x) cl&)?
(2.9a)
XL(X) = 5’(x) 4Ax).
(2.9b)
to this chiral rotation, @m
the fermion integral measure changes as = (J(~))Nc~x~~,
(2.10)
where (J(<))Nc is the Jacobian of the transformation (2.9) [20, 21, 44, 453. (The functional dependence of J on R, and L, is not explicitly shown, for notational brevity.) Performing the fermion integration, we then have Z,j& Z, R,, L,) = (J(S))Nc(det iDS)Nc,
(2.11)
where (2.12)
iDc=iy”(a,+ji,P,+z,P,)-C.
Here the chirally rotated vector and axial-vector defined by E, = W,
(right- and left-handed) fields are
+ a,) 5+,
2, = <+(L, + a,) r.
An important
relation
(2.13a) (2.13b)
obtained from Eqs. (2.7) and (2.11) is (det iD)Nc= (J(S)fNc(det iDr)Nc.
(2.14)
The apparently closed expression (2.7) or (2.11) for the fermion part of the generating functional is only formal. It contains divergences which must be removed by some regularization procedure. We adopt here the proper-time regularization scheme, which is known to automatically preserve vector gauge invariance [ 19-221. It is well known that the presence of a yVys coupling makes the Dirac operator iD in Eq. (2.8) (an analytic continuation to the euclidean action is implicit in the argument below) non-antihermitian and log det iD acquires an imaginary part which is
NAMBU-JONA-LASINIO
MODEL
293
not invariant under a chiral transformation [20, 211. To be explicit, the precise definition of log det iD in the proper-time regularization scheme is given as follows [20,21]: log(det iD)Nc = N,. log jdet iD[ + id,
(2.15)
N,. log ldet iDI = 9 Tr’ log DtD = $ s,‘,, 4 Tr’ em rotn,
(2.16a)
where
and d = N,.Im(log
det iD) = - 2 Im [,I,: $ Tr’ e -T(zD)2.
(2.16b)
Here ,I is the intrinsic cutoff of the present theory, Tr = j d4 x tr and a prime indicates that a trace over Dirac indices is included. As is well-known [20, 211. the real part of log(det iD)“‘< contributes to the non-anomalous part of the effective action, while the imaginary part of it gives the anomalous effective action. These two parts of effective action are evaluated in the following two subsections. 2.2. The Non-Anomalous Effective Action As was pointed out by several authors [20,21], minant is chiral gauge invariant, i.e., I det iDI = (det iDi I.
the modulus of the quark deter(2.17)
This quantity, which is related to the non-anomalous part of the effective action, can be straightforwardly evaluated by using the heat-kernel expansion, which is essentially a gradient expansion (i.e., an expansion in powers of derivatives of collective meson fields). It is immaterial which form of the Dirac operator, i.e., the original one iD or the chirally rotated one iD 5, is used in this evaluation (at least assuming infinite summation of the heat-kernel expansion). Dhar-ShankarrWadia [ 203 and Ebert-Reinhardt [21] chose to calculate 1det iD1, whereas Ball [22] and we (in (I)) chose ldet iDC I. We do not repeat here the analysis in (I), but show only its outline. First, truncate the heat-kernel expansion at terms of second order. Second, neglect the quantum fluctuation of the scalar field C around its (chiral symmetry breaking) vacuum expectation value, which amounts to setting m . Z with Z a n x n unit matrix and m the constituent quark mass. (The /!I- (U value of m may be determined as a solution of the NJL gap equation, which depends on the intrinsic cuttoff /1 of the theory [20,21].) Third, introduce the coupling constant g,. by the relation (2.18)
294
M. WAKAMATSU
where T(a, x) is the incomplete gamma function defined by T(a, x) = 1: dt e-‘F1. Then, examining the coefficients of the bilinear terms of the field variables in the resultant effective Lagrangian, we have the following relations: M’, = M$ + 6m2,
(2.19)
Here M, and MA are respectively the vector and axial-vector meson masses, while m is the constituent quark mass. Finally, defining the quantity u by the relation M2
a=
-1
( )
(2.20)
1-v
AI:
’
we are led to the following form of effective Lagrangian:
(2.21) where
i?,, = a,R, - a,& + cRp, R,], Z,, = a,Z, - a,& + [Z,, L",-J,
(2.22a) (2.22b)
and
D,5=a,tl+&-5& D,~t=a,~t+~,~t-~t~p.
(2.23a) (2.23b)
In I, this effective Lagrangian was shown to agree with the extended hidden symmetry Lagrangian of Bando et al. with special parameter choice [14] (more precisely, a gauge fixed form of it). The original version of their hidden symmetry Lagrangian [ 131 that contains no axial-vector meson, can be obtained in the following way. Since the axial-vector meson mass MA is much larger than the vector meson mass M,, and since we are interested in the low energy limit, let us assume that the kinetic term of the axial-vector meson can be ignored. In this case, by setting tr & = tr & = tr r$ with rflV = a, vV - a, P+ [VP, FYI, the 2, becomes a redundant field constrained by the equation of motion:
A&=
(2.24)
NAMBU-JONA-LASINIO
MODEL
295
We then arrive at
This form precisely coincides with the gauged version of the hidden symmetry Lagrangian given by Bando et al. [ 131, except that in the present approach the free parameter a of their model is uniquely given by a = ( 1 - M:,/Mi ) -’ in terms of the physical masses of the vector and axial-vector mesons. The value of a = 2, which led them to remarkable phenomenological success, is therefore inseparably connected with the Weinberg mass relation M, =&My [56] in our treatment. Obviously, the Weinberg mass relation is not an exact theoretical prediction of the NJL model. The relation given by this model is Mi = M’,.+ 6m’ (see Eq. (2.19)) with HI the constituent quark mass. The Weinberg mass relation follows if and only if M,,=JZm, which yields with 44, N 770MeV the constituent quark mass m N 315 MeV and the axial-vector meson mass M,, =&M,, N 1090 MeV. It is interesting to see that the above value of m is roughly comparable with the typical value of the constituent quark mass. Now we realize that the identification of the chirally rotated vector field 8, (and possibly the axial-vector field all) as a physical field in the bosonization procedure of the NJL model gives a microscopic foundation of the hidden symmetry approach. As mentioned before, we could alternatively evaluate the heat-kernel expansion based on the original Dirac operator iD. This would lead to another representation of the non-anomalous effective action, as a functional of the original vector and axial-vector fields V, and A, together with the Goldstone field. Practically, it is simpler to do the same thing in another way [19]. That is, by using the explicit relation (2.13) between the field variables, we can express Eq. (2.21) in terms of Vlc, A!,, and U (or R,, L,, and U). The result is
+ a-la r3 4 tr(D, ZJDpUt),
(2.26)
where D,U=d,U+L,U-
UR,,
D, Ut = a, Ut - UtL, -I- R, Ut.
(2.27a ) (2.27b)
296
M. WAKAMATSU
Although it appears that the pion kinetic term does not have its proper normalization, that is not the case. Due to the presence of the mixing term tr APPrc, A, is still an unphysical field. The elimination of this mixing term requires the introduction of the physical field Al through the relation A, + i( l/a)( l/f,) 8,x. After this diagonalization, the pion kinetic term emerges with the correct normalization. For the sake of completeness, let us rewrite the Lagrangian (2.26) in more conventional form [l-3, 10, 111. This can be done through the introduction of the unrenormalized quantities (related to the pion field) as follows:
n(x) = ,Tz k(x),
fr=JZfl,
(2.28)
with Z=-
U-l a
Then, we are led to another equivalent 1 P”)=-tr[V2 @2,
(2.29)
’
form of the Lagrangian
(2.26) as
PV+A2 PV]+5? ext
- a,fi2 tr( VP - VP)’ - a, f,” tr(A, - dP)* 1
+-f4" I2 tr(D PUDpUt) '
(2.30)
where u(x) = eiz’@)lfr and a, = UZ = a - 1. If we identify the p and A i meson with VP and A, (more precisely AL) instead of VP and a,(aL), respectively, Eq. (2.30) is just the massive Yang-Mills Lagrangian of Schwinger [lo] and of Wess and Zumino [ 111 except that it includes the electroweak couplings precisely so as to implement the exact current-field identities [ 121. Now we have confirmed that either form of the (non-anomalous) effective action, i.e., the hidden symmetry one or the massive Yang-Mills one, can be derived from a single quark Lagrangian, i.e., the NJL model. A basic ingredient which relates these two schemes is the chiral rotation (2.13) which depends on the Goldstone pion field. Although the appearances of these two effective Lagrangians are quite different, the physical predictions are identical, as will be illustrated by several examples in Section 3. The rest of this subsection is devoted to the question how to interpret the massive Yang-Mills Lagrangian [ 183. Let us first forget about the presence of electroweak gauge fields (that is, we set VP = dP =O). The idea of the massive Yang-Mills approach is to introduce the hadronic right- and left-handed fields (Rr and L,) as gauge fields of the flavor U(n), x U(n), symmetry, which transform as 4i-4
+ kh(-wu~)
L,(X) -g,(w,(x)
+ a,) d(x),
(2.31a)
+ a,) d,(x),
(2.31b)
NAMBU-JONA-LASINIO
MODEL
297
where gR(x) and gL(x) are the elements of the gauged (or local) flavor U(n), x U(n), group. Although the kinetic terms are invariant under this gauge transformation, the mass terms are not. It is usually said that the gauge invariance is “minimally” broken due to the mass terms [ 1-3, 10, 111. However, the transformation properties (2.31) of the fields R, and L, do not follow from the present treatment in which these fields are introduced as collective meson field such that R,,(x) - qR(x) ypqR(x) and L,(x) - qL(x) yrqL(x), respectively. The transformation properties of R,, and L, suggested by this fact are R,,b) --+g,J-x) R,,(x) dJ.4~
(2.32a I
L,,(-x) + gL(-y) L,(-u) gm,
(2.32b)
rather than Eq. (2.31). Under this transformation, the mass terms are invariant, but the kinetic terms are not. This consideration reconfirms that the theory has only global U(n), x U(n), chiral symmetry (i.e., g, and g, must be restricted to x independent ones), which is certainly a symmetry of the original NJL model. (In any case, QCD is a color gauge theory but not a flavor gauge theory.) It is also instructive to see how the situation changes in the presence of the external gauge fields. A simple situation follows if we assume full “external” gauging of the flavor U(n), x U(n), symmetry, which amounts to introducing 2n2 external (or electroweak) gauge bosons in the present context. By definition, the external gauge fields transform as
under the gauged U(n), x U(n), transformation. Then, owing to the redefinition (2.5) together with Eqs. (2.32) and (2.33) the transformation laws of the new hadronic vector and axial-vector fields are just given by Eq. (2.31). That is, the new R,, and L, transform as gauge fields under the (externally) gauged U(n), x U(n). transformation (precisely in the same way as the external gauge fields %!P and 9’, do). Because of this fact, the generalized mass terms -uf 5 tr( I’,, - $,)I and --af z tr(A,- c$)2 in Eq. (2.26) are obviously gauge invariant [18]. Thus, in a licitious world where there exist 2n2 external gauge fields corresponding to the full flavor U(n), x U(n), symmetry, the notion of the massive Yang-Mills Lagrangian now becomes legitimate. (Curiously enough, what we have obtained is the “gauge invariant” massive Yang-Mills Lagrangian.) However, this conversely makes us conclude that in the real world where there are restricted number of external gauge fields, i.e., the photon, W’ and Z bosons, the notion of the massive Yang-Mills scheme cannot be justified in any strict sense. Summarizing the argument, we conform that the flavor symmetry is a global one, and simple-minded gauging of it has little meaning. The hadronic fields V, and A,, in our model are simply spin 1 composite particles of a quark and an antiquark,
298
M. WAKAMATSU
and they are not to be interpreted as Yang-Mills gauge fields, even though the formal appearance of the Lagrangian is that of the massive Yang-Mills model. 2.3. The Anomalous Now we turn to First, we point out the imaginary part Eq. (2.14), since
Effective Action the discussion about the anomalous part of the effective action. that the Jacobian 5(l) of the transformation (2.9) is related to of the (euclidean) effective action [20,21]. This is clear from
ZV,log J(r) = iN,(Im(log
det iD) - Im(log det iD5)}.
(2.34)
Here we have used the fact that the modulus of the quark determinant is chiral gauge invariant, i.e., Eq. (2.17). It is also clear from Eq. (2.34) that the Jacobian J(l) is a pure phase. For actual evaluation of J(c), more useful is the following formula which shows a response of J(t) under a small chiral (axial) variation of < from <=g to t=g+6g: NJ,
logJ(g)~N,(logJ(g+~g)-logJ(g)} = -iN,(Im(log
det iD g+ag) - Im(log det iDg)>
= -id,A(g). Here, the definition as
(2.35)
(2.16b) of A has been used. Noting
that Ljg G iDg is expressed
~‘g=(gPL+g+pR)~g=‘(gPL+g+pR),
(2.36)
we can show that &J$~Ijg+&-~Ez = f pgg+ -g+sg, Bq - f (g(dgg+ + g+dg), fig}.
(2.37)
On the other hand, using Eq. (2.16b), we have (2.38) Here, use has been made of the equality [bg, e-‘(‘g)2] = 0 and the cyclic properties of the trace. Then, by using Eq. (2.37), we find 6,A(g) = -NC Im Tr’{y’(Ggg+
+g+dg) eP(Bg)2/n2}.
(2.39)
The evaluation of the trace of y-matrix is long and tedious. The answer was already given by Dhar, Shankar, and Wadia [20] and also by Ebert and Reinhardt [21]. It is written in the form:
NAMBU-JONA-LASINIO
299
MODEL
N,.hA log J(g) = -i6,d d(g) = iTr(hg’
+ gt& 1GAL;,
where G,(LY,, RR,) is the chirally rotated Bardeen anomaly tional Ge(LI,, R,,) is given in the following form Ge(L,,,
RJ=s
( 2.40 )
R”, 1,
[20, 21, 471. The func
F;,+;F:+;A4-;(Fb,A2+AFL.A+A2Fv)
,
(2.41
1
with F,,=dV+
V’+A’,
(2.42a )
F,,,=dA+
VA+AV.
(2.42b)
Here we adopt the notation of differential forms [48851]. (The vector and axialvector fields are l-forms defined as V = V,dx@ and A = A, dxp and the l-form d= dxp8, denotes the exterior derivative.) The Jacobian J(5) itself can be obtained by integrating Eq. (2.40) between g = 1 and g = 5. The most elegant way of performing this integration is to use the differential geometric method [48-511. The independence of the final result on the integral path is assured by the WessZumino self-consistency condition for the anomalous action. This condition requires that the U(n), x U(n), group properties are maintained even in the presence of the anomaly [47-511. It is also understood as a generalized Bose symmetry in the -perturbative context [52]. This means that the axial-vector vertices (and also the vector vertices) appearing in the quark l-loop diagrams are treated symmetrically among themselves. The integration constant of the above integral is given by Im(log det iLIt), which was shown to vanish in the soft momentum limit by Dhar, Shankar, and Wadia [20] and also by Ebert and Reinhardt [21]. Then, N,. log J( 5) just gives the imaginary part of the fermion determinant, which is in turn to be interpreted as representing an anomalous action. The final answer can be written in several equivalent forms. For our later consideration, it is especially convenient to write it in the following form [Sl ]: r wzwC& L,,, &I = -iN,. log 4;) = W’o(L, R)-
W(‘(l, w),
(2.43)
where
where c’ = -i(N,./24z’)
WdL, R) = c’ jB5&(L, R),
(2.44)
i? = 5(R + d) 5+,
( 2.45a )
L = t+(L + d) i’.
(245b)
and
300
M. WAKAMATSU
Equation (2.45) is nothing but the differential form notation of Eq. (2.13). In Eq. (2.44), BS is a five-dimensional manifold with space-time as its boundary. The quantity c&+ , is the so-called Chern-Simons secondary form defined by c&+,(L,
R) = (n + 1) s,’ ds tr(A’(s) F”(s)),
(2.46)
where A’(s) = (d/ds) A(s) with A(s) = L + s(R - L),
(2.47a)
F(s) = dA(s) + A2(s).
(2.47b)
The particular choice of the integration path specified by Eqs. (2.46) and (2.47a) corresponds to vector gauge invariant regularization scheme [SO, 511. The quantity W’(L, R) is therefore invariant under vector gauge transformation. The standard process of obtaining the anomalous action in this formulation goes as follows [SO, 511. Using the vector gauge invariant property of W”(L, R), we obtain WO(L, R) = T((, 5) WO(Z, 8) = W’(L,
where T(gL, gR) defines the action U(n),,
R”),
of an element
(2.48)
g = g, P, + g,P,
E U(n),
x
and RU = U(L + d) UT,
(2.49)
U(x) = 5’(x) = $i=(x)/fn.
(2.50)
with
Then, we can rewrite Eq. (2.44) as r ,+/&U;
L,, R,] = W’(L,
R) - W’(L,
R”).
(2.51)
This form has the advantage that the effective action is represented in terms of the conventional unitary matrix U(x) and the vector and axial-vector fields V= i (R + L), A = i(R - L). Skipping the intermediate steps, we write down the final expression of this Wess-Zumino-Witten action. (For detail, refer to the review articles, for example, by Zumino [49] or by Petersen [Sl 1.) It is given as rwzwc
u; L, 3
$,I = c‘ jB5w;( UT dU, 0)
-c’s
sICp4(0,L,RC’)+p~(0,U+dU,R)-(U=1)1,
(2.52)
NAMBU-JONA-LASINIO
MODEL
301
where (2.53 I
-&,tr(UtdU5,
ot(UtdU,O)=
~~(0, L, R) = $tr[(LR
- RL)(F,
+ FR) (2.54)
- L3R - LR3 + $ LRLR].
We point out that the resultant anomalous action is just the same as the one u priori assumed in the massive Yang-Mills treatment of the chiral anomaly [Z, 27-291. A key ingredient leading to this result is the redefinition (2.5) of the internal vector and axial-vector fields. As was already mentioned, this redefinition works so as to eliminate the couplings between the quarks and the electroweak gauge fields. As a consequence, we get the anomalous action as a functional of the hadronic vector and axial-vector fields (and also the Goldstone field) instead of the external gauge fields. Then, our next question is the anomalous action in the hidden symmetry scheme. What should be recognized here is the following fact. Since the anomalous action in our treatment (based on a fermion theory) is given as the Jacobian of the chiral transformation or equivalently as the imaginary part of log(det iD)N,, its determination is essentially unique, once the regularization of the fermion path integral is unambiguously defined. This means that, in order to obtain the corresponding anomalous action in the hidden symmetry scheme, we have only to rewrite the WesssZumino-Witten action which was already given as a functional of U, L, and R, in terms of the field variables U, t, and R with use of the relations (2.13 ) or (2.45). A brute force evaluation would be a cumbersome task. Fortunately, there is a simple way of doing it. Of fundamental importance is the symmetrical role played by the original (L, R) and the chirally rotated (2, R) left- and right-handed fields in the definition (2.43) of the Wess-Zumino-Witten action. This equation together with the relations (2.45) and their inverse relations, R = t+( ii + d) 5,
(2.55a)
L = <(L + d) it,
(2.55b)
enables us to express the Wess-Zumino-Witten r wzw= W’(L,
R)-
W’(t(L+d)
action in two equivalent forms as t+, S+(R+d)
5)
= - [ W”(~, iT) - W”((+(.t + d) 5, [(ii + d) <+)I.
(2.56)
Note that the two functional forms of rwzw (one as a functional of L, R, and rc, the other as a functional of z, R, and II) are very similar aside from the overall sign difference and the interchanged role of 5 and <’ (or n and -7-r). Now we can make use of an important property of the function W”( L, R) [48-5 11: it is antisymmetric under the exchange of L and R, i.e., W”(L, R)= -W’(R,
L).
(2.57)
302
M.WAKAMATSU
From this equality, there follows a well-known property of the Wess-ZuminoWitten action [35, 361: it is antisymmetric under the simultaneous exchange of L w R and U c) Ut (or n ++ --71). Then if, for example, the first line of Eq. (2.56) has vertex pieces such as dV”‘A” (1, m, n = integer, I+ n = odd), it is easy to see that the second line of Eq. (2.56) has corresponding
(2.58) vertex pieces
- (-71)‘PLP.
(2.59)
This provides us with a simple rule of constructing the anomalous action in the hidden basis, in which the chirally rotated fields P and 2 are identified as the physical particles. More precisely, an additional complication arises from the A,-n mixing. This must be removed by the following redefinition of the axial-vector fields
in the massive Yang-Mills
scheme, and J=A’-i-.-.
in the hidden difficulty.
symmetry
a-l a
1 f,
d*’
scheme. That can however be handled
without
any
3. PHYSICS OF THE NON-ANOMALOUS SECTOR In this section, we shall investigate some physical implications of our effective Lagrangians, concerning first the physics of the non-anomalous sector. The main objective is to show the equivalence of the massive Yang-Mills Lagrangian (2.26) and the hidden symmetry Lagrangian (2.21). Here we confine ourselves to the simple case where the photon is the only external gauge field, which amounts to setting (3.1) where gP = - i&@;7’ with & the relevant charge operator and g;“’ the photon field. The effective action (2.26) in the massive Yang-Mills scheme is expanded in powers of the pion field n(x), by taking care of the Al-x mixing (2.60a). Then, we find
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303
MODEL
where (3.3) (3.4) (3.5) 1 1 Yt.,, = 2 tr VII[7c, P7c] - 7 7 tr(a,, V,. - C!,,V,)[?%
a f,s;,
Y
?7r],
(3.6)
tr(8, V, - 8, V,,)[A’p, 8x1 +2i--
1 1
afd2,.
tr(a,A:
- a,AI)[
V’, c?‘x] (3.7)
- 2i
(3.8) T,, = 9k,,(L3,) .Pyv = 2a e f
- a e2f ‘, tr a:,
(3.9 1
', tr BP VP.
(3.10)
On the other hand, in the hidden symmetry scheme, we have P)
= g + Pv + T& + Pv,, + Pb..4n +~~++~v+~~nn+~~.4n+~;~C.nn+
“.,
(3.11 )
where (3.12) (3.13) (3.14) a-1’
PL,,, = a tr Fp[n, P7c] -
7
(
1 -tr(a~,a,-a,,~~)[a~~,avn],
> f", g:..
(3.15)
304
M. WAKAMATSU
2Fva, = -2i -u-l
7 1 tr(ap 8, - 8, FJ[A”‘“, Prc] a fngv u-l 1 -2i -tr(a,J: - a,J;)[ VP:“,Prc], a fd;?y (3.17) (3.18) (3.19) (3.20)
(3.21) Note that, in both schemes, the vector and axial-vector meson masses are given as M2, = afig; and Mf4 = (a2/(a - l))ffgc. At first sight, the two forms of effective Lagrangians, i.e., Eqs. (3.2 j(3.10) and Eqs. (3.11)-(3.21), look quite different. (Note in particular the difference between the VW coupling strengths in the two schemes in the general case of a # 2. This turns out to play an important role in the following study.) Only with the special choice a = 2, many corresponding terms of the two schemes coincide with each other. But, even in this case, we do not have complete correspondence between the two schemes. Some couplings existing in one scheme are simply missing in the other. (One example is the nrcVV coupling in the massive Yang-Mills scheme.) Nevertheless, we will show below by several examples that both schemes give identical predictions independently of the value of a as far as the on-mass-shell (or physical) vertices in the low energy domain are concerned. The first example concerns the coupling between the external photon and the Goldstone pion in the soft momentum limit. In the massive Yang-Mills Lagrangian, there is no direct photon-pion coupling. The photon couples to the pion only through the vector meson. Assuming the low energy (zero-momentum) approximation for the vector meson propagator [2629], i.e., dab Gzi(vector) N i g”” MZ,
(3.22)
V
where M$ = af ‘, gt, coupling becomes
the effective yrcrt vertex through r,,, = 2etr .C@Jrc,Prc].
the vector meson mediated (3.23)
Here we have used the VT-UCcoupling given by Eq. (3.6). On the other hand, in the hidden symmetry scheme, the direct photon-pion coupling vanishes only when a = 2. (In other words, the vector meson dominance holds only for this special
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305
value of a [ 131.) In the general case of a # 2, the effective y?rrcvertex in this scheme is (3.24) Here the first and second terms (in the brackets) are the contributions from the direct “~nz coupling and that from the vector meson mediated coupling, respectively. Note that the answers of both schemes are the same irrespective of the value of a. (This is a trivial example, since the electromagnetic charge of hadrons should receive no renormalization in any realistic model of strong interactions.) The second example is the 7~7~scattering amplitude in the low energy limit. The effective 47c vertex in the massive Yang-Mills scheme is (3.25) Here the first contribution comes from the second term of Eq. (3.12), while the second is the contribution of the vector meson exchange diagram resulting from the coupling L?&,,, . Here Eq. (3.22) is assumed again. (The contribution of the second term of LZV,, to the effective 4n vertex contains higher derivatives of the pion field compared with Eq. (3.25), and can be neglected in the soft pion limit.) The effective 4rr vertex in the hidden symmetry scheme is similarly evaluated as (3.26) In either case, the vector meson exchange contribution cancels a part of the direct 47~interaction one [53]. Note that this cancelation is independent of the parameter a and the final answers are the same in both schemes, i.e., I‘,,=F,,=+tr[7r,d,,n]’ . It
(3.27)
which precisely reproduces the low energy theorem prediction. Instead of carrying out exhaustive study, we shall be satisfied by giving one more interesting example. This concerns the 7c*--71’ mass difference in our effective meson theories [ 543. Since we are treating ideal chiral symmetric limit, this mass difference is of purely electromagnetic origin. (In the following, we consider the SU(2), x SU(2), flavor symmetry, by setting n = 2 and neglecting U( 1) symmetry.) In the massive Yang-Mills scheme, three Feynman diagrams illustrated in Fig. 1 contribute to this mass difference. An elementary calculation shows that
M. WAKAMATSU
306
(A)
(B)
ICI
FIG. 1. The Feynman diagrams that contribute Yang-Mills scheme.
to the n’-no
where PA, RB, and S$ are respectively diagrams (A), (B), and (C), given by
the contributions
3
SB = e2M~M~,
A
[ q2(q2-M:y+M;q2
SEC= e2M~M~,(M~,
- Adi)
from the Feynman
1 ’
[
3
I
q2(q2-M:,)(q2-M~)2-M391M~q2
Here ,J is the gauge parameter of the photon propagator P’(photon)=
mass difference in the massive
4
1 .
(3.31)
given by
1
-$+(2-l)?. g”y
In the above derivation, we have neglected the small photon mass of the order of e2, since it only gives corrections of order e4 to 6Mi. (Note that we are working in an unphysical basis in which the direct y-V coupling still remains. We can perform this calculation alternatively in the physical basis, in which this coupling is eliminated and the photon is exactly massless.) On the other hand, the Feynman diagrams that contribute to the z*-z” mass difference in the hidden symmetry scheme are illustrated in Fig. 2. A similar calculation shows that
(a)
(b)
(c)
td)
(e)
FIG. 2. The Feynman diagrams that contribute to the n’-x0 mass difference in the hidden symmetry scheme.
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(6Mf),,=
-ig$
MODEL
{Fa+F4+~.+FJ+.3J,
307 (3.33)
where 2
i.
(3.34
e2_;, 4-
(3.35 (3.36) (3.37) (3.38)
As was expected, the answers of both schemes are again the same, i.e., Fd + FB + .F(. = F. + 4 + E + .Fd + 9;, = 3e’
M:,M; q2(q2-M:Jq2-M;)-
(3.39)
Note that the result is independent on the gauge parameter 2 of the photon propagator. This is natural since our Lagrangians have electomagnetic gauge invariance. Performing the momentum integration, we arrive at an elegant formula: (3.40)
which was first derived by Das, Guralnik, Mathur, Low, and Young [SS] by using the current algebra technique supplemented by the Weinberg spectral sum rule [56]. Assuming the Weinberg mass relation M,, = 4 M,, (and by using M,, = 770 MeV), this formula gives M,t - M,o =
@Mf,), 2 5.20 MeV, M,+ + M,o
(3.41)
which is surprisingly close to the experimental value 4.6 MeV [54]. Note that the answer so obtained is finite, even though we are evaluating l-loop diagrams. (This is true only in the exact chiral symmetric limit. It is known that, for finite pion mass, there appear logarithmically divergent corrections [57].) The cancellation of the high momentum contributions between the Feynman diagrams (B) and (C) or
308
M.WAKAMATSU
(d) and (e) are the cause of the above result. This illustrates an important role of the A, meson as a chiral partner of the p meson. From the phenomenological viewpoint, both forms of our effective Lagrangians with the explicit A, degrees of freedom have their obvious limitation. For example, it is known that a strong momentum dependence of the pnrc coupling comes from the redefinition (2.60) of the A, field, which modifies the successful KSFR relation and also makes the effective A I yrr vertex vanish in contrast with experiment [l-3]. To remedy this situation, Bando et al. proposed to add higher derivative terms in their effective Lagrangian entirely on phenomenological ground [SS]. Recall that the necessity of such higher order terms has been recognized for a long time in the massive Yang-Mills scheme [ 1,2]. Since the purpose of our present analysis is not to construct a phenomenologically complete model but to analyze the theoretical structures of the two widely-used effective meson Lagrangians, we do not go into the detail of this problem. We only comment that the predictions of the two schemes are identical also for the above problems, even though they are phenomenologically unsatisfactory.
4. PHYSICS OF THE ANOMALOUS
SECTOR
Now we turn to the discussion of the anomalous part of the effective action as derived from the NJL model. We start with the Wess-Zumino-Witten action in the massive Yang-Mills representation obtained in Section 2: r(a) E r
wzwcu; L, RI =r,,cu1+
{LCU; L, RI -r(Ju=
1; L, RI}, (4.1)
where I’,,[U]
= CjB5 tr(Ut diJ)5,
rcCG; L, RI = 5C S, ,i
ri[ U; L R],
l-1
with cc
N 240x2.
--i---.-L
(4.4)
The vertices Ti are given by rI = -tr URU+(LdL+dLL)-(L-R, r2 = -tr URUtL3
- (perm),
I-,= tr URUt(dUUt)2L
-(perm),
u.
Ut),
(4.5) (4.6) (4.7)
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309
MODEL
f4 = tr dUUt( LdL + dLL) - (perm),
(4.8)
f 5 = tr dUUt L3 - (perm),
(4.9)
r6 = -tr(dUUt)3L r, = tr URU’
- (perm),
LdUUt
(4.1 I)
L - (perm),
Ts = -tr lJRUtdUUtdL
(4.12)
- (perm),
Ts = - $tr RdUtURdUtU-
f,,,=
(4.10)
(4.13)
(perm),
(4.14)
$tr(LURU’)‘,
where U(s) = J?(““~. For practical consideration, we must expand the above action in powers of n(x). This can be done by using the following identities,
u~U+=B+~[~,8l-~[n,[n,B,l-~~n,In.[~,81]]+ ..., T: IT -. n
(4.15a) (4.15b)
and Udu+ = -;
*
dn +f
R
[n, dn] + $
U+dU=~d~+~In,d~]-~In, x x
T[
[n, [n, dn]] [r,dn]]+
n
+ ... .
,
(4.16a) (4.16b)
This gives, in the lowest powers of z(x), 5
tr(Ut dU)s - tr = $$ d[tr n(dn)4]. K
(4.17 I
Then, using Stoke’s theorem, we find fwz[
U] - 32Ciz
1
(4.18)
The second term of Eq. (4.1) is a complicated functional of the fields V, A, and n. Furthermore, the axial-field here is not still a physical one, because of the ,4-n mixing term contained in the non-anomalous part of the effective action. The physical field A’ is defined by Eq. (2.60a), i.e., A = A’ + i( l/a)( l/f,) dn. Fortunately, after a detailed inspection, it can be verified that the propagation of the axial-vector field
310
M. WAKAMATSU
does not contribute to the anomalous processes which we shall study below at the tree level. This allows us to set A’ = 0, or (4.19) which simplifies practical calculations considerably. It should be emphasized that our elimination procedure of the axial-vector field is different from the one of Scoccola et al. [ 381. They set A = 0 instead of A’ = 0, after proving that this elimination procedure is equivalent to the one of Schechter et al. with use of the Stiickelberg transformation [29, 341. We will come back to this point later. Introducing Eq. (4.19) into the second term of Eq. (4.1), we find r(~)=r,+r,+r,+r
(4.20)
ZT
where rwz
= 32C f. tr x(&)~,
(4.21)
f:
tr7r(drr)4,
(4.22) (4.23) (4.24)
T,=SCEtrdVdVrc.
fn
Here and hereafter, we omit the space-time integration symbol, for brevity. In order to obtain the anomalous effective action in the hidden symmetry scheme, we need not repeat tedious calculations. We have only to recall the argument given at the end of Section 2. (See Eqs. (2.56), (2.58), and (2.59), in particular.) The only one thing we must be careful about is that the definition of the physical axial-vector field is now given by Eq. (2.60b) in this scheme and therefore we should set
J= -i a-l --drc,
1
a fn
(4.25)
corresponding to Eq. (4.19). Then, after some algebra, the effective anomalous action in this scheme is found to be
F-@’ =F:wz + r;, + Fy+i-z,
(4.26)
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311
MODEL
where
(4.29 ) (4.30) We immediately note that if a = 2 the functional forms of the anomalous actions in both schemes are exactly the same. However, we will show below that the physical equivalence of the two schemes holds irrespective of the value of u. Now, let us investigate some physical implications of the anomalous actions (4.20) and (4.26). First, the op7c vertex is given by Tz or Fz in each scheme. The standard definition of the coupling constant g,,,, given as
tr dVdVn, l-z= ropn= -2(g,,,,/g~~)
(4.31 )
leads to the prediction 3d g cop*= -- 8rc2.fn’ which has good phenomenological support [2,3, 22-331. The prediction of the hidden symmetry scheme is just the same, since the functional forms of Tz and Fz are identical. The well-known rr” + 2y decay occurs through the vector meson mediated process (no + po + 27) illustrated in Fig. 3, because the coupling between the external photon field and the hadronic fields is contained only in the nonanomalous part of action. This is again a common feature of the two schemes in our treatment. An elementary calculation with use of the couplings (4.24) and
FIG.
3.
The Feynman
diagram
that contributes
to the no + 2y decay
in our model
312
M. WAKAMATSU
(3.10) together with the zero-momentum approximation propagator leads to the effective ~yy vertex: 3e2 Lr(~"+2Y)--y-
4T.Lfn
for the vector meson
tr dS9dS?n,
which precisely reproduces the low energy theorem. Next we shall analyze the y + 371 process. Since the y -+ 371 process takes place necessarily through the o meson in the present models, it is simpler to treat the w -+ 371 process in the soft-pion limit (q, = 0). In the massive Yang-Mills action, both of f y and Tz contribute to this amplitude. We recall that the second and third terms of ry, which depend on the parameter a, comes from the A i-71 mixing effect. To stress the role of the axial-vector meson, we show in Fig. 4a the corresponding Feynman diagrams. Here, the second and third diagrams do not mean propagation of the physical A, meson but they are to be understood to give graphic representations of the A,-n mixing effects. On the other hand, the action r, contributes to the above process through the vector meson mediated diagram illustrated in Fig. 4b. The resultant effective vertex is (3/a) tr V(drc)3. Then, adding up the two contributions, we have in the massive Yang-Mills approach: I-,,(0 + 37c)- &{(l-i+$)+i}tr We can similarly
V(dn)3.
obtain the effective vertex in the hidden symmetry scheme as
Fe&3 + 371)~--&{(1-3($)+~(~)2)+~{tr
v(dn)3.
(4.35)
Here the .first and second terms result from p, and iiZ, respectively. We find that, despite the difference of the individual contribution, the final predictions of the two schemes are identical independently of a, (4.36)
FIG.
4.
The Feynman
diagrams
that contribute
to the process
w --t 371.
NAMBU-JONA-LASINIO
MODEL
313
Unfortunately, this result breaks the low energy theorem in the order of l/a’. (Note that this term originates from the A 1-n mixing effect of second order; the third diagram of Fig. 4a.) The low energy theorem insists that the coefficient of tr P’(&c)~ or tr 8(~&)~ in the brackets of Eq. (4.36) must be 1. Nonetheless, the cancellation among the terms of order l/a is a noteworthy feature. In the massive Yang-Mills scheme, such terms come from the vector meson mediated diagram (Fig. 4b) and the A ,-n mixing effect of the first order (the second diagram of Fig. 4a). Both terms just cancel. In this sense, the A,-7~ mixing effect plays an important role. There obviously exists a mechanism which suppresses additional contributions from vector mesons in this scheme [2, 27, 291. Had we neglected the A,-n mixing and simply set A = 0 in the Wess-Zumino-Witten action, we would have (4.37)
which breaks the low energy theorem even worse than before. (Here, the first and second terms are the contributions from the direct o -+ 3n coupling and the vector meson mediated process, respectively.) According to Scoccola et al. [38], the above elimination procedure (i.e., setting A = 0) is equivalent to the one of Schechter et al. with use of the Stiickelberg transformation [29, 341, which amounts to setting R = <+( p+ d) i”.
(4.38a) L = 5( P+ d) i”‘.
(4.38b)
in the effective action in the massive Yang-Mills basis. Here v is to be interpreted as the physical vector meson field. (More precisely, the equivalence proof by Scoccola et al. relies upon the fact that the Wess-Zumino-Witten action is chiral gauge invariant in the absence of the axial-vector degrees of freedom, and cannot be applied without special care to the non-anomalous part of the action which is not generally chiral gauge invariant.) Thus, our analysis above indicates that the Stiickelberg elimination of the axial-vector meson results in losing an important cancellation mechanism between the contributions of the vector and axial-vector mesons to the anomalous process y + 37r. Accordingly, the discrepancy of the massive Yang-Mills scheme is exaggerated too much. This throws a little doubt upon this elimination procedure of the axial-vector field. We recall that it was criticized also by Yamawaki [18]. This elimination method amounts to dropping one physical degrees of freedom (the A, meson) by hand, but the problem is that this brings about some inconsistency with its equation of motion. We comment that our (standard) elimination procedure of the axial-vector meson is nothing inconsistent with the equation of motion. We should point out that our prediction (4.34) for the w -+ 37r amplitude is nothing new. It was already given by Kaymakcalan et al. in their massive Yang-Mills
314
M. WAKAMATSU
treatment of the problem [27]. (See also Ref. [2, 343.) This is easily understood, because we already know that the effective action resulting from the NJL model is formally identical to theirs (but for the non-minimal terms in the non-anomalous part of their Lagrangian). What is new in our results is that the hidden symmetry scheme, if treated mutually consistently with the massive Yang-Mills scheme, gives the same answer. The feature described above can be demonstrated even more clearly in our next example, the anomalous process K+K- -+ 3~. In the following, n(x) should be understood to represent generically the Goldstone fields belonging to the octet representation of flavor SU(3). The effective 5Goldstone vertex in the massive Yang-Mills scheme turns out to be I’,,(K+
K- + 3~) ‘v
(4.39) Here the first and the second terms are the contributions of the contact diagram in Fig. 5a. (The first comes from the Wess-Zumino term, and the second from r, in Eq. (16b), which is entirely due to the A,--71 mixing effect.) The third and fourth terms are the contributions of the vector meson mediated diagrams illustrated in Figs. 5b and c. Adding up all the contributions, we eventually find f,,(K+K-
--t 371) N {l+5(&&i)]bz.
The low energy theorem requires that the answer should be Twz C59-613. We again see that it is violated in our model. This breaking however happens only in the higher orders of l/u. In particular, the terms of order l/a and l/a2 exactly cancel among themselves. This again shows the important role of the axial-vector field, which appears through the A i-71 mixing. Simply setting A = 0 (or equivalently using ‘\
(a) I’
‘\ ,’ ,y;--I ‘\
,’ \
(d FIG.
5.
The Feynman
diagrams
that contribute
to the process
K+K-
+ 3x.
NAMBU-JONA-LASINIO
MODEL
the Stiickelberg elimination) in the gauged Wess-Zumino-Witten justified. Had we done so, we would have found
315
action is not
(4.41) Setting a = 2, this precisely reproduces the result of Scoccola et al. [37], which leads to an intolerably large violation of the low energy theorem. Unfortunately, the parameter a dependent correction in Eq. (4.40) is far from small for a ‘v 2. A direct experimental check of the low energy theorem is highly desirable. For the sake of completeness, we have analyzed the same amplitude based on the effective action in the hidden symmetry basis. The answer is as follows:
Here the first and second terms come from the contact diagram, and the third and fourth ones from the vector meson mediated diagrams. If we add up all terms, we find after a series of cancellations: R,,(K+K--
+3n)
-{1+5(&$)}r,,,.
(4.43)
which precisely coincides with the answer (4.40) of the massive Yang-Mills scheme. From the analysis so far, we have therefore convinced ourselves that the two schemes, i.e., the massive Yang-Mills and hidden symmetry schemes, are physically equivalent as long as they are treated with mutual consistency. This conclusion may be self-evident, from the viewpoint that these effective Lagrangians are two different but equivalent bosonic representations of a single fermion theory, i.e., the NJL model. Alternatively, the above equivalence may be thought of as a special example of the well-known theorem due to Kamefuchi-O’Raifeartaigh-Salam [63] (See also Ref. 64).), which claims that the on-shell S-matrix is invariant under the change of field variables. (Strictly speaking, their exact proof was given only for point transformations, i.e., transformations which do not involve time derivatives of the fields. On the other hand, the transformation (2.13) relating the field variables of the two schemes generally includes time derivatives. However, they also suggested that their theorem may be generalized to include such cases as well.) To be more rigorous, our demonstration on the equivalence of the two schemes is far from complete. The explicit examples given here are concerned with the processes which contain the Goldstone bosons and the photon as external particles. (The only exception is the statement given at the end of Section 3 that the on-massshell prcn vertices are exactly the same in both schemes.) They are those amplitudes
316
M. WAKAMATSU
which are determined by the symmetry structure of the Lagrangians and might not be sensitive to the different dynamical structure possible for the heavy states, i.e., the p and A, mesons. Although we believe that the equivalence still holds for such processes as containing the heavy mesons at least after properly incorporating the quantum loop effects, the direct check of it might not be straightforward. This is because we are treating effective Lagrangians which are not renormalizable in the usual sense, and therefore we have no convincing method of handling divergences which appear in the evaluations of loop diagrams. (This should be contrasted with the processes studied in this paper. For these processes, the equivalence holds at the tree level.) Despite this insufficiency, it is hoped that the present analysis has achieved a partial success in clarifying several questions concerning the conceptual relation between the two popular approaches to low energy effective models for mesons.
5. THE ANOMALOUS SYMMETRY BREAKING AND CURRENT NON-CONSERVATION In the previous sections, we have advocated the viewpoint that the massive Yang-Mills and (extended) hidden symmetry schemes are two different but equivalent bosonic representations of a single quark theory. That parameter a is independent of this equivalence is a noteworthy feature of the present analysis. To avoid confusion, however, we should emphasize that the extended hidden symmetry Lagrangian obtained here from the generalized NJL model is different from the corresponding model Lagrangian of Fujiwara et al. [33], which contains no A, degrees of freedom. (Remember that it is the Lagrangian adopted by Scoccola et al. in their comparative analysis of the two schemes [38].) It is known that this model satisfies all the low energy theorems [33]. This is certainly related to the fact that it does not contain the explicit AI degrees of freedom. The more essential reason is however an assumption made in their construction of the anomalous action. As was mentioned in Section 1, it was a priori assumed that the anomaly sits in the part of the effective action that includes the Goldstone field and the external gauge fields alone, and that the other part containing the hadronic vector field is anomaly free. This latter part can be fixed only through phenomenology. We have no objection against such an approach, since it is consistent with the general belief that the only dynamical anomaly in QCD is the U( 1 )A axial current anomaly. What is not clear to us however is a microscopic (quark-level) basis of such an ad hoc model construction. This should be contrasted with our treatment, in which the anomalous action is essentially uniquely determined (up to the regularization scheme arbitrariness), once we start with the definite fermion Lagrangian, i.e., the NJL model. However, the violation of the low energy theorems for some anomalous processes is an unpleasant feature of our model. The reason why our model breaks some of the low energy theorems is basically a known subject from the previous studies [27-29, 33, 343. We have only to remember the fact that one of our effective Lagrangians derived from the
NAMBU-JONA-LASINIO
317
MODEL
generalized NJL model formally coincides with the massive Yang-Mills model generalized by Kaymakcalan et al. so as to include the anomalous part [27-291. Nonetheless, we think it instructive to perform a reanalysis of the problem on the basis of the NJL model. This is because for this special model we have translation rules (although of approximate nature) between the quark language and the collective meson language. This enables us to clarify the general structure of the hadronic currents in a transparent fashion. For example, we can get an interesting insight into the origin of the current-field identities a la Sakurai [ 121. We can also answer the question whether the presence of anomalies is really inconsistent with the equations of motion for the “massive” vector and axial-vector fields [27]. Let us start with the expression (2.6) of the generating functional. (In consideration of the equivalence of the two schemes, only the effective action in the massive Yang-Mills represenation will be discussed below.) After neglecting the quantum fluctuation of the scalar field, it reduces to
II (5.1)
. ~[iy”(a,
+ R, P, + L, PL) - m( UPR + U+ P,)]
= exp
q
(5.2)
The basic currents are defined in terms of the right and left variations of the action T, = -i log Z/: (53a) (53b) From Eqs. (5.1), (5.2), and (2.19), we have (5.4)
318
M. WAKAMATSU
which is also expressed in the following form:
where r strong= r,-
2
tr[Ri
+ L:],
(5.6)
V
is the strong interaction
part of the action and (5.7a) (5.7b)
are the hadronic currents which couple to the external gauge fields. We see that the currents .I;” and Jk are exactly proportional to the hadronic fields R, and L,. This is just the current-field identities a la Sakurai [12]. Undoubtedly, it is a consequence of the specific nature of the NJL model, i.e., the four-fermion form of interactions together with the field redefinition (2.5) Now, the anomalous conservation equations for the currents (5.3) can be obtained by investigating the change of an action under the following V(n), x U(n), gauge variation: R, + g.0,
+ a,) st,,
(5.8a)
L, + gdL,
+ a,) gt,
(5.8b) (5.8~)
u+gJJ& First consider the infinitesimal
right variation, g,=@4
i.e., +ieR.
(5.9)
The changes of the fields R,, L,, and U under this variation
6,R, = 4a,,& &Lp=O,
(5.10a)
+ CR,, e,l)
(S.lOb) (5.1Oc)
6, u = -iUO,.
The change of an action r under the right variation
are given as
is then
(5.11)
NAMBU-JONA-LASINIO
319
MODEL
where we have performed a partial integration derivative D,(R) operating on a matrix M by D,(R)M=a,M+
and introduced
the covariant (5.12)
[R,, M].
The standard argument goes as follows [47, 51, 651. By setting r=f,-(Eq. (5.2)), and imposing the equation of motion for the Goldstone field Sr/SU = 6r,/6U = 0. we obtain S,r,-=
i =
I
d4x tr 8, D,,(R) 2 I’
d4x tr !3,Dp(R)j,t.
s
(5.13)
Here use has been made of the definition (5.3a) of the current j:. hand, the gauge variation of r’ by definition gives the anomaly: S,r,=
On the other
(5.14)
1 d4.x fr tl,G,.
After a similar consideration about the left variation, we are thus led to the following anomalous conservation laws for the currents jf and ji : D@(R)j,R = G,,
(5.15)
D”(L)j,L
(5.16)
= G,.
The explicit form of the anomaly depends on the regularization scheme. If we adopt the vector gauge invariant scheme as in the present analysis, the anomaly is the so-called Bardeen form [47-5 1,651: G,=
-G,=G,(R,,
L,,).
(5.17)
Now we come to the following question: what is the relation between the above “covariant” conservation (or non-conservation) laws for the currents j,” and jb and the “ordinary” conservation (or non-conservation) laws for the symmetry currents dictated by the presence of global (or rigid) symmetries? This can be seen as follows. The equations of motion for the hadronic fields result from the stationary requirement of rstrong under arbitrary variations of R,, L,, and U. On the other hand, the gauge variation (5.19) is a special case of such arbitrary variations. Then. it follows that ’ R rstron,
=
6 L rstrong
=
O.
(5.18)
This, combined with Eq. (5.6) as well as Eqs. (5.3), leads to the following equations:
320
M. WAKAMATSU
DG(R)(j:-gR,)=O,
(519a)
D@(L) (ji-zL,.)=O. Then, using the identities P(R) R, = PR, and P(L) L, = PL,, as well as the definition (5.7), we now see that the covariant conservation Eqs. (5.15) and (5.16) for the currents j,” and j,” are equivalent to the following ordinary conservation equations for the currents J;1” and Jt : dpJRP = G R? PJL P = G L’ Especially, in the vector gauge invariant
(5.20a) (5.20b)
scheme, Eqs. (5.20) reduce to
apJ;=o,
(5.21a)
PJ; = G,( VP,A,),
(5.21b)
where JL = $(J,” + J,“) and J;1” = i(J,” -J,“). Remember that these are the currents which couple to the external gauge fields. Equations (5.21) are completely consistent with the symmetry breaking pattern of the present model such that (We recall that the Bardeen subCub),’ U(n)Rl,l,,,, + CUtn)Vx u(1),41,,,,,,. tracted term in our effective action explicitly breaks the global axial symmetry [27-291.) The conservation of the vector current JF which couples to the external photon field ensures the electromagnetic gauge invariance. The explicit breaking of the global chiral symmetry however leads to the non-conservation of the axialvector current even in the massless pion limit. As is evident from the above derivation, there is no inconsistency between the presence .of anomalies and the equations of motions for the “massive” vector and axial-vector fields. This again shows that the massive Yang-Mills theory should not be confused with true gauge theories [27]. For true gauge theories, the presence of anomaly in the source current of the gauge field cannot be consistent with the equation of motion, that is, the two equations D”j, = G and DpF,,v =j, cannot hold simultaneously unless G = 0. It might be also interesting to see what happens if we adopt the left-right symmetric regularization scheme, although we do not think that this regularization scheme is consistent with the derivative expansion with large constituent quark masses adopted in this paper for obtaining the non-anomalous part of the effective action [66]. It is well known that the anomalies in this scheme can be expressed as total derivatives of a certain functional in the following manner: GR = G(R,) = a”A,(R,),
(5.22a)
G, = -G(L,)
(5.22b)
= -PA,(L,).
NAMBU-JONA-LASINIO
MODEL
321
This means that, if we introduce the new currents by J,” E J:” - A,( R,,),
(525a)
3; = Jk + d,(L,,),
(5.23b
then they are conserved:
aflJRP = 0 ’ aq = 0.
(5.24a (5.24b
The presence of conserved currents was naturally expected from the fact that this regularization scheme preserves the global chiral symmetry. These symmetry currents however differ from the currents J,” and .I: which couple to the external gauge fields. Because of this fact, the electromagnetic gauge invariance is lost in this regularization scheme. This is undoubtedly the reason why the left-right symmetric form of the Wess-Zumino-Witten action supplemented by the vector meson dominance assumption leads to incorrect prediction for the decay amplitude
n"+2y [27]. One interesting feature of this regularization scheme is that it reproduces the low energy theorems for the amplitude K+K- -+ 37~. That is, adopting the gauged Wess-Zumino-Witten action in the left-right symmetric form, we obtain
f&K+K--
--+3x)-
= rwz,
(5.25)
instead of Eqs. (4.39) and (4.40). Thus, despite the presence of the anomalies, the low energy theorem for this purely hadronic process is intact in this scheme. This suggests the importance of respecting the global chiral symmetry in the construction of models of strong interactions. (It should be recalled however that this scheme considerably underestimates the hadronic o + 3n decay rate [27], though this is not such a process as given any constraint by low energy theorems.) Summarizing the arguments, the generalized NJL model with its axial-vector four-fermion coupling necessarily leads to a dynamical anomaly, which is not predicted by QCD [33, 34, 381. The presence of anomaly means that it is impossible to regularize the theory so as to preserve all the classical symmetries of the original Lagrangian. Adopting the vector gauge invariant regularization scheme, the electromagnetic gauge invariance is preserved but the global chiral symmetry is broken at the strong interaction level. The violation of the low energy theorems for the processes y + 3n and Kf K- + 37r seems to be related to this “explicit” (not “spontaneous”) breaking of the global chiral symmetry. On the
322
M.WAKAMATSU
other hand, adopting the left-right symmetric regularization scheme, the global chiral symmetry is preserved, but the current which couples to the external electromagnetic field is not conserved any more. It seems that we cannot escape from the above difficulties as far as we start from the generalized NJL model with its axial-vector four-fermion coupling. Then the problem again reduces to the relevance of the A, degrees of freedom in low energy effective meson theories. This is an old but still poorly understood problem [l-3]. We have already seen that the inclusion of the explicit A, degrees of freedom causes some troubles also for the non-anomalous part of the action. The problem of the strong momentum dependence of the prm coupling coming from the ,4,-n mixing effect is a typical example. (From a purely phenomenological viewpoint, this difficulty is circumvented by adding higher derivative effective action by hand.) However, we have also seen that the A, meson plays desirable roles as a chiral partner of the p meson. This happens for instance in our effective Lagrangian approach to the problem of the rr*-?I’ mass difference. The partial cancellation, between the contributions of the p meson mediated diagrams and the A,-rr mixing effects, which was observed in some anomalous processes is also a noteworthy example. It is a difficult problem to understand the reason why the A, degrees of freedom, which in some instances play preferable roles as expected from its nature as a chiral partner of the p meson, must do harm in other occasions.
6. CONCLUDING
REMARKS
Through several explicit examples, we have demonstrated that the massive Yang-Mills Lagrangians and the extended hidden symmetry Lagrangians can be thought of as two different but equivalent bosonic representations of a single quark theory, i.e. the generalized Nambu-Jona-Lasinio model. On the other hand, from the comparative analysis of the anomalous process K+K- + 3n, using both the massive Yang-Mills and hidden symmetry schemes, Scoccola et al. [3g] concluded that the massive Yang-Mills scheme is not consistent with QCD anomalies, and only the hidden symmetry scheme is acceptable as a consistent framework. The conclusions of these two researches are however not contradictory. The hidden symmetry model adopted by Scoccola et al. [38] is that of Fujiwara et al. [33], who constructed the anomalous action on the basis of the original hidden symmetry model of Bando et al. [13]. This model contains no A, degrees of freedom and is clearly different from the extended hidden symmetry model derived here from the generalized NJL model. The reason why Scoccola et al. obtained different answers in the two schemes is now quite obvious. It is simply because they are handling two different models in two different representations. It would be certainly true that among the above models only the hidden symmetry model of Fujiwara et al. is consistent with the dynamical anomaly structure of QCD. As can be learned from the work of Jain et al. [34], however, a consistent model can be constructed also in the massive Yang-Mills representation. Clearly, it is not a
NAMBU-JONA-LASINIO
MODEL
323
problem of scheme (or representation) but rather how to treat the dynamical anomaly. We believe that our demonstration here gives another support on such a viewpoint, i.e., the representation independence of effective meson theories, despite the fact that our model in either representation has its intrinsic problem in order for it to be regarded as a consistent effective theory of QCD. Probably, one of the greatest advantages of the original version of the hidden symmetry approach [ 131 (or the non-linear realization of the chiral symmetry with the vector meson [46]) is its natural possibility of introducing the p meson without including the A, meson. However, as seen from the present analysis. the microscopic (quark-level) foundation of such a construction appears highly nontrivial. Specializing to the NJL model with its four-fermion couplings, the introduction of the vector and axial-vector couplings is an inseparable operation, because of the requirement of the global chiral symmetry. Also from more general viewpoint of QCD, there seems to be no essential difference (at least conceptually) between the vector and axial-vector mesons as composite particles of a quark and an antiquark. Nonetheless, this primitive candidate (the generalized NJL model) for an effective low energy theory of QCD seems to contain an inconsistency due to the presence of dynamical chiral anomaly which is not owned by QCD Lagrangian itself. Can this deficiency be cured by the introduction of some other hadronic degrees of freedom to this simplest model so as to cancel the anomaly? Or, does it make little sense at all to consider the collective vector and axial-vector mesons which couple to quark loops? It is hoped that future studies will solve these questions on the basis of the underlying quark-gluon dynamics.
ACKNOWLEDGMENTS The author express his gratitude to W. Weise for critical reading of the manuscript and for encouraging discussions. He also thanks N. Kaiser, M. Schaden, H. Forkel, and A. Hosaka for many helpful discussions. Stimulating discussions with U.-G. MeiDner and N. N. Scoccola are greatly acknowledged.
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59s. 193.2-6