From Gauged Linear Sigma Models to Geometric Representation of WCP ( N , Ñ ) in 2 D

In this paper two issues are addressed. First, we discuss renormalization properties of a class of gauged linear sigma models (GLSM) which reduce to WCP(N, Ñ) non-linear sigma models (NLSM) in the low-energy limit. Sometimes they are referred to as the Hanany-Tong models. If supersymmetry is N = (2, 2) the ultraviolet-divergent logarithm in LGSM appears, in the renormalization of the Fayet-Iliopoulos parameter, and is exhausted by a single tadpole graph. This is not the case in the daughter NLSMs. As a result, the one-loop renormalizations are different in GLSMs and their daughter NLSMs We explain this difference and identify its source. In particular, we show why at N = Ñ there is no UV logarithms in the parent GLSM, while they do appear on the corresponding NLSM does not vanish. In the second part of the paper we discuss the same problem for a class of N = (0, 2) GLSMs considered previously. In this case renormalization is not limited to one loop; all-orders exact β functions for GLSMs are known. We discuss divergent loops at one and two-loop levels. ar X iv :1 90 7. 09 46 0v 1 [ he pth ] 2 2 Ju l 2 01 9


Introduction
In 1979 Witten suggested [1] an ultraviolet (UV) completion for CP(N − 1), one of the most popular non-linear sigma models (NLSM), with the aim of large-N solution of the latter. He considered both, non-supersymmetric and N = (2, 2) versions. In the supersymmetric case the UV completion is in fact, a two-dimensional scalar SQED with the Fayet-Iliopoulos term and judiciously chosen n fields. UV completions of this type are referred to as gauged linear sigma models (GLSM).
The target space of CP(N −1) and similar models (see below) is Kählerian 1 and of the Einstein type. Such models are renormalizable since all higherorder corrections are proportional to the target-space metric, and, therefore, are characterized by a single coupling constant. 2 Thus, geometry of the target space is fixed up to a single scale factor.
The renormalization group (RG) flow from GLSM to NLSM is smooth, no change in the β function occurs on the way. 3 Moreover, for CP(N − 1) we know the large-N solution which explicitly matches the dynamical scale following from the β function. For, say, the Grassmann model G(L, M ) (here M + L = N ) the solution is not worked out in full. However, the β functions in both regimes -GLSM and NLSM -coincide [2,3].
In [4,5,6] a generalization of N = (2, 2) GLSMs was suggested and discussed. These generalizations include a number of n fields, with signalternating charges. Of special importance is the case in which the number of positive charges N is equal to that of the negative chargesÑ . 4 In such GLSMs the Fayet-Iliopoulos parameter is not renormalized (assuming N = (2, 2)). When these GLSMs are rewritten at low energies in the form of NLSMs they give rise to the so-called weighted WCP(N,Ñ ) models. The target spaces in these cases are non-Einsteinian noncompact manifolds. Hence, these models are not renormalizable in the conventional sense of this word. 5 We will 1 More exactly, CP(N − 1) is a particular case of the Grassmann model which, in turn, belongs to the class of compact, homogeneous symmetric Kähler manifolds. 2 In (2,2) supersymmetric models the first loop is the only one which contributes to the coupling constant renormalization. In (0,2) models fermions do not contribute in the first loop, manifesting themselves starting from two loops. 3 Strictly speaking, whether this statement survives beyond one loop in models other than N = (2, 2) models is not fully known. This feature is by no means generic. 4 The general condition is i q i + ĩqĩ = 0. 5 In [7] the notion of a generalized renormalizability of any two-dimensional NLSM is presented in the form of a quantum deformation of its geometry described by the NLSM discuss these N = (0, 2) models as well. Unlike N = (2, 2) case in the (0, 2) models the second loop does not vanish in generic cases, resulting in "new" structures. (In those special cases when it does, the third and higher loops do not vansis.) In this paper we address the issue of RG running in the parent-daughter pairs GLSM/NLSM for such target spaces. Discussion of some previous results in the Hanany-Tong model [6] which inspired the current work can be found in [10]. Recently, a number of GLSMs with signalternating charges were considered, and the β functions calculated for (0,2) supersymmetric versions [9].
Our conclusions are as follows. For the class of GLSMs which upon reduction produce NLSMs of the WCP(N,Ñ ) type the RG evolution is more complicated and is not smooth. The Kähler potential (and, hence, the Lagrangian) of the resulting NLSMs consists of two parts. The first part has the exactly the same structure as the second term in the bare Kähler potential K (0) , see Eq. (3.8). Its RG evolution produces the same formula for the renormalized coupling constant r as for the FI constant in the parent GLSM. The first term in (3.8) is not renormalized at all. Moreover, a new structure emerges upon RG evolution (see the second line in Eq. (4.8)) which receives a logarithmic in µ coefficient in the RG flow, totally unrelated to that of r(µ). Thus, the RG flow for the WCP(N,Ñ ) models is not described by a single running coupling constant. The number of the emergent structures will grow in higher loops in the non-supersymmetric case (see (8.4)), so that these NLSMs are not renormalizable in the conventional sense of this word. Is the number of the emergent structures is limited in N = (0, 2) supersymmetry? The answer to this question can be found in Sec. 9.
The paper is organized as follows. In Sec. 2 we briefly outline the GLSM formalism and renormalization of the FI constant under the RG evolution. Section 3 is devoted to reduction to NLSMs of the WCP(N,Ñ ) type. We derive geometry of the target space: metric, Riemann and Ricci tensors, scalar curvature, etc. In Sec. 4 we consider RG evolution in the WCP(N,Ñ ) models. Distinct structures responsible for different effects are isolated and a general result is formulated. Section 6 presents the simplest example of WCP(1, 1) for illustration. In Sec. 7 we work out the N = (0, 2) versions of the WCP(N,Ñ ) models.
metric. By nonrenormalizability we mean a more traditional definition that generally speaking an infinite number of counterterms is needed to eliminate all ultraviolet logarithms. A thorough discussion of geometrical properties to be used below can be found in [8].

General Construction
We start from presenting the bosonic part of our "master" model; its versions will be studied below. First, we introduce two types (or flavors) of complex fields n i and ρ a , with the electric charges +1 and −1, respectively, The index i runs from i = 1, 2, ..., N while a = 1, 2, ...,Ñ . The action above is written in Euclidean conventions. The parameter r in the last term of Eq.
The U(1) gauge field A µ acts on n and ρ through appropriately defined covariant derivatives, 6 reflecting the sign difference between the charges. The electric coupling constant e 2 has dimension of mass squared. A key physical scale is defined through the product m 2 V = e 2 r .
If e 2 → ∞ all auxiliary fields (i.e. D and σ) can be integrated out, and we are in the NLSM regime. All terms except the kinetic terms of n and ρ disappear from the action, while the last term reduces to the constraint However, if the normalization point µ 2 m 2 , the appropriate regime is that of GLSM. The parameter r is the only one which is logarithmically D n, ρ This renormalization vanishes if N =Ñ due to cancellation of charge +1 and −1 fields. Now we proceed to the discussion of the NLSM regime.

Geometric formulation of WCP(N,Ñ )
To derive the geometric formulation we must take into account that the constrain (2.5) and the U(1) gauge invariance reduce the number of complex fields from N +Ñ in the set {n i } + {ρ a } down to N +Ñ − 1. The choice of the coordinates on the target space manifolds can be made through various patches. For the time being we will choose one specific patch. Namely, the last ρ in the set {ρ a } (assuming it does not vanish on the selected patch) will be denoted as ρÑ = ϕ , where ϕ will be set real. Then the coordinates on the target manifold are Note that the variables introduced in (3.2) are not charged under U(1).
7 Equation (2.6) assumes that r is positive and N ≥Ñ . IfÑ > N one should consider negative r.
On the given patch ϕ can be expressed in terms of the above coordinates as The shorthand in Eq. (3.4) will be used throughout the paper. Integrating out the gauge field we observe that Now we are ready to present the geometric data of the target space for WCP(N,Ñ ) in the following form: with the inverse This result can also be recovered by differentiating the corresponding Kähler potential 8 which was previously found in [10,11]. We will consider the Kähler potential (3.8) and its one-loop correction in more detail in the next section. For the time being, let us move on to further discuss geometry of this target space.
To this end, we first find the metric connections, , Then the Ricci tensor takes the form According to (3.10), the target space is not an Einstein space. Furthermore, the scalar curvature is Equation (3.11) implies that H is a function of scalar curvature and parameters N,Ñ and r, say H = H(R, r, N,Ñ ). Note that setting N equal to zero and r negative, we should be able to recover all well-known results in CP(Ñ − 1) model. Indeed, all non-Einstein terms in Eq. (3.10), the last line, vanish because r + H = 0 (and so do the non-Einstein terms in the second and third lines, because we must put all term with z i to zero in (3.10)). Then the coefficients of the Ricci and scalar curvature also match, namely, with r < 0. Next, we observe that the general theory of NLSMs implies at one loop (see e.g. [7]) (3.13) where {φ p } is generic coordinate of the target space. The question we will address now is the relation between two results: Eq. (2.6) in GLSM and Eq. (3.10) in NLSM. Both expressions mentioned above are known in the literature, (for (3.10) with a particular choice of N,Ñ see e.g. [10]). Clarification of their relationships is our starting goal.

Renormalization in GLSM vs. NLSM
In this section, we will study the renormalization of WCP(N,Ñ ) model in the NLSM regime, and trace its origin from the parent GLSM. First of all, to discuss the renormalization structure, it is convenient to rephrase the previous results in terms of the Kähler potential.
For a Kähler manifold endowed with the Kähler potential K(φ p ,φq), the metric is determined by the relation while other components vanish. The corresponding Ricci tensor is given by where g represents the determinant of the metric tensor, If this manifold admits an Einstein-Kähler metric, the Ricci tenosr is propotional to its metric, in other words, for some constant α. Yet, our case does not belong to this class. Back to our model, we can recover the result (3.6) by using (3.8) and (4.1). For convenience we will represent it in a different form, In the above formulas for the metric tensor (they are identical to (3.6)) we separate the contributions from H and 2r log ϕ, respectively, in the Kähler potential K (0) , namely, the terms marked by underbrace originate from 2r log ϕ in Eq. (3.8). From the expression (3.6), the metric determinant can be calculated in a straightforward manner, and we obtain for which the result coincides with the example in [10] with a particular pair of N,Ñ . As a consistency check, we can apply (4.2) to (4.6) to see that it indeed reproduces (3.10). Also, it is instructive to explicitly indicate the Einstein part and non-Einstein part in the Ricci curvature. Namely, At one-loop level, the Kähler potential acquires a correction following from (4.6), see also (4.7), The correction of the coupling constant, r, and the log H term result from the first and the second terms in Eq. (4.6), respectively while the corrections to H term cancel. As a consistency check, considering the CP(Ñ − 1) case (N = 0), we observe that H reduces to a constant and and dropping all H terms we observe that the Kähler potential renormalizes multiplicatively. We recover the conventional CP(Ñ − 1) result. We can immediately read off from Eq. (4.8) that the FI parameter is renormalized as 9 in agreement with (2.6) obtained in the GLSM analysis.
As an essential example, we consider the model with the equal numbers of positive and negative charges. Then, as shown in (4.9), the FI parameter gets no correction and the corresponding β function vanishes. However, the Kähler potential is still modified by the one-loop contribution, The emergent term proportional to log H does not vanish even if N =Ñ , therefore making the theory non-renormalizable (in the case of N = (0, 2) supersymmetry, see Sec. 7). Note that in the generic case N =Ñ but N ∼Ñ the renormalization of r scales as N while the coefficient of log H is O(N 0 ). Then the latter can be ignored in the large-N limit. 5 Where does the discrepancy between GLSM and NLSM come from?
The answer to the above question might seem paradoxical. Let us return to Sec. 2.1 in which it was stated that the only ultraviolet logarithm in GLSM comes from the Fayet-Iliopoulos term renormalization depicted in Fig. 1. This statement is correct. However, this does not mean that there are no other logarithms in this model (with is a two-dimensional reduction of SQED with matter fields possessing opposite charges). If we descend down in µ below m V (see (2.4)), we will discover logarithms of m V /µ rather than log M UV /µ. The former in a sense might be called "infrared." They come from the Z factors of the matter fields in (2.1) and are determined by the graphs shown in Fig. 2.
On dimensional grounds the one-loop contribution to the Z factor is proportional to It is curious that the same type of "infrared" logarithms were found 45 years ago [12] in weak flavor-changing decays and are widely known now as penguins. They are typical of theories with multiple scales. In passing from GLSMs to NLSMs we tend m V → ∞ thus identifying it with M UV . The distinction between two types of logarithms are lost.
We conclude that the Fayet-Iliopoulos parameter is related -in the NLSM formulation -to the cohomology class of the Kähler form of the target space generically defined as where d is the de Rham operator. 10 Speaking in physical terms, the Kähler class can be viewed as a product of a complexified scale parameter r and an analog of the appropriately normalized topological (or θ) term. The latter takes integer values. These remarks explains the structure of the first line in Eq. (4.8), as well as the emergence of extra logarithms. That's why in GLSM we recover Eq. (4.9), inherited from GLSM, in addition to an "extra" last term in the first line of Eq. (4.8).
6 The simplest example: WCP(1, 1) model To further illustrate our analysis, let us have a closer look at the minimal example consisting of only two chiral fields, one with the positive unit charge and the other with the negative unit charge (i.e. N =Ñ = 1). Also, the appropriate number of fermi superfields can be included, so we can consider either N = (2, 2) or N = (0, 2) theories. The bare Kähler potential in this problem is presented in [14], Sec. 52.
Note that in the given simplest case First of all, let us examine the structure of the vacuum manifold in the corresponding GLSM, |n| 2 − |ρ| 2 = r .

(6.2)
This space is simply a four-dimensional hyperboloid. Gauging out a U (1) phase we arrive at a two-dimensional target space in WCP(1, 1) (two real dimensions). Indeed, ρ in Eq. (3.1) can be chosen to be real and positive, then so is ϕ. Using the choice of coordinates in (3.1) and (3.2), we can reduce (6.2) to illustrated in Fig. 3. From the graph, we see that the singularity at ϕ = 0 is one and the only one sigular point on this patch. However, considering z andz as coordinates, we observe that becomes zero at the origin, the point which must be punctured on the given patch. The constraints imposed on the fermion fields are of the typē which implies that the fermions live on the tangent bundle of the target manifold, see Sec. 7. Following the same line of calculation as in Sec. 3, we obtain the only non-vanishing element of the metric Its connections are , and Γ1 11 = − 2z r 2 + 4zz . (6.7) In addition, it is not difficult to the curvature tensor, (r 2 + 4zz) 5/2 (6.8) and the Ricci tensor, (6.9) From (6.6) and (6.9), we can explicitly see that the Ricci tensor is not proportional to the metric, and this is consistent with the fact that the target manifold is not of the Einstein type and our general analysis of Sec. 4. The scalar curvature is also computed, it reduces to Now, it is time to talk about the quantum correction of this model. That is, the β function is computed as follows.
β(g 11 ) one−loop = r 2 π (r 2 + 4zz) 2 . (6.11) For N = (2, 2) case, this is the end of story. However, for a non supersymmetric model, it is not the case, i.e. it still receives the two-loop correction. Namely, β(g 11 ) two−loop = r 2 π (r 2 + 4zz) 2 1 + r 2 2π (r 2 + 4zz) 3/2 , (6.12) see Sec. 8 for various N = (0, 2) models. In this simplest example the Lagrangian (including one loop) can be written as follows: where H is given in (6.1). The first term on the right-hand side represents the bare Lagrangian which is not renormalized (remember that in the case at hand N =Ñ = 1). The second term emerges at one loop -a different structure proportional to log µ which is absent in the UV. It can be ignored at large |z|.
As an aside, if we take the U (1) charges of two chiral superfields to be q and −q, the geometry of the target space does not change, but only the scale r from the FI term rescales as r/q. For example, (r/q) 2 + 4zz . (6.14) 7 Generalization to N = (0, 2) WCP(N,Ñ ) The N = (0, 2) deformation discussed in this section was introduced in [9]. With the fermion fields taken into account, we can work out in this paper heterotic supersymmetric versions. As suggested in [15,16], we construct N = (0, 2) GLSM with the gauge multiplet, fermi multiplets, and two types of the boson chiral superfields with U (1) charge +1 and −1.
Before proceeding to the invariant action, we recall the superfield representation for each multiplet. In this case, two chiral multiplets are the gauge multiplet is and, lastly, the fermi multiplets are Now, we are allowed to present the full expression of N = (0, 2) extension of the key model, which is non-minimal The covariant derivative for χ −M field is defined though its U (1) charge, q M , such that Note that σ field is suppressed preserving (0, 2) supereymmetry. Also, we notice that G M is an auxiliary field.
In NLSM regime, the gauge multiplet becomes auxiliary (all kinetic terms vanish in e 2 → ∞ limit), so the corresponding component fields (i.e. σ, λ − , and D) can be integrated out to give the constraints. To be more precise, D term again results in Eq. (2.5), and gauginos yield where the same condition applies to its hermitian conjugate.
To obtain the geometric formulation of N = (0, 2) WCP(N,Ñ ), we follow the parallel treatment in section 3 to eliminate U (1) redundancy by setting in which ϕ is a real field and κ + is a complex Weyl fermion. Notice that Ñ is assumed to be nowhere vanishing on the chosen patch. On the target manifold, bosonic coordinates are defined in the same way as Eq. (3.2) while the fermionic coordinates are ζ +,i = κ + n i + τ +,i ϕ for i = 1, 2, ..., N , η +,a = 1 ϕ ξ +,a − ρ a ϕ κ + for a = 1, 2, ...,Ñ − 1 . This can be seen by taking the following parametrization for superfields On this patch ϕ has the identical expression as Eq. (3.3) and κ + is written in terms of the above coordinates by Integrating out gauge fields we then find that where As a remark, these coefficients can also be related to the connection associated with χ M fields (see Eq. (7.17) with ∂ ++ replaced by the exterior derivative d) in the way Next, we present the final expression of the geometric formulation of N = (0, 2) WCP(N,Ñ ) by collecting above ingredients. 14) The covariant derivative in (7.14) for chiral fields is defined as where {φ p } and {ψ p } are generic coordinates on the target space, say, {z i , w a } and {ζ +,i , η +,a }, respectively and Γ p qs is defined in Eq. (3.9) while for fermi multiplet, it is shown that with Two remarks are in order here. First, we may wonder whether it is possible to enhance supersymmetry in (7.14) up to N = (2, 2) under an appropriate choice of parameters. The answer is negative. This can be traced back to the original construction of the gauged formulation, Eq. (7.4). Evidently, the kinetic term of the left-handed fermions, τ + and ξ + (corresponding to ζ + and η + ), respectively, does not match that for the right-handed fermions χ −M . In addition, interactions of these fermions are different. These two facts block the possibility of finding N = (2, 2) models in the class of N = (0, 2) models considered in this section. However, we will see that once the anomaly-free condition is met, the two-loop term in. the β function vanishes much in the same way as in N = (2, 2), see Sec. 9 for more details.
Second, in accordance with [9,19], we need to impose the constraints on the representation of the chiral and fermi multiplets for the theories to be free of the gauge anomalies, which implies their internal quantum consistency. Namely, where the U (1) charges on the left-hand side come from the (left-handed) fermions in the supermultiplets N i and a while those on the right-hand side are from the (right-handed) fermi multiplets.
To wrap up this section, the geometry of the target manifold is identical to that obtained from the bosonic calculation, cf. Eq. (3.6) and (3.9) - (3.11), at the classical level. Since the fermion fields play no role in one-loop renormalization, the FI parameter and the Kähler potential receive the same corrections at the first order as discussed in the previous section. Making one step further, we will show in the next two sections that the N = (0, 2) case have no correction at the two-loop level.
8 More on geometry of WCP(N,Ñ ) As a complement to the discussion of WCP(N,Ñ ) target manifold carried out above, here we will present the Riemann curvature tensors needed for the second loop to be obtained in Sec. 9.
For a generic Kähler manifold, the Riemann curvature tensor can be written as implying Riemann tensors, This combination can be obtained by a tedious although straightforward calculation. Extensively employing (3.7) and (8.2) we derive One can easily verify the above expressions in two simple limiting cases. First, we consider the CP models and, then, the simplest example N =Ñ = 1 discussed in Sec. 6. To reduce the generic case to CP(Ñ −1), we should again take N = 0 and r negative, arriving at On the other hand, addressing the WCP(1, 1) model, we set N =Ñ = 1 and obtain cf. Eq. (6.12). As is seen from Eq. (8.4), more and more structures emerge in higher order corrections. In comparison with the one-loop results in which only terms up to H −4 show up at two loops we find additional H −5 to H −7 terms. It is not possible to absorb them in g pq . This illustrates our statement of non-renormalizability of non-supersymmetric Hanani-Tong model.
Similarly to the N = (2, 2) case, the two-loop correction does not exist in N = (0, 2) sigma model since the imposition of (7.18) will lead to a vanishing coefficient in front of of the second order term in the beta function.

Second loop
Let us explore the renormalization of WCP(N,Ñ ) in higher loops. For a given bosonic two-dimensional non-linear sigma model, the first two terms in the β function are known in the general form (see e.g. [17]), namely, where the first term is nothing but the Ricci tensor and the following term represents the second power of the Riemann tensors, see Eq. (8.4). Note that in Eq. (9.1), the term proportional to the Ricci curvature stands for the one-loop correction while the second term composed of the square of the Riemann tensors relates to the two-loop calculation. The discussion of the first order renormalization is presented in Sec. 4. Now we will briefly outline what happens in the second order. ζ, η, χ ∂z, ∂w In the N = (0, 2) model we consider the two-loop fermionic contribution shown in Fig. 4. If we work in the vicinity of the origin on the given patch and keep only the lowest order terms, this is the only relevant diagram. Then, it is easy to see that In the above equality we employ the anomaly-free condition (7.18), see [9] for details. It is important to stress that we should take the coefficient in front of the the fermion contribution to R (2) pq to be −1/(16π 2 ) in the minimal N = (0, 2) model [18]. The reason is that the fermion graph in Fig. 4 contributing at two loops acquires an extra factor 1/2 in passing from the Driac to Weyl fermions.
Returning to the anomaly-free non-minimal N = (0, 2) model we observe that the second order contributions from bosonic and fermionic fields cancel each other, and thus the second order coefficient vanishes.
Indeed, if we neglect for a short while the N andÑ dependence in Eq. (9.2), the fermionic two-loop correction reduces −1/8π 2 . Together with the bosonic part in (9.1), we obtain the second order coefficient leading to the same result as in N = (2, 2) model, in which only the first loop survives as a result of a non-renormalization theorem. The two models above are expected to have different contributions starting from three loops. The remaining question refers to the overall factor N +Ñ in Eq. (9.2). In the latter equation it was obtained by examining the vicinity of the origin of the given patch. Now we will have a closer look at the general form of R (2) pq near the origin starting from (8.4). It is important that in the vicinity of the origin of the origin H → r and therefore Proportionality of R (2) pq to the overall N +Ñ factor near the coordinate origin is obvious in the above expressions.
In addition, we can compare with the results in [9] (see Eq. (4.10)). Generally speaking, the β function in our notation has the form where γ α and γ M are the anomalous dimensions of the chiral multiplets and the fermi multiplets, respectively. Also, the coupling constant g is linked to the FI parameter through the relation r = 2 g 2 . (9.7) Perturbatively, to obtain the two-loop β function, we only need γ at the one-loop level, and we know that Since this formula is universal, it is good enough to consider a simple example discussed in [9], in particular, N = (0, 2) CP(N −1) model. In this case, there are N chiral fields with positive unit charge and the same number of fermi multiplets with the same charge as that of chiral fields. As a consequence, the second term in (9.9) vanishes and only the one-loop effect survives, namely, β(g 2 ) two−loop = − N g 2 4π . (9.10) A similar argument can also be applied to the entire particular class of the N = (0, 2) WCP(N,Ñ ) models without internal anomalies which we consider in this paper. To proceed, let us first note that the anomaly-free condition (7.18) in this model again forces the left-handed fermions to "pair up" with the right-handed ones as is the case in N = (2, 2) models. We can specify a particular choice for the set of q M s such that N of them have the U (1) charge +1 and the restÑ fields have the U (1) charge −1. Then, Eq. (9.9) further reduces to i.e. the two-loop contribution vanishes in much the same way as we have seen in the CP(N − 1) case.

Conclusions
In this paper, we studied the structures of a particular NLSM derived from a class of GLSM and its N = (0, 2) family. The geometry of such NLSM is a weighted complex projective space, WCP(N,Ñ ), where N andÑ stand for the number of fields with the opposite U (1) "charges". This non-compact Kählerian manifold does not admit a Kähler-Einstein metric which leads to emergence of extra structures and two different types of logarithms. Renormalization of the Fayet-Iliopoulos in GLSM and that of the Kähler class in NLSM coincide. However, there are additional logarithms in NLSM.