The $\mathcal{N}=3$ Weyl Multiplet in Four Dimensions

The main ingredient for local superconformal methods is the multiplet of gauge fields: the Weyl multiplet. We construct the transformations of this multiplet for $\mathcal{N}=3$, $D = 4$. The construction is based on a supersymmetry truncation from the $\mathcal{N}=4$ Weyl multiplet, on coupling with a current multiplet, and on the implementation of a soft algebra at the nonlinear level, extending su$(2, 2|3)$. This is the first step towards a superconformal calculus for $\mathcal{N}=3$, $D = 4$.


Introduction
In supergravity it is often a non trivial exercise to construct theories in which gravity multiplets are coupled to matter multiplets, so called matter-coupled supergravity theories. The most systematic approach that has been used for such constructions is the superconformal method. In this method one starts with a supergravity theory that has additional conformal symmetries. The multiplet of gauge fields in these theories is called the Weyl multiplet. This forms the background for general superconformal-invariant interactions of matter multiplets. The superconformal symmetry is then broken to super-Poincaré symmetry [1]. This procedure is a far easier task than constructing a Poincaré supergravity from scratch. Furthermore, the extra symmetries in conformal supergravity also offer a systematic approach to the construction of the matter couplings and reveal much of its structure. This superconformal method has therefore been used extensively in the past for different supergravity theories in multiple dimensions and number of supersymmetries. The Weyl multiplet is also the basis for constructing conformal supergravity theories, which are theories with higher derivatives. E.g. recently the N = 4 conformal supergravity theories have been studied in [2,3].
An old argument says that N = 3 rigid supersymmetry theories always have a fourth supersymmetry, and hence are in fact N = 4 supersymmetric theories. This is based on theories that have an action with a σ-model for the scalars. For every supersymmetry added to the N = 1 case one needs an additional parallel complex structure, see [4,5] for a more detailed discussion on this fact. Consequently, for N = 3 theories one needs two of such structures. However, similarly as for the complex numbers, two complex structures automatically lead to a third one. This then immediately results in a theory that has four supersymmetries. Another argument for the non-existence of N = 3 supersymmetric theories that are not N = 4 theories comes from the analysis of multiplets of massless states. The irreducible representations with maximal spin 1 carry either helicities (1, 3×1/2, 3×0, −1/2) or (1/2, 3 × 0, 3 × −1/2, −1). Both separately are not CPT invariant. To ensure CPT invariance, one should join both representations. The field content is then that of an N = 4 theory. The kinetic action that one can construct with at most 2 spacetime derivatives shows that indeed the fourth supersymmetry is always present. Recently, however, a completely new approach has been taken to look at four-dimensional N = 3 theories, which has taken quite some interest from the community [6][7][8][9][10][11][12][13]. These approaches do not rely on the usual Lagrangian philosophy and use techniques originating from holography to discover new physics in these theories.
This inclusion of N = 3 in N = 4 does not hold for supergravity. In that case other representations, going up to spin 2 distinguish N = 3 from N = 4. The structure of the N = 3 and N = 4 supercurrents and their relation to N = 6 supergravity in 5 dimensions was considered in [14]. A superspace approach to conformal supergravity for N ≤ 4 has been given in [15]. Poincaré supergravity-matter couplings with N = 3 in four dimensions have been considered for their representation content [16], in (harmonic) superspace [17,18] and using the group-manifold approach [19]. 1 However, it was never done using the superconformal method. It can be expected that these methods will result in the same theory for the supergravity obtained by promoting 3 of the 4 rigid supersymmetries in the N = 4 supersymmetric σ-model. In any case the superconformal construction of N = 3 Poincaré supergravity theory may shed more light on the structure of these theories whose solutions were recently studied in the context the AdS/CFT correspondence [21,22]. Also the alternative N = 3 theories mentioned above may be studied with superconformal methods.
The first step in this programme is constructing the Weyl multiplet. In fact, a separate motivation for the construction of the Weyl multiplet is that it seems to be the final gap in the construction of gauge multiplets of conformal supergravities. These theories have been constructed for all the possible superconformal groups in dimensions varying from D = 2 to D = 6. It is proven using an algebra argument by Nahm in [23] that no superconformal algebra exists in higher dimensions. 2 Much work has been done to find the Weyl multiplets in different dimensions and with a different number of supersymmetries, see e.g. [25]. In two dimensions the possibility for Weyl multiplets has been discussed in [26,27]. In three dimensions the different multiplets are discussed in [28][29][30]. An off shell formulation of the possible Weyl multiplets in three dimensions was given in [31,32]. In four dimensions the Weyl multiplet for N = 1 has already been found in [33]. For N = 2 it was found in [34] and for N = 4 in [35]. It was shown in [36] that no Weyl multiplets exist beyond N = 4. For five dimensions only N = 2 appears in Nahm's classification, and the corresponding Weyl multiplets were found in [37,38]. The Weyl multiplets in 6 dimensions were constructed for (1, 0) supersymmetry in [39] and for (2,0) in [40] and these are the only cases that appear in the classification of Nahm. We would like to note that the given list of papers discussing the construction of Weyl multiplets and conformal supergravity theories is far from complete. Very interesting work on the subject has been done since the original multiplets were constructed. However, the goal of the given list is merely to present a short overview of the original works concerning the Weyl multiplets in different dimensions. For the case of N = 3 conformal supergravity in four dimensions suggestions have been made for the field content of the Weyl multiplet [41,42]. The actual derivation of the full symmetry transformations, however, has never been done.
Before discussing the explicit content of this paper we will give a small introduction into some general features of the Weyl multiplets in four dimensions. The Weyl multiplet is a massive multiplet with maximal spin 2. For every spin, the fields of massive multiplets form representations of USp(2N ) [43,44]. These are given in Table 1. The explicit SO(3, 1) × SU(N ) representations known in four dimensions will be discussed in Section 3.2 in more detail.  We have constructed the Weyl multiplet for N = 3 conformal supergravity and found the nonlinear supersymmetry transformations of the fields in the multiplet. The applied method resulted in one Weyl multiplet. However, in other dimensions and with a different amount of supersymmetries it was found that there are several Weyl multiplets. Future work will have to determine if this is also the case for the N = 3 theory in four dimensions. The constructed Weyl multiplet consists of 64 + 64 fermionic and bosonic components. The supersymmetric algebra applied on this representation resulted in a consistent soft algebra as is usually the case for gauged supersymmetric theories.
Previous research in the subject has often made use of the so-called method of current multiplets [45,35,46]. This method requires a rigid supersymmetry theory at the outset. Because there is no known N = 3 rigid supersymmetric field theory we have applied a threestep procedure. The first step in this method consists of consistently truncating the N = 4 current multiplet of the N = 4 Maxwell multiplet, obtained in [35], to three supersymmetries.
In the second step, similar to the case of N = 4 conformal supergravity, the Weyl multiplet is found by coupling a field to every current. By imposing invariance of the first order action (which consists of the current × f ield terms) one is able to derive the linear supersymmetry variations of the fields in the Weyl multiplet, starting from the variations of the currents. These transformations have then been checked for consistency with the symmetry algebra su(2, 2|3). In the third step, the nonlinear supersymmetry variations are found by taking a general ansatz for the nonlinear terms and checking for consistency with the soft algebra, the chiral weights and the conformal weights of the fields. This paper is organized as follows. In Section 2 we recapitulate the already known Weyl multiplet for N = 4 conformal supergravity and its construction using the current method.
The truncation to N = 3 conformal supergravity will be discussed in Section 3. This will lead to the representation of the gravity multiplet (Weyl multiplet) for su(2, 2|3). The Rsymmetry group will break from SU(4) into U(3). The truncated Weyl multiplet, as already mentioned, consists of 64 + 64 independent components while the N = 4 multiplet consists of 128 + 128 independent components. A comparison of all the known Weyl multiplets in four dimensions is given in Section 3.2.
In Section 4 we will give the explicit linear and nonlinear supersymmetry variations of the N = 3 Weyl multiplet and discuss the method used to find them. The nonlinear variations are discussed in detail in 4.2. An important part of this derivation leads to the structure of the soft algebra of the theory, which is a modification of the algebra su(2, 2|3). Such soft algebras contain structure functions depending on the usual infinitesimal parameters as well as on the fields present in the Weyl multiplet itself.
Finally, in Section 5 a discussion of the found results will be given. Appendix A discusses some of the conventions and identities that have been used throughout the paper.

The N = 4 Weyl Multiplet and the current method
The content of the N = 4 Weyl multiplet was given in [47][48][49] and the transformation rules were fully constructed in [35,50]. The method used was the so called supercurrent method. The philosophy is to start with a rigid supersymmetric theory and perturb the theory around flat space. In this sense one splits the Lagrangian of the theory in a zeroth order and a first order part: The zeroth order Lagrangian contains the kinetic terms of the rigid supersymmetry theory and the first order part contains the coupling of the currents with the fields in the multiplet. This first order coupling uniquely determines as well the content of the Weyl multiplet as its linear supersymmetry variations. We will recapitulate this construction of [35] in Section 2.2. The nonlinear variations are determined by consistency with the appropriate algebra. This is discussed in Section 2.3.
The rigid supersymmetric theory from which the N = 4 Weyl multiplet in four dimensions was constructed is the unique N = 4 SYM (super-Yang-Mills) theory that was introduced in [51]. Section 2.1 will summarize the field content of this theory.

The rigid N = 4 SYM multiplet
The rigid N = 4 super-Maxwell theory contains a gauge field B µ , which is an SU(4) singlet, four fermions ψ i , in the SU(4) vector representation and six scalars, ϕ ij = −ϕ ji , combined in the 6 representation of SU(4). The Latin indices denote the representation of the fields with respect to this SU(4) R-symmetry group and run from 1 to 4. We use chiral spinors ψ i = P L ψ i and their complex (or charge) conjugates ψ i = P R ψ i . We use the notations from [52] to indicate the chiralities. The scalar fields obey the following reality relations Instead of using the vector B µ we will often rather use its field strength, or even better the (anti-)selfdual parts of this tensor: The Lagrangian is given by which is conformally invariant, using the coordinate transformations with and intrinsic dilatation transformations 3 On top of that, it is invariant for the following supersymmetric variations ( i = P L i and (2.7) The action is invariant under rigid superconformal transformations, which means that i can be linear in the spacetime variable x µ : where i 0 and η i = P R η i are constants. The superconformal transformations satisfy the superconformal N = 4 algebra, which includes su(4) R-transformations with an anti-hermitian traceless parameter λ i j . These transformations satisfy the algebra su(2, 2|4). The general form of the superconformal algebra su(2, 2|N ) has been found in [53] for general N . It is generated by the standard conformal generators of su(2, 2), together with supersymmetry generators (Q i = P R Q i and Q i = P L Q i ), special supersymmetry generators (S i = P L S i and S i = P R S i ) and the (s)u(N ) R-symmetry generators U i j (and T ). The non-trivial commutation relations are as follows: Remark that the U(1) generator T is optional 4 for N = 4. It does not appear at the righthand side of (2.10). This implies that representations of the N = 4 superconformal algebra may or may not have such chiral transformations. One can check that the supersymmetry variations of the SYM multiplet in (2.7) constrain the chiral weights of i and i in that representation to be zero. However, if we omit B µ and take instead F ± µν as independent field, then consistent chiral weights can be assigned. These chiral transformations [35,14,54] will play an important role in this paper. The Weyl multiplet of N = 4 is a representation of SU(2, 2|4), i.e. the fields do transform under the T symmetry. We will leave this aside for the moment, and will come back to this symmetry at the end of Sec. 2.2.
The translations are realized on the fields of the super-Maxwell multiplet as derivatives P µ = ∂ µ , except on the gauge field, where they act as covariant translations: P µ B ν = F µν . The generators are related to transformations with parameters as In this way, the last anticommutator in (2.10) e.g. implies The superconformal symmetries are rigid symmetries, but the U(1) gauge transformation of B µ is local. Similar to other supersymmetric gauge theories, one then finds soft algebras. This means that the commutator relations of (Q and S) symmetries lead to U(1) transformations with parameters dependent on the fields inside the multiplet itself. 5 One finds that the supersymmetry commutator acting on the gauge field B µ gives the following result: where λ U(1) is the gauge parameter and the x-dependence of (x) is given in (2.8). This gauge parameter is now dependent on the fields in the multiplet, explicitly one has that (2.14) One can check that the supersymmetry variations given in equation (2.7) are consistent with the algebra given in (2.10) plus the mentioned gauge parameter term. Using the Noether procedure, the stress energy tensor, supercurrent and R-symmetry currents are found from the Lagrangian: These currents are, as usual, only determined modulo equations of motion of the matter fields in the SYM multiplet. These equations of motion are given by The stress energy tensor is improved such that it is symmetric and traceless. 6 Furthermore, current conservation and conformal symmetry tells us that The last two equalities are a consequence of the conformal symmetry, and can be verified from (2.15) using (2.16).

The N = 4 Weyl multiplet and its linear variations
We are now able to apply the supersymmetry variations of the SYM multiplet to the currents that were found. We will find that to close the superalgebra on the Noether currents new (matter) currents have to be introduced. The full multiplet of currents will then give rise to the Weyl multiplet and its linear supersymmetry variations, as will be explained in more detail below. The variation of the stress energy tensor is given by 7 This is something that could be expected since it says that the graviton and gravitino are related through supersymmetry variations. However, when the supersymmetry current is varied one finds something new, namely: Here t µνij is the first current not associated to a symmetry. Its explicit form in terms of the SYM multiplet is given by 8 The rest of the currents in the supercurrent multiplet are found by consecutively applying these supersymmetry variations. This procedure will result in five more currents associated to matter fields. In terms of the SYM multiplet these new currents are given by They satisfy the following conditions The explicit supersymmetric variations of the currents are given by One can check these by applying the known variation of the N = 4 SYM multiplet to the currents, which are themselves nonlinear combinations of the SYM fields. The lowest weight field in the multiplet is the d-current, which is in the 20 representation of the SU(4) R-symmetry group. Therefore, the multiplet is said to be in the 20 representation of SU (4).
With the extra matter-currents the number of fermionic and bosonic components are equal, which is a necessary condition for linearized supersymmetry.
The gravity multiplet is found by coupling each of the currents to a corresponding field in the Lagrangian. This field will either be a gauge field or a matter field, depending on whether the current is related to a symmetry or not. In the explicit form of the coupling of currents to fields of the gravity multiplet we choose normalizations for the gauge/matter fields that are convenient for comparison with [35]: In the current multiplet we saw that the d-current had the lowest weight. In the Weyl multiplet this means that the D-field will have the highest weight and is also in the 20 representation of SU(4). The invariance requirement of the action leads, using the representation properties of these fields in Table 2 and (2.22), to the following linear variations of the fields where ξ µ , λ j i , i , λ D and η i are undetermined due to the constraints (2.17). This leads to symmetries of the gauge fields. Furthermore we used in (2.25) which transforms under the η symmetry in the δψ i µ as δφ i µ = ∂ µ η i .
In order to promote these transformations to the transformations of the gauge fields of the superconformal algebra, one interprets h µν as the first order perturbation of the frame field: which needs a compensating Lorentz transformation parametrized by λ ab since h µν was defined to be symmetric, and e a µ is defined without a symmetry. We introduce then the customary composite field which in first order reduces to Gauge field Properties SU(4) repr. Weyl weight Chiral weight This is thus the gauge field of the symmetry parametrized by λ ab , and the first term of the gravitino transformation in (2.25) can then be written as When we consider then the gauge transformations in the first line of (2.25), the ξ µ transformation can, up to a λ ab transformation, be written as δe a µ = ∂ µ ξ a . The dilatation transformation is the first order in (2.31) We explicitly introduce a gauge field b µ with δ D (λ D )b µ = ∂ µ λ D in the theory. This gauge field however caries no degrees of freedom. The reason is that it is the only field that transforms under the special conformal symmetries. Specifically a special conformal transformation will only cause a shift in the b µ field: In order to have a covariant ω µ ab under the local transformations (2.31), we have to use The covariantization of the gravitino transformations further requires that the ∂ µ term is combined with a b µ term. The linear transformation of the gravitino is therefore The two additions with b µ terms sum up to an extra term 1 2 γ µ / b i . Therefore, this is of the form 9 of the undetermined η term in (2.25) and thus does not invalidate the previous results. Hence we can include b µ in the set of fields, including also the special conformal transformations. 10 At this time, we can identify the independent fields e a µ , ψ i µ , V µi j and b µ to gauge fields of the superconformal algebra (2.10) (for N = 4 and without the T symmetry) according to Table 3. The composite fields (2.33), (2.26) and From the point of view of the final results this reflects the commutator

Transformation
Generator Parameter Gauge field Independent components provide the (linearized) gauge fields for the other superconformal symmetries. These composite fields can be understood as resulting from constraints on curvatures of the full superconformal algebra: So far, we used only the linearized form of these constraints, but further on we will use these constraints to complete (2.33), (2.26) and (2.35) at the nonlinear level. The hats on top of the curvatures imply that they are then dependent on the matter fields in the multiplet as well. The way that one determines these curvatures and the gauging of the Poincaré group is explained in more detail in [52, chapter 11]. A discussion on the curvature constraints is given in chapter 16 of the same book. Later on we will come back to the curvatures and give explicit expressions when we reduce to the N = 3 Weyl multiplet. An important motivation for the constraints is that they reconcile general coordinate transformations with gauged translations.
For the independent fields, the linearized transformations are in (2.25), with the completion (2.34) and h µν is replaced by e a µ and b µ , which transform under supersymmetry as All the variations of the gauge fields are now consistent with what one would expect from a gauge theory, i.e.
for the algebra of the PSU(2, 2|4) symmetry group. This also implies transformations under S-supersymmetry, dilatations, Lorentz and SU(4) transformations. All the currents, together with their respective gauge/matter fields, chiral and Weyl weights, are listed in Table 2. This contains also chiral weights. To explain these we should now come back to the remark after (2.10), namely that the original SYM multiplet did not have assigned chiral weights. It was mentioned that the T symmetry for N = 4 is not part of the simple group PSU(2, 2|4). So far it has also not been included in the symmetries that have been gauged, and e.g. in the range of the index A in (2.38). However, the currents in (2.15), (2.20) and (2.22) only depend on the (anti-)self-dual F ± µν and not on B µ explicitly. As was mentioned after (2.10), this allows one to assign chiral weights to the fields and supersymmetry parameters 11 We would like to remark that these weights are consistent with the transformations of the bonus symmetry discussed in [54]. 12 The weight of the supersymmetry parameter was directly assigned using the commutator [T, Q] in (2.10). These lead to the weights of all the currents and, requiring (2.24) to be invariant, to the weights of the fields of the Weyl multiplet [35] given in Table 2. This bonus U(1) symmetry is not gauged so far, though we will come back to its gauging in Sec. 2.3.

The nonlinear variations of the N = 4 Weyl multiplet
The next step in constructing the nonlinear supersymmetry variations consists in the covariantization of the linear ones. 13 This comes down to a three step procedure: 1. make the parameters local: → (x), 2. change derivatives into covariant derivatives: ∂ µ → D µ , 3. replace all derivatives of gauge fields with curvatures: . After the covariantization one has to make an ansatz concerning the nonlinear terms in the variations. These terms have to be consistent with the representations and the Weyl and chiral weights of the different fields. The consistency with SU(4) means that the indices of the fields need to be correctly contracted on the right-hand side of the variations such that they match the indices on the left hand side. The terms in the right-hand side will also have to be combined in such a way that the sums of the Weyl and chiral weights of the fields and derivatives equal those of the Weyl and chiral weight of the field in the left-hand side of the variation. Finally, the coefficients appearing in front of the nonlinear terms have to be determined by imposing soft algebra relations to be determined by comparing the action of the commutator on the different fields. We will specify the relations below.
The chiral bonus symmetry, which was so far only a rigid symmetry, can be extended to a local symmetry [35], using a rewriting of the scalar field C of the Weyl multiplet as projective coordinate of the coset space SU(1, 1)/ U(1) as in [55]. 14 This means that the complex field C is replaced by a complex constrained doublet {Φ α } = {Φ 1 , Φ 2 }, constrained to |Φ 1 | 2 − |Φ 2 | 2 = 1. This new doublet has now the following transformation laws where λ T is a local parameter, and U α β with (U α β ) * = −η αγ U δ γ η δβ and U α α = 0 are rigid parameters. Appropriate insertions of Φ α allowed the authors of [35] to write the Weyl multiplet with a local λ T chiral symmetry, acting on all the fields φ as in footnote 11, with the weights c given in Table 2. The gauge connection is the composite field (2.41) 13 Details of this procedure have been discussed in [39, sec. 2]. 14 One could expect that the field C is related to the bonus symmetry since its current c = F − ab F ab− allowed for the bonus symmetry in N = 4 SYM in the first place.
The second term is arbitrary and is introduced to simplify further formulae where Υ µ appear. This is the case for all covariant derivatives, which have now a term (2.42) The relation with the formulation in terms of C is made by gauge fixing, imposing the gauge condition Φ 1 = (Φ 1 ) * . This also fixes λ T in terms of the rigid parameters U 1 1 and U 1 where we have that On the other hand we can then also write that The variation of the original scalar with respect to the new parameters is In the previous subsection we considered the linearized theory, which is also linear in C.
Hence it contains only the rigid U 1 1 symmetry, related to the remaining constant value of λ T according to (2.43) as U 1 1 = −iλ T . Hence we have agreeing with the weight 2 assigned to C in Table 2. The reason one introduces the extra local symmetry and scalar doublet is that it puts strong restrictions on the nonlinear supersymmetry transformations. The full nonlinear variations of the Weyl multiplet, including the S-supersymmetry variations were found in [35] and are given by 15 See the translation of conventions in Appendix A.4.
with composite fields ω µ ab (e, b, ψ) and φ µ as solutions to the constraints (2.36): (2.50) The covariant derivatives on fields are covariant for all symmetries. E.g. on Φ α this is but this simplifies in the expression Note that this is the expression that reduces to ∂ a C in the linearized theory. The only elementary field that transforms under K is b µ as in (2.32). The algebra of N = 4 conformal supergravity is a soft algebra, i.e. with parameters that are dependent on the fields in the multiplet. The algebra of Q supersymmetries is This algebra is an extension of su(2, 2|4) since it reduces to the latter upon putting the fields of the Weyl multiplet to zero.

The truncation to N = 3 extended conformal supergravity
In this section the construction of the Weyl multiplet for N = 3 supergravity in four dimensions will be discussed. The construction is based on an explicit breaking of the supersymmetric conformal group PSU(2, 2|4) into SU(2, 2|3). This breaking will happen in three steps. Firstly one supersymmetry parameter, 4 , is set to zero and secondly the appropriate field components of the N = 4 Weyl multiplet will have to be found that keep an N = 3 symmetry after the truncation. Finally, the variations of the fields in the new representation are derived. Deriving the explicit supersymmetry variations will be the subject of the next section. In our truncation we will find that the SU(4) R-symmetry group breaks to SU(3) × U(1). This means that the Latin indices used in the previous section will not run from 1 to 4 anymore, but from 1 to 3. For the linear transformations that we present first in this section, the U(1) factor provides the N = 3 T -symmetry in (2.10). This will be more subtle for the nonlinear transformations since the non-linear U(1) R-symmetry is a combination of the bonus U(1) symmetry described in the previous section and the U(1) factor in the truncation SU(4) → SU(3) × U(1). The way in which these two U(1) symmetries are merged was already described in [14], and will be relevant when we will discuss the nonlinear theory in section 4.2.
In the truncation of the R-symmetry group we will have to choose a convention for the order of the Levi-Civita tensor. The following choice has been made: (3.1) Considering the variations (2.23), we can identify the set of currents containing Θ µν that form a multiplet under the transformations i , i = 1, 2, 3, putting 4 = 0. These are where we have defined The λ-current has become an SU(3) scalar and thus there is an ambiguity in the notation concerning the chirality of the spinor. To indicate the chirality of the spinor we use subscripts L or R. For practical use, it is also useful to record the inverse of the transformation between the ξ symbols: This is a multiplet with 64 + 64 components and is found to be in the 8 representation of the SU(3) R-symmetry group. This labeling stems from the fact that the lowest weight current, d m n , is in the 8 representation, having the traceless property, d n n = 0, inherited from the properties of the N = 4 current. In [41,42] a similar suggestion has been made for the representations that should be present in the N = 3 Weyl multiplet. The next step is to truncate the supersymmetry transformations of (2.23): The coefficients of the different terms have been checked on consistency with the algebra. Namely, the following commutator, when acting on the currents, has been calculated in this procedure: As was already expected we find that the R-symmetry group partially breaks from SU(4) to SU(3) × U(1). This is supported by the fact that the associated current acquires a trace after truncation: Because we are interested in the irreducible representations of the symmetry group we split up the R-current in a traceless part and an SU(3) scalar, namely: The current multiplet now consists of the following fields: From the truncation of N = 4 conformal supergravity one finds that there are two (spin-3/2) multiplets in the 6 and6 representations of SU(3), additionally to the (spin-2) stress-energy tensor multiplet in the 8 representation of SU (3). The components of the N = 4 multiplet therefore decompose as 20 → 8 ⊕ 6 ⊕6, under the truncation of the R-symmetry group (SU(4) → SU(3) × U(1)).
The 6 and6 multiplets consist of 32 + 32 components given by and its conjugate multiplet 16 , with The lowest weight component, d ij , is in the 6 representation of SU(3). The supersymmetry variations of this multiplet are found in the same way as for the 8 representation, namely by a consistent truncation of the variations in the N = 4 multiplet: 16 The conjugation has to be taken in the N = 4 representation.
Hence, we find that none of the currents in the N = 3 Weyl current multiplet are found in the right-hand side of the variations. This means that we can consistently put all of these currents to zero and conclude that the truncation of the 20 representation of SU(4) into 8 ⊕ 6 ⊕6 of SU(3) is consistent and that the multiplets are disjoint: (3.13)

Components of the Weyl multiplet(s)
Now that we know the content of the N = 3 Weyl current-multiplet, we can determine the gauge and matter fields in the Weyl multiplet. The Weyl multiplet is simply found by coupling a field to each of the currents, exactly as was already done in the case of N = 4 conformal supergravity. The first order action then looks like (3.14) leading to the independent fields 15) where V i µj is traceless. As in sec. 2.2, we can introduce then the Lorentz transformations, dilatations and special conformal transformations. This works exactly as explained there and leads to the replacement of h µν by e a µ , the introduction of the gauge field b µ and the definition of composite gauge fields by the constraints (2.36). This replaces the set (3.15) by These fields are consistent with earlier suggestions made for the N = 3 Weyl multiplet in [41,42], similar to the case of the current multiplet. We will present the transformations in Sec. 4.1.
Although we have found the N = 3 Weyl multiplet through a reduction of the N = 4 current multiplet, which was then coupled to the gauge fields, one could also directly reduce the N = 4 Weyl multiplet. 17 Both procedures are completely consistent. We have chosen the normalizations of the gauge fields that couple to the N = 3 current multiplet in such a manner that the Lagrangian given in (3.14) resembles the one in (2.24). Considering the N = 3 Weyl multiplet as a reduced version of the N = 4 Weyl multiplet (setting the fields in (3.10) to zero), we can identify (2.24) with (3.14) for where all the i, j, . . . indices refer now to an SU (3) representation and thus run from one to three. Two inverse relations that will be useful in the future are The last equation implies also how the SU(4) transformations contribute to the SU(3) and T transformations. In fact, it implies for the parameters The parameter λ i j has a trace and corresponds to the gauge field V µi j , λ T is the tracepart and corresponds to the gauge field A µ , finally the symbolλ i j is the traceless part of λ i j and corresponds to the gauge field V µi j . Because the notation is rather heavy we will omit the hat in the future and from here on assume that the R-symmetry parameter λ i j is once again traceless.
We can then calculate the weights under this λ T transformation for all the fields in the N = 3 multiplet (3.16), using their definition from N = 4 fields in (3.17). It turns out that this weight is equal to the chiral weight of the extra generator in N = 4 mentioned in the last column of Table 2. Therefore we can identify these symmetries and use λ T for both.
The corresponding gauge field will then be the sum of A µ in (3.17) and Υ µ reduced from (2.41). However, the latter has no linear part after the truncation to N = 3 and will only play a role in the non-linear theory. We will therefore come back to this in Sec. 4.2, see (4.6).
The summary of the currents and the fields for N = 3 is given in Table 4, which also mentions these chiral weights. Now that we know the components of the N = 3 Weyl multiplet, we are able to summarize all the known Weyl multiplets in four dimensions. More information on these multiplets can be found in [35,57,41,42]. The different known Weyl multiplets 18 in four dimensions, varying from N = 4 to N = 1 are listed in Table 5. This table is an extension of Table 1 given in the introduction. Here the representations are further split into SU(N ) representations, which correspond to the fields of the Weyl multiplets as e.g. for N = 4 in Table 2 and for N = 3 in Table 4. Another systematic way of representing the states of the N ≤ 4 Weyl multiplets has been given in [59].

Supersymmetry transformations of the N = 3 Weyl multiplet
To find the supersymmetry variations we follow the same procedure as was applied in the case of N = 4 conformal supergravity. This means that first the linear variations are determined by imposing invariance of the first order action, and inserting the superconformal symmetries, as explained at the end of the previous section. In a second step these variations will be covariantized. Thereupon an ansatz for the nonlinear terms in the variations will be made such that the representations, Weyl weights and chiral weights are consistent. Finally, this will be checked for compatibility with the soft algebra, fixing the coefficients of the nonlinear terms.

The linear supersymmetry transformations
The procedure outlined at the end of the previous section leads to the following linear supersymmetry variations Table 4: The multiplet of currents and their corresponding gauge/matter fields for N = 3 conformal supergravity. The third column shows some properties of the gauge fields derived from the properties of the currents, the fourth column gives the R-symmetry representation of the currents (and fields) and the fifth and sixth column respectively give the Weyl and chiral weights of the gauge/matter fields.
f ield #states   (2)) agrees with the numbers in Table 1. For the nontrivial representations, also the Dynkin labels are given, which corresponds to the Young Tableaux (the i-th Dynkin label is the number of columns with i vertical boxes). The fields that have two parts in the second column have also the conjugate representation in SU(N ).
with D µ i as in (2.34), which after the split in (3.18) is These variations agree also with the reduction of (2.25), (2.34) and (2.37), and are consistent with the N = 3 supersymmetry algebra. The highest order component of the multiplet is D m n , which is in the 8 representation of SU(3). The next step is to derive the special supersymmetry transformations generated by S i . This derivation is similar to the derivation of the Q-supersymmetry variations, the difference is that in this case the last line in (2.10) is used to determine the coefficients in the variations. The non-trivial linear special supersymmetry variations are given by

The nonlinear supersymmetry transformations and the soft algebra
To find the nonlinear part of the supersymmetry variations one has to follow the same method as was described in the case of N = 4 conformal supergravity. A careful analysis results in the following nonlinear variations where The A µ in here is the combination from the linear one in (3.17) and the reduction of Υ µ in (2.41). Note that the complex scalar C describing the coset SU(1, 1)/ U(1) vanishes in the truncation to the N = 3 Weyl multiplet. Therefore also Φ α disappears. As a result, the bonus U(1) symmetry described in Section 2.3 is not anymore an independent symmetry, instead, it recombines with the diagonal U(1) inside SU(4) to form the U(1) R-symmetry in SU(2, 2|3). As written after (3.19), the weights of the fields for both the U(1) factor inside SU(4) and the extra generator λ T used in Section 2.3 are equal, and they can thus be combined in the new soft algebra. The gauge field associated to the U(1) R-symmetry in SU(2, 2|3) will only inherit the fermionic term from the composite field Υ µ in (2.41). Explicitly one finds that the new U(1) gauge field in terms of the N = 4 fields is Note that this relation also impacts the λ T parameter in the soft algebra. Furthermore, the curvature tensor of the A µ gauge field also gets corrected in the non-linear case: This correction for the curvature has already been applied in (4.4). Explicit expressions of the curvature tensors will be given shortly. The nonlinear variations mentioned above are consistent with the soft algebra of the following form Note that the parameter for the T-transformation has been corrected for the fact that the U(1) R-symmetry gets combined with the additional U(1) symmetry present in the N = 4 theory when reducing to the case of N = 3 supersymmetry. It is also useful to have the transformations of constrained gauge fields. Following the method in Sec. 16 k γ a Λ L + ε ij γ a χ k ( k γ a ψ µ j + h.c.) ,

Conclusion
In this paper the gravity multiplet for N = 3 conformal supergravity in four dimensions, also known as the N = 3 Weyl multiplet, has been constructed. The construction of this multiplet was done using three steps. First the known current multiplet of the N = 4 conformal supergravity theory was truncated to N = 3 supersymmetry. These currents are essential because they uniquely determine the Weyl multiplet. This one to one correspondence follows from the first order action in which each current is coupled to a field in the multiplet: The breaking of supersymmetry explicitly consisted of three consecutive steps: 1. put one supersymmetry parameter to zero 4 → 0, 2. determine the supersymmetry transformations restricted to the remaining three supersymmetries, 3. find a subset of currents that transform internally for the remaining three supersymmetries.
It was found that the subset of currents consisted of 64+64 ⊂ 128+128 fermionic and bosonic components. The 128 + 128 components refer to the case of N = 4 conformal supergravity. Inside the found multiplet 40 fermionic and 32 bosonic components were assigned to matter fields. These fields are generally necessary in extended supergravity to ensure an equal amount of fermionic and bosonic components. The truncation thus split up the 128 + 128 components in the original N = 4 conformal supergravity in two subsets. One of these subsets contained the gravity multiplet 19 and the other multiplet could be interpreted as a matter multiplet. For the truncation to be consistent the two subsets had to be completely disjoint. The gravity multiplet transforms internally under supersymmetries, and the matter multiplet does not act as a source into the gravity multiplet when the supersymmetries are applied. We found that this is indeed the case: To further argue that the correct multiplet of currents was found, remark that previous literature suggested that the Weyl multiplet of N = 3 conformal supergravity indeed had to consist of 64 + 64 fermionic and bosonic components [41,42].
The first order coupling in (5.1) can be viewed as a perturbation around flat space. By imposing invariance of this first order action, one then systematically finds the linearized supersymmetry transformations. Determining these linear supersymmetry variations is the second step in the three step procedure. To make sure that the found variations were correct, their consistency with the superconformal algebra was checked.
The third step in the procedure was to determine the nonlinear variations. In this step the large amount of symmetries in the superconformal group gets its merit. Consistency with the Lorentz, conformal and R-symmetries puts strong restrictions on the possible terms in the supersymmetry variations. Keeping these restrictions in mind all the thinkable terms were added to the variation, with a priori unknown coefficients. These coefficients were then determined by consistency with the soft algebra. In extended supergravity one normally finds such soft algebras instead of conventional Lie algebras, see [60][61][62] for a more detailed description of such algebras. In a soft algebra the commutator relations deform such that the parameters are dependent on the field content itself, for the N = 3 Weyl multiplet the soft algebra has been given in Section 4.2.
Finally, we would like to elaborate on some possible future applications of the theory constructed in this paper. With the knowledge of the Weyl multiplet and its full supersymmetric variations one is able to research the possibilities for extending to higher order derivative theories as well. This was already done in [2] for N = 4 conformal supergravity. However, because very little was known for the N = 3 case this is still an open problem.
Also, applications in holography would be interesting with respect to this newly found theory. Recent papers, [21,22], have discussed several of these applications concerning N = 3 Poincaré supergravity. It would be interesting to see in what way these results can be incorporated into the superconformal theory. In recent studies of double copy constructions the case of N = 3 supergravity has also been of interest [63].

A.1 Conventions
In general the conventions of [52] are used. Here we will mention a few important notions that could potentially cause for confusion. Throughout this paper the mostly plus convention is used for the metric. When a two sided derivative is used it will be with a minus sign when the derivative works as a right acting operator: A dualized tensor is denoted with a tilde and we use the following definition of the dual:

A.2 Chiral notations
In N -extended supersymmetry the fields are, amongst others, representations of the Rsymmetry group. Specifically for N = 3 supersymmetry the fields are representations of the group SU(3) × U(1). For the N = 4 case on the other hand we have that the R-symmetry is described by SU (4). Concretely this means that the fields in such theories have extra indices, besides the possible spacetime and spinor indices. These indices are denoted with Latin letters i, j, k, . . .. Furthermore, we will use these indices to distinguish between fields and their charge conjugated versions. An example of this is given by the R-symmetry gauge field in the N = 4 and 3 Weyl multiplets described in Sections 2 and 3.1 respectively. The complex conjugation of this field is given by where the latter equation is due to the antihermiticity of these fields. For spinors we can use these indices to denote their chirality. For instance, for the spinor Λ i , which is in a vector representation of the R-symmetry group, we define For different spinors we have used different conventions for their chirality. This should become clear if one keeps in mind that for the supersymmetry parameters we use the following conventions The chirality for all the other spinors then follow from consistencies in the supersymmetry transformations. For clarity all the conventions of the spinor chiralities with respect to the SU(N ) representation have been written in Table 6.

A.3 Traces and hermitian conjugation
In several supersymmetry variations we have used the notation δV = W − trace , and δV = W + h.c.. (A.6) The meaning of these notations is the following. As a first example, for indices running over i = 1, . . . , 4: where the coefficient of the second term is determined by the demand that δ k i on this expression vanishes. Say we have a tensor D ij k in some representation of SU(N ) such that D ij k = D [ij] [k ] and D kj k = 0. Then we will have to ensure that the supersymmetric variation of this tensor will have the same symmetry and trace properties. This is done by taking a variation of the following form The coefficients α and β are then determined by making δD k kj vanish identically. In the case of SU(4), such that i, j, . . . = 1, . . . , 4, this is done by taking α = 2 and β = − 1 3 . If the field D is also hermitian we will have to ensure that the right-hand-side of the variation is also hermitian. The following example shows how this is done by adding the hermitian conjugated form of a variation. If we write that the tensor varies under a supersymmetry as

A.4 Comparing the conventions to the literature
Much of the work presented in this paper is related to results already found in [35]. In this appendix we will clarify the differences in terms of the conventions between this work and theirs.
For the (anti-)symmetrization we have taken the "weight one" convention such that , and similar for the antisymmetrization, (A.11) in contrast with [35] where no factor 1/2 is taken. Another difference is that the Levi-Civita symbol with space-time indices, ε abcd , in [35] should be replaced with −iε abcd to compare the results. The antisymmetric gamma matrix with two indices in [35] is defined as Furthermore, for the gauge fields some conventions have changed (the left-hand side are symbols used in [35], while the right-hand side consists of symbols used in this work) The final differences are in the definitions of the parameters of the soft algebra i ⇐ (A.14)