The B-field soft theorem and its unification with the graviton and dilaton

In theories of Einstein gravity coupled with a dilaton and a two-form, a soft theorem for the two-form, known as the Kalb-Ramond B-field, has so far been missing. In this work we fill the gap, and in turn formulate a unified soft theorem valid for gravitons, dilatons and B-fields in any tree-level scattering amplitude involving the three massless states. The new soft theorem is fixed by means of on-shell gauge invariance and enters at the subleading order of the graviton's soft theorem. In contrast to the subsubleading soft behavior of gravitons and dilatons, we show that the soft behavior of B-fields at this order cannot be fully fixed by gauge invariance. Nevertheless, we show that it is possible to establish a gauge invariant decomposition of the amplitudes to any order in the soft expansion. We check explicitly the new soft theorem in the bosonic string and in Type II superstring theories, and furthermore demonstrate that, at the next order in the soft expansion, totally gauge invariant terms appear in both string theories which cannot be factorized into a soft theorem.


Introduction
There has been a huge effort in the last few years to connect the soft behavior of scattering amplitudes of massless particles to underlying symmetries of the theory. This connection has been made explicit in the case of gauge, gravity and higher-spin theories, where the soft factorization theorems of the scattering amplitudes through subleading orders have been shown to follow from their on-shell gauge invariance [1][2][3][4][5]. Their relation to asymptotic symmetries were recently suggested [6,7], and are now being being vastly explored (see e.g. the recent review [8] and references therein, as well as the more recent paper [9], which discusses also scalar soft theorems from asymptotic symmetries).
The focus of this paper concerns the gravitational S-matrix in theories of gravity coupled with a dilaton and a two-form. It is well known from string theory that amplitudes of this theory can be described in a unified way, which we in short will describe. Nevertheless, while it is known that the graviton and dilaton obey soft theorems, a soft theorem for the two form is still missing [19,20]. The aim of this paper is to fill this gap, and to derive a unified soft theorem valid universally for the graviton, dilaton and the two-form.
The two-form appears particularly in theories of supergravity and string theory, where it is known as the Kalb-Ramond two-form B-field. In string theory it enters as a closed string massless state accompanying the graviton and dilaton. Their soft behavior, and particularly the soft theorems obeyed by the string graviton and dilaton were recently derived in Refs. [3,[20][21][22][23][24][25][26], extending the well-known graviton [27][28][29][30] and less-known dilaton [31,32] soft theorems from the 60s and 70s to one higher order. (See also Ref. [33][34][35][36][37][38] for other string theory related soft theorems.) The B-field also appears in gravity as a double-copy Yang-Mills theory. An easy way to understand this, which will later be useful, is by decomposing the double-copied Yang-Mills field into its constituent fields: where D is the number of spacetime dimensions and ⊥ µν = such that η µν ⊥ µν = √ D − 2, and ⊥ µν ⊥ µν = 1, whilek is an unphysical reference momentum. The fields g µν , φ, and B µν are naturally identified with the gravitational field, the dilaton and the antisymmetric B-field, while ⊥ µν can be thought of as the dilaton 'polarization tensor' (or dilaton projector). By the Kawai-Lewellen-Tye [39] and Bern-Carrasco-Johansson [40] relations, double-copied amplitudes of Yang-Mills theory can be identified with amplitudes of gravity coupled with the dilaton and B-field, providing a unified description for amplitudes involving any of the three fields.
From this double-copy construction one may naïvely expect that also the B-field should obey soft theorems at the same order. After all, one may compute the amplitudes generically, and only in the end project the external states appropriately. However, the naïve expectation turns out not to hold, and we will explain why.
It is useful to first review how the soft theorems for the graviton and dilaton can be derived by using gauge invariance of the amplitude. Considering an (n + 1)-point amplitude involving double-copied Yang-Mills states, i.e. gravitons, dilatons, and Bfields, it is possible to decompose it into two contributions, as depicted in Fig. 1. The decomposition of the amplitude as given in Fig. 1 can be written as: where dependence on all other k j = k i is implicit. We are giving a special role to the state carrying momentum q, since we will consider its soft behavior. By using the relation M n = µ 1 1¯ ν 1 1 · · · µn n¯ νn n M n µ 1 ν 1 ...µnνn , the three-point amplitude entering in the above expression can be rewritten in terms of differential operators acting on M n , given by [2,3]: where κ D is related to Newton's constant by κ D = 8πG The two contributions in Eq. (1.3) are not independently gauge invariant. We may therefore use gauge invariance to put certain constraints on the remainder function N n+1 . Considering the kinematical region where q k i for any i, Eq. (1.3) can be expanded in q. At tree-level, N n+1 does not have any poles in q and hence at leading order one recovers Weinberg's soft theorem (loops do not modify this leading order result, see e.g. [41,42] for a recent discussion): To project this expression on the physical states, one takes q µ¯ q ν = q µν to be the polarization tensor of either the graviton, dilaton or B-field. If the soft state is projected onto the B-field, whose polarization tensor is antisymmetric, this leading expression clearly vanishes, but also if it is projected onto the dilaton, since ⊥ q µν k µ i k ν i = k 2 i +O(q) = 0+O(q). Only the graviton has a leading nonzero singular soft behavior. The expression is gauge invariant due to momentum conservation i=1 k µ i = 0 + O(q).
At every other order in the soft expansion, the two types of contributions are related by gauge invariance; that is, by These two conditions are sufficient to fix completely the orders q 0 and q 1 in the soft expansion of the amplitude, when M µν n+1 is symmetric in its indices µν; i.e. when the soft state is either a graviton or a dilaton [2,3]. We will in this work additionally show that if the soft state is a B-field, i.e. if M µν n+1 is antisymmetric in µν, this construction is sufficient to fix completely its order q 0 soft behavior, with the result being: where B q µν = 1 2 ( q µ¯ q ν − q ν¯ q µ ) is the polarization tensor of the B-field. This result is consistent with the 'holomorphic soft theorem' for the B-field found in the bosonic string in Ref. [20] (further details are given in Sec. 3.1).
The leading soft theorem for the B-field can be added to the corresponding expression derived for the dilaton and graviton [3,20,23] to define a unified operator that collects the soft behaviour of amplitudes in theories of gravity coupled to a dilaton and a two form. The full soft operator then turns out to be: This expression generically reproduces the soft behavior of the graviton, dilaton and B-field upon symmetrization, respectively, antisymmetrization of the polarization vectors q,µ¯ q,ν . As such, it can be considered the soft theorem of double-copied Yang-Mills theory.
As we will also show, contrary to the case of the dilaton and graviton, it is not possible to fix completely the term of order q in the soft behavior of the B-field by this construction. To explain why, let us note that a caveat in the construction above is that the quantity N n+1 in Eq. (1.3) may, at a particular order in q, contain terms local in q that are independently gauge invariant. Such terms can for obvious reasons not be related to the factorizing set of diagrams by gauge invariance. For the graviton and dilaton, this is avoided through order q in the soft momentum, since the most general local expression for a gauge invariant symmetric two-index tensor is of O(q 2 ) [2]: where, due to gauge invariance, A ρµ = −A µρ is an antisymmetric function constructed out of the momenta and polarization vectors of the external states, and is furthermore a local function in q.
For the antisymmetric B-field, however, things are different, since it is possible to write a general expression for an antisymmetric two-index tensor local in q, which obeys gauge invariance starting already at O(q): where A ρµν is a totally antisymmetric tensor constructed from the external momenta and polarizations, and is furthermore a local function in q. For this reason one is not able to constraint N n+1 through order q in the case of a soft B-field. It is nevertheless possible to decompose the amplitude through any order in the soft expansion into two separately gauge invariant parts, as follows using the notation v where one part remains unconstrained due to the preceding discussion, but is local in q, while the other part factorizes as a soft theorem (one can Taylor expand M n (k i + q)). The factorizing part encodes the soft theorem, as well as containing all terms needed to gauge covariantize the first part of Eq. (1.3) involving M 3 . This expression can essentially be seen as the main consequence of the B-field obeying a soft theorem. As we will show in Sec. 2, the order q factorizing terms can compactly be written in terms of angular momentum operators.
We will in this work first derive the above summarized results and then explicitly derive the soft behavior of the Kalb-Ramond B-field both in the bosonic string and in superstrings. We confirm the proposed soft relations, and furthermore we provide explicit expression for A ρµν showing that it is non-zero. In particular, we will see that the Bloch-Wigner dilogarithm appears in A ρµν in both string theories, which leads us to conclude that A ρµν cannot be written as a soft theorem. As regards the field theory limit, the form of A ρµν remains to be understood.
The paper is organized as follows: In Sec. 2 we show that on-shell gauge invariance fixes the leading soft behavior (of order q 0 ) of the B-field in tree-level amplitudes, while the subleading part (of order q) can only be partially fixed. In Sec. 3 and 4 we explicitly compute amplitudes in the bosonic, respectively, the supersymmetric string theory involving a soft Kalb-Ramond state to confirm the new soft theorem as well as to show that the subleading soft behavior cannot be factorized. In Sec. 5 we provide our conclusions.

Soft theorem for B µν from gauge invariance
In this section we derive the soft theorem for the antisymmetric tensor B µν in an amplitude with only massless particles, i.e. Kalb-Ramond fields, gravitons and dilatons. We will see that, unlike for the graviton and dilaton, in the case of the antisymmetric tensor we can only determine the soft behavior through order q 0 . The soft behavior of order q 1 cannot be fixed by gauge invariance.
Let us start from the pole term given by the diagrams where the soft particle is attached to one of the other external particles, as depicted in Fig. 1. As explained in the introduction their sum is given by ( where k i and q were put on shell, i.e. k 2 i = q 2 = 0, the polarization tensors µ q¯ ν q were stripped off, and (2.14) In the case of a soft antisymmetric tensor, where M pole µν is antisymmetric under the exchange of the indices µ and ν, the expression reduces to: The previous expression is not gauge invariant, i.e. it is not vanishing when we saturate it with q µ or q ν . It is possible, however, to add to it a term, local in q, which will make it gauge invariant, i.e.: 16) where N µν is now the antisymmetric gauge-invariant remainder of the amplitude. It is easy to see that the expression in the square bracket above vanishes when we saturate it with q µ or q ν . Gauge invariance then implies the following conditions on the additional term N µν : Expanding around q = 0, at the lowest order, we get two conditions: that are for N µν = −N νµ consistent with At the next order in the soft momentum q we get where A ρµν is a completely antisymmetric tensor under the exchange of the three indices, and is only a function of the momenta and polarizations of the hard external particles. Notice that the tensor N µν contains in general higher powers in the soft momentum q.
and since we assume that it is local in q, we may just as well express it as: to all orders in q, and automatically satisfying Eq. (2.17), where now A ρµν (q, k i ) contains all the higher order terms in q. We end up with: This is an exact relation between the n+1 and n-point amplitudes, valid to any order in the soft expansion. Obviously, since the last term is gauge invariant, A ρµν cannot be fixed by gauge invariance of the amplitude. To conclude, in the case of a soft antisymmetric tensor scattering on other massless states, gauge invariance fixes the amplitude only through the order q 0 . The term of order q contains a totally antisymmetric tensor that cannot be fixed by gauge invariance.
It is convenient for later use to introduce a new tensorÃ ρµν for the leading order expression of A ρµν , in the following way This is possible since the operator in the squared bracket is just another totally antisymmetric tensor. Expanding Eq. (2.23) and inserting this alternative expression for A ρµν at leading order, we arrive at where ∂ µ i ≡ ∂/∂k iµ . This expression can be written more compactly, by defining holomorphic and antiholomorphic total angular momentum operator, as follows: These operators especially turn useful, when considering the action on superstring amplitude. Let us consider the operator: Considering the first term on the right-hand side, it can be shown to vanish due to antisymmetry and transversality of B qµν , as well as the mass-shell condition q 2 = 0. Therefore we get, after inserting the explicitly expression for L i , which is exactly equal to the order q factorized part of Eq. (2.25). In other words, we find a more compact form for the expanded amplitude through order q, reading: where we used that the contraction of µν is antisymmetric, and we can thus equally write B µν → µ¯ ν . Notice that we could also trivially rewrite the first two terms in the right-hand side of the previous expression in terms of One may wonder whether the part that remains unfixed by gauge invariance also factorizes in terms of a soft and a hard part due to some other property of the amplitude. In the subsequent two sections we investigate this question by computing explicitly the unfactorized part involvingÃ ρµν in the bosonic string as well as in the superstring. Our conclusion to this question is negative, nevertheless, we provide the details and explicit expressions that may be useful in other regards. The conclusion about the field theory limit ofÃ ρµν remains open.

Soft scattering of B µν in the bosonic string
For the derivation of the scattering amplitude involving n + 1 massless closed string states in the bosonic string we refer to Sec. 2 in Ref. [23]. Therein it was shown that the (n + 1)-point amplitude, M n+1 , can be written as a convolution where M n is just the n-point amplitude, and where by * a convolution of integrals is understood, and S carries all the information of the additional external state. The point is that the computation of the soft behavior of M n+1 is equivalent to computing the soft expansion of S. Let us quote the expressions for M n and S: and where z i are the Koba-Nielsen variables of the hard states, and z is for the soft state. Grassmannian variables ϕ i have been introduced and in this notation i , the holomorphic polarization vector of the massless closed states, are also Grassmannian, and likewise for the antiholomorphic counterparts, denoted with a bar. k i are the momenta of the hard states, while q is for the soft state, and α is the string Regge slope.
The expansion of S was computed in the decomposition: defined by: (3.36) Each part was further split in S (a) i , a=0,1,2, with the index a labelling the order of expansion in q of the integrand modulo the factor |z − z l | α qk l , which has to be integrated. The explicit results for S (a) i can be found in Ref. [23], and apply to any massless closedstring state. Here we are interested in the antisymmetric part in µ q¯ ν q of those expressions. First, the result for S (0) 1 is: We can show that the part in the square bracket is just the Bloch-Wigner Dilog, which is analytic and continuous 1 . Denoting ζ ≡ (z i − z m )/(z i − z j ) we can write the square bracket of the antisymmetric part as: where in the second line we identified the Bloch-Wigner dilog, denoted as D 2 . This function has the following properties (as well as many other, not relevant here): • It is a real function on C, and analytic except at the points ζ = {0, 1}, where it is only continuous, but not differentiable. For us, ζ never takes these values, since • It has a six-fold symmetry: The antisymmetric part of S (0) 1 can thus be written as It can be checked that this expression is gauge-invariant by itself by using e.g. the relation D 2 (ζ) = D 2 ( 1 1−ζ ). In fact, we can write it in the form of Eq. (1.11), making it explicitly gauge invariant: where the symmetry properties of D 2 were used to completely antisymmetrize the expression in the square bracket in the indices ρνµ.
It is convenient also for later use to introduce the tensorial function: which is totally antisymmetric in its indices ρµν and in its variables V, X, Y . 1 We thank Lance Dixon for pointing this out to us during the Nordita program Aspects of Amplitudes.
In terms of this function, we compactly have: where we stripped off the polarization tensor.
The antisymmetric part of all other S (a) i is simply obtained by antisymmetrizing the expressions derived in Ref. [20,23] in the polarization indices of the soft state, leading to: We note that when taking the complex conjugate one must also exchange the indices µ ↔ ν, since B qµν = − B qµν = B qνµ , which follows from the decomposition q µν = qµ¯ q ν .

The soft theorem
The terms of O(q 0 ) appear in Eq. (3.43), (3.46a) and (3.46b) only. Summarizing, they read: The soft theorem proposed to reproduce this is: it is straightforward to see that Eq. (3.48) exactly reproduces Eq. (3.47). For checking this, we note that the terms with two ϕ's produced by (S i −S i ) µν vanishes over the sum, due to opposite parity of the numerator and denominator in the exchange of i ↔ j.
We additionally like to make the remark that the soft operator in Eq. (3.48) follows also from earlier considerations in Ref. [3,20], where it was noticed that the explicit result in Eq. (3.47) can be reproduced by the following 'holomorphic' soft theorem: By separating the string amplitude into a holomorphic and an antiholomorphic part, and promoting the momentum in the antiholomorphic sector to a (spurious) 'antiholomorphic' momentum, k →k, it can be shown that both the bosonic string amplitude and the superstring amplitude at O(q 0 ) can, for any soft state, be equivalently written as: whereL i denotes the antiholomorphic angular momentum operator that acts on thek quantities. The notation | k=k means that thek is, after the action, identified again with the physical momentum k. In Ref. [3] it was shown that when the soft state is symmetrically polarized, i.e. µ¯ ν → S µν , then the above expression is easily seen to match the known subleading graviton soft theorem, while in Ref. [20] it was remarked that for an antisymmetric soft state the expression reduces to: Now, notice that under a gauge transformation for the Kalb-Ramond field, B q µν → B q µν + q µ χ ν − q ν χ µ , the amplitude changes as follows Since for any q ρ and any χ µ the additional term has to vanish, the following identity must hold (3.53) which can be checked by a direct calculation. From this we conclude that Eq. (3.51) for an antisymmetric soft state reduces to: Since this expression no longer involves theL operator, we may readily identifyk = k, making M n (k i , i ;k i¯ i ) = M n the physical n-point amplitude. This reproduces, and thus confirms once again, the soft theorem in Eq. (3.48).

The order q soft behavior
While there does not exist a complete soft operator reproducing the terms at O(q), we are still able to greatly reduce the terms into a gauge invariant part that factorizes, and a gauge invariant part that can be written in terms of a totally antisymmetric tensor.
The soft behavior is proposed to admit the form: The action of the soft operators on the lower-point amplitude read: It is now a straightforward, but very tedious task, to show that all terms in Eq. (3.43)-(3.46c), which have a 1/q-pole exactly matches the terms given by Eq. (3.56) and (3.57). These simply come from the Feynman diagrams where the soft state is attached to an external leg. This confirms that all other Feynman diagrams only produce terms that are local in q.
Most of the terms given by Eq. (3.58) also matches similar terms in the explicit expressions Eq. (3.43)-(3.46c). However, the term involving ϕ i ϕ j ϕ l in Eq. (3.58) does not have a counterpart in the explicit expressions. It therefore has to be gauge invariant on its own, and indeed: To arrive at the second line we used that the first line vanishes for l = j, because ϕ j ϕ j = 0, and for the third line we used the definition in Eq. (3.41), making the expression explicitly gauge invariant.
The terms with two ϕ's coming from Eq. (3.58) also do not match to the explicit expression, however, as we will see below, they ensure gauge invariance of what remains, when we subtract the terms coming from Eq. (3.56)-(3.58) from the explicit expressions. Indeed, our most reduced expression for the soft behavior through the order q reads: We can express this more compactly in terms of the totally antisymmetric tensor given in Eq. (3.41): It is tempting to think that, besides the dilogarithm term, all the other non-factorizing terms above may be reproducible in terms of gauge-invariant soft operators acting on the lower-point amplitude. We have investigated an exhaustive number of possibilities, and have not found any reduction as compared to the above expression. For instance, one could consider an operator involving α This type of operator leads to the following type of terms and is made gauge invariant by the combination: This operator produces the same four types of terms as the last four lines in Eq. (3.60) plus two additional and different types of terms. However, among the four types that are similar it is only possible to match one of them, while the other three are different in their Koba-Nielsen structure. Therefore in total, while matching one line in Eq. (3.60), five new gauge-invariant expressions are generated.
One instance, where one may introduce an additional soft operator, without elongating the expression, is The last term matches the similar term in Eq. (3.62), but the first term is new. Therefore this operator effectively exchanges one type of term with another. We note that, although this operator is not exactly matching terms in Eq. (3.62) one-to-one, it shows that terms of the form of the right-hand side above are terms of order α , because the operator explicitly carries such a factor.

Soft scattering of B µν in superstrings
For the derivation of the scattering amplitude involving n + 1 massless closed string states in superstrings we refer to Ref. [3]. As was shown in Ref. [3], we can take advantage of knowing the results in the bosonic string case, which were presented in the previous section. This follows by realizing that the n-point tree-level scattering amplitudes, M n , of closed massless superstrings can generically be written as a convolution of a bosonic part, M b n , with a supersymmetric part, M s n , as follows: The expressions for bosonic and supersymmetric parts of the n-point supersymmetric string amplitude are defined by: where κ D is the D-dimensional Newton's constant, dV abc is the volume of the Möbius group, z i are the Koba-Nielsen variables, ϕ i and θ i are Grassmannian integration variables, and we have introduced the following superkinematical quantities: where µ i and k µ i are respectively the holomorphic polarization vector and momentum of the state i, and α is the string Regge slope.
Apart from the integration measure, M b n is equivalent to the same amplitude in the bosonic string, given in Eq. (3.31); the integrands, in fact, become equal if one makes the identification θ i i → i and remembers that, after this substitution, i becomes a Grassmann variable. The difference between M b n and the bosonic string amplitude Eq. (3.31), is only the presence in M b n of the integrals over the Grassmann variables θ i ,θ i , and the additional factor 2 i=1 θ iθi /|z 1 − z 2 | 2 coming from the correlator of the superghosts.
As in the case of the bosonic string, it is also useful to factorize the superstring amplitude, at the integrand level, into a soft part S and a hard part as follows: where M n is the full superstring amplitude of n closed massless states, and S is a function that when convoluted with the integral expression for M n provides the additional soft state involved in the amplitude. The function S can further be decomposed into its bosonic part and supersymmetric part as follows: where S b is the purely bosonic part, given by: which is simply equal to the similar expression in the bosonic string, given in Eq. (3.32), after identifying θ i i → i (whereby i becomes a Grassmann variable). S s andS s are the complex conjugates of each other and they provide the contributions from the additional supersymmetric states. They are given bȳ and S s is given by the complex conjugate of this expression, where complex conjugation sends z i →z i , µ i →¯ µ i , θ i →θ i , and ϕ i →φ i , while the momenta k i are left invariant. This decompositions is of course useful, since we already dealt with the bosonic integral S b in the previous section. The additional part coming from supersymmetry, S s +S s , was furthermore computed through the order q in Ref. [3]. Here we explicitly construct their functional form, when the soft state is an antisymmetric Kalb-Ramond field. The general result found in Ref. [3] reads: where the brackets and curly-brackets in the indices denotes commutation and anticommutation of the indices, e.g.: (4.75) These definitions differ by a factor of two with the ones in Ref. [3], where also appropriate factors of two have been introduced in Eq. (4.74).
We must now project out the antisymmetric part, in µ¯ ν , to obtain the expression for the Kalb-Ramond field. At order q 0 we find: At the next order, it can be checked that the antisymmetric part can be written as: where T ρµν was defined in Eq. (3.41). It can be checked that the term involving T ρµν , in fact, cancels out with the similar term coming from the bosonic part in Eq. (3.62).

The soft theorem
As remarked in Sec. 3.1, the soft theorem can be equivalently written as in Eq. (3.51).
Since the soft theorem operator is a linear operator, and since we know that it reproduces the bosonic part, when acting on M b n , we only need to show that it reproduces the supersymmetric part, given in Eq. (4.76), when acting on M s n , i.e.
which is easily checked by noticing the relations: where the quantities A and C are defined in Eq. (4.69).

The order q soft behavior
Let us now consider the order q soft operator, which up to the totally antisymmetric tensor according to Eq. (2.29), reads: The action of this operator on M n can be decomposed as followŝ The actionŜ (1) B M b n is equivalent to the one studied in the bosonic string. We need to analyze the remaining terms. Let us notice that and likewise for the antiholomorphic counterpart. We find that (4.83) The first term above reproduces exactly a similar term of the explicit result of Eq. (4.77). The terms with one θ i can be reduces as follows, using that θ i A µ i = −C µ i : where we also used that q ρ q σĀ ρ jĀ σ l (z i −z j )(z i −z l ) = 0, because the denominator and the numerator have different parity. The other term with one θ i is the complex conjugate of this expression. The second term above also reproduces a similar term of the explicit result of Eq. (4.77).
It is finally useful to simplify the terms with θ iθi , which due to B µν k µ i k ν i = 0, can be reduced to: showing that this term is totally gauge invariant and local in q.
Next, consider the second line of Eq. (4.81). It is easy to derive the following action: where for the first equality we manipulated the summation indices i, j, l, for the second equality we manipulated the expression using both µν antisymmetry and j, l symmetry. Again the final expression is, consistently, a totally antisymmetric, gauge invariant term.
We are now in a position to write our entire result in terms of the totally antisymmetric tensor. Adding also the bosonic part, derived in Eq. (3.61) with i → θ i i , we find:

Conclusion
We have shown using gauge invariance that the soft behavior of the antisymmetric Bfield is fixed at the order q 0 in the soft momentum in amplitudes involving gravitons, dilatons and other B-fields. We have furthermore explained why gauge invariance cannot fix completely its soft behavior at order q, in contrast to the case of a soft graviton or dilaton. By using the leading soft theorem, it is nevertheless possible to explicitly decompose the amplitude into two separately gauge invariant parts to all orders in the soft momentum.
The new soft theorem provides, together with the soft theorems through the same order for the graviton and dilaton, the basis for the unification of the three soft theorems, which we have offered in Eq. (1.9). This universal expression is a step towards understanding the interplay between the infrared behaviors of Yang-Mills theory and gravity as Yang-Mills squared theory [19].
We have explicitly checked the new soft theorem of the B-field in the bosonic string as well as in superstrings, and we have furthermore computed the soft behavior through order q in both theories, expressed in terms of a convoluted integral of a hard and a soft part. Based on the structure of the soft integrand we conclude in both theories that the soft behavior at order q cannot be factorized in form of a soft theorem. As regards the field theory limit of these expression, the conclusion remains an open question and should be further studied.