Top-forms of leading singularities in nonplanar multi-loop amplitudes

  • Baoyi Chen
  • Gang Chen
  • Yeuk-Kwan E. Cheung
  • Ruofei Xie
  • Yuan Xin
Open Access
Regular Article - Theoretical Physics
  • 137 Downloads

Abstract

The on-shell diagram is a very important tool in studying scattering amplitudes. In this paper we discuss the on-shell diagrams without external BCFW bridges. We introduce an extra step of adding an auxiliary external momentum line. Then we can decompose the on-shell diagrams by removing external BCFW bridges to a planar diagram whose top-form is well known now. The top-form of the on-shell diagram with the auxiliary line can be obtained by adding the BCFW bridges in an inverse order as discussed in our former paper (Chen et al. in Eur Phys J C 77(2):80 2017). To get the top-form of the original diagram, the soft limit of the auxiliary line is needed. We obtain the evolution rule for the Grassmannian integral and the geometry constraint in the soft limit. This completes the top-form description of leading singularities in nonplanar scattering amplitudes of \(\mathcal {N}=4\) Super Yang–Mills (SYM), which is valid for arbitrary higher-loops and beyond the Maximally-Helicity-Violation (MHV) amplitudes.

1 Introduction

Bipartite diagrams and the associated Grassmannian geometry [2, 3] have recently found their way into the scattering amplitude studies. An amazing discovery was to exploit them in computing scattering amplitudes in \(\mathcal {N}=4\) SYM theory [4, 5, 6, 7, 8, 9, 10, 11]. Planar scattering amplitudes are represented by on-shell bipartite diagrams and expressed in “top-form” as contour integrations over the Grassmannian submanifolds. Planar loop integrands in \(\mathcal {N}=4\) SYM have recently been constructed in [4, 12] along with the introduction of the Grassmannian and on-shell method. As a result, the “dlog” form and the Yangian symmetry [13, 14, 15, 16, 17] of the scattering amplitudes are made manifest in the planar limit. It is natural to extend the construction to non-planar scattering amplitudes [1, 18, 19, 20], and theories of reduced (super-) symmetries [21, 22, 23].

The leading singularities are represented in the top-form of Grassmannian integrals in which the integrands are comprised of rational functions of minors \(\{\mathbf {R}(M_C)\}\) of the Grassmannian C matrices. The top-form is elegant in that the amplitude structures are simple and compact; and the Yangian symmetry is manifest in the positive diffeomorphisms of positive Grassmannian geometry [4]. It is therefore crucial to express the scattering amplitudes in top-form in order to explore the power to further uncover hidden symmetries and dualities of the scattering amplitudes. We present in this letter our successful construction of top-forms for non-planar scattering amplitudes. Our method applies to multi-loop, beyond-MHV leading singularities.

Recently, exciting progress in \(\mathcal {N}=4\) SYM scattering amplitude computation (by the on-shell method) was reported by many research groups in [1, 3, 18, 19, 24, 25, 26, 27, 28]. Together we have made a step forward in the computation of nonplanar \(\mathcal {N}=4\) SYM scattering amplitudes, and hopefully in the formulation of the AdS/CFT correspondence at finite N.

2 BCFW-bridge decompositions of leading singularities

The aim of this work is to obtain a simple and compact analytical expression of leading singularities of scattering amplitudes, valid for arbitrary number of loops, beyond the planar limit. A general leading singularity can be represented by a reduced on-shell diagram. BCFW-bridge decomposition provides an efficient way of constructing on-shell diagrams in the planar limit. In non-planar cases, we can obtain the BCFW-bridge decomposition chain by extracting planar sub-diagrams and computing them recursively [1] as shown in Fig. 1. For the sub-diagrams that are BCFW-decomposible, we follow the recipe presented in [1]. There exist, however, “No Bridge” (NB) diagrams which do not contain any BCFW bridges [1, 19]. We have presented a method in [1] to transform some NB diagrams, schematically depicted in Fig. 1b, by applying U(1)-decoupling relations [29].

In this work we present a general method applicable to any NB diagrams. The key is to add an auxiliary external momentum line to form an auxiliary BCFW bridge, shown in Fig. 1c. To regain the original NB diagram we take the soft limit [30, 31, 32, 33], setting the auxiliary momentum to zero. This way the BCFW-bridge decomposition chain of the reduced on-shell diagrams beyond the planar limit can be obtained.
Fig. 1

a Obtaining the Lth loop amplitude recursively. b Utilizing the U(1) decoupling relation to turn a nonplanar diagram into a planar one. c Introduction of an auxiliary external momentum line to form the BCFW bridge

In the rest of this letter we present a recipe for constructing an analytical expression, the top-form, for a nonplanar leading singularity using the BCFW-bridge decomposition chain [1] after adding an auxiliary external momentum line.

3 Construction of the top-form

The top-form of an on-shell diagram is obtained once the geometric constraints, \(\varGamma \), and the integrand, f(C), are determined. A non-planar leading singularity in the form [4]
$$\begin{aligned} \mathcal {T} = \oint _{\varGamma } {dC^{k\times n} \over \text {Vol}(GL(k))} {\delta ^{k\times 4}(C\cdot \widetilde{\eta }) \over f(C)}\delta ^{k\times 2}(C\cdot \widetilde{\lambda })\delta ^{2\times (n-k)}(\lambda \cdot C^\perp )~ \end{aligned}$$
requires one to calculate f(C) and \(\varGamma \) under the BCFW shifts and to take the soft limit of the auxiliary BCFW bridges.
Let us study the BCFW shifts. The integrand, f(C), must contain those poles equivalent to the constraints in \(\varGamma \); otherwise the contour integration around \(\varGamma \) will vanish. Each BCFW bridge removes one pole in f(C) by shifting a zero minor to be nonzero: in general the poles in the integrand must change their forms and the integrand changes its functional form accordingly. To see this we parametrize the constraint matrix, C, using the BCFW parameter, \(\alpha \). In a BCFW shift, a column vector X is shifted: \( X\rightarrow \widehat{X}=X+\alpha Y, \) with several minors of f(C) become functions of \(\alpha \). After the shift, there exists at least one constraint \(M_0(X)=0\) being shifted to \(M_0(\widehat{X})=M_0(X)+\alpha R(Y)\) if there is a top-form. This is demonstrated in the following section. Meanwhile the factor \(M_0(\widehat{X})\) should be present in the dominator to contribute a pole at \(\alpha =0\). In other words \( \alpha =M_0(\widehat{X})/R(Y) \) is then a rational function of \(\widehat{C}\) and can be subtracted from the other shifted minors to obtain some shift-invariant minors of \(\widehat{C}\), \( M_i(X)=M_i(\widehat{X}-\alpha Y). \) In summary, attaching a BCFW bridge, the integrand is
$$\begin{aligned} f(\widehat{C}) = M_0(\widehat{X}) \prod _i M_i(\widehat{X}-\alpha Y) \times \left( \begin{array}{c} \text {minors}\\ \text {without}~\alpha \end{array} \right) . \end{aligned}$$
(1)
Fig. 2

An MHV example

3.1 An MHV example

A six-point three-loop MHV example has been analyzed in [19]. Here, for comparison, we provide our calculation by attaching the auxiliary BCFW bridges. We attach an auxiliary external momentum line, in Fig. 2, and form an auxiliary BCFW bridge-(3, 7). This on-shell diagram can be decomposed to an identity as follows: \((1,7)\rightarrow (2,6)\rightarrow (3,5)\rightarrow (2,3)\rightarrow (3,4)\rightarrow (12)\rightarrow (2,3)\rightarrow (5,7) \rightarrow (3,7)\). Before adding bridge-(5, 7), the on-shell diagram is still planar. The Grassmannian constraints and the top-form can be obtained directly from the permutation [4] shown in the first row of Table 1. Adding bridge-(5, 7), the constraint \((7,1)^{1}\rightarrow (1,5,7)^2\), as shown in the second row of Table 1. Here we use \((i_1,i_2,\cdots , i_m)^r\), where mr are positive integrals, to denote the matrix of rank r constructed by the columns \(i_1,\cdots , i_m\) in the C matrix. \((i_1,i_2,\cdots , i_m)^r\) also characterize the \((r-1)\)-dimensional hyperplane in the k-dimensional projective space. Adding bridge-(3, 7), the constraint \((1,5,7)^2\) disappears.
Table 1

The evolution of the geometric constraints

 

\((7,1)^{1}\)

\((2,3,4)^{2}\)

\((4,5,6)^{2}\)

\((6,1,2)^{2}\)

(5, 7)

\((1,5,7)^{2}\)

\((2,3,4)^{2}\)

\((4,5,6)^{2}\)

\((1,2,6)^{2}\)

(3, 7)

 

\((2,3,4)^{2}\)

\((4,5,6)^{2}\)

\((1,2,6)^{2} \)

Before attaching bridge-(5, 7), the top-form is
$$\begin{aligned} \frac{1}{(123)(234)(345)(456)(567)(671)(712)}, \end{aligned}$$
where we use \((i_1i_2\cdots i_k)\) to denote the minor of the matrix which is formed by the columns \(i_1\cdots i_k\) in C. When attaching (5, 7), the contour integral around the pole \((712)=(\widehat{7}12)-\alpha (512)\) is replaced by \(d\alpha \over \alpha \) with \(\alpha = \frac{(\widehat{7}12)}{(512)}\). All the minors with column 7 except (712) are affected by the bridge,
$$\begin{aligned} \begin{array}{ccccc} (567) &{}\rightarrow &{} {(56(\widehat{7} 5)\cap (12))\over (512)}&{}=&{}(56\widehat{7})\\ (671)&{}\rightarrow &{} {(6(\widehat{7} 5)\cap (12)1)\over (512)} &{}=&{}\frac{(\widehat{7}15)(126)}{(512)}, \end{array} \end{aligned}$$
where \((\widehat{7} 5)\cap (12)\) denotes the intersection point between the two lines characterized by \((\widehat{7} 5)\) and (12). Then the top-form integrand becomes
$$\begin{aligned} \frac{(125)}{(123)(234)(345)(456)(567)(157)(126)(127)}. \end{aligned}$$
Similarly after attaching bridge-(3, 7) the top-form integrand becomes
$$\begin{aligned} \frac{(135)^{2}}{(123)(234)(345)(456)(156)(357)(157)(126)(137)}. \end{aligned}$$
To obtain the top-form of the original diagram, we parametrize the \({C^\prime }\) as
$$\begin{aligned} \left( \begin{array}{cccccc|c} &{} &{} &{} C&{} &{} &{} 0 \\ &{} &{} &{} &{} &{} &{} 0 \\ \hline 0 &{} 0 &{} c_{3} &{} c_{4} &{} c_{5} &{} c_{6} &{} 1 \\ \end{array} \right) . \end{aligned}$$
Then we expand all the minors in \({C^\prime }\) in terms of those in C,
$$\begin{aligned} \begin{array}{ll} (126)=(12) c_{6}&{} (234)=-c_{3}(24)+c_{4}(23)\\ (123)=(12)c_{3}&{}(456)=c_{4}(56)-c_{5}(46)\\ (156)=-(16)c_{5}&{}(135)=-c_{3}(15)+c_5(13)\\ (137)=(13) &{}(345)=c_{3}(45)-c_{4}(35)+c_{5}(34)\\ (357)=(35)&{}(157)=(15) ~~ . \end{array} \end{aligned}$$
The top-form becomes
$$\begin{aligned}&\frac{(-c_{3}(15)+c_5(13))^{2}}{-(12)(35)(15)(12)(13)(16)c_3 c_6 c_5 (-c_{3}(24)+c_{4}(23))}\\&\quad \times {1\over (c_{3}(45)-c_{4}(35)+c_{5}(34))(c_{4}(56)-c_{5}(46))}. \end{aligned}$$
The additional pole is characterised by (126), (234), (456). The contour integration gives \(c_{6}\rightarrow 0, c_{3}\rightarrow \frac{(23)}{(24)}c_{4}, c_{5}\rightarrow \frac{(56)}{(46)}c_{4}\) and
$$\begin{aligned} \frac{[(56)(13)(24)-(23)(15)(46)]^{2}}{(23)(12)(24)(26)(45)(34)(16)(56)(35)(15)(13)(46)} \end{aligned}$$
consistent with the MHV example in [19]. This can be simplified further,
$$\begin{aligned}&-f_p(125364)+f_p(125463)-f_p(134265)\nonumber \\&\quad +f_p(126543)-f_p(132465)-f_p(123564), \end{aligned}$$
with \(f_p\) denoting the planar amplitudes of the corresponding orders.

4 Construction of the top-from of NB diagram

Now we discuss the new Grassmannian geometry structures in the NB diagrams [1, 19]. For the sub-diagram structure in Fig. 1b, the top-form is obtained by imposing U(1)-decoupling relation in [1]; in this work we focus on the auxiliary BCFW bridges which is suitable for the general diagrams as shown in Fig. 1c. The top-forms of those diagrams containing auxiliary BCFW bridges can be obtained using the above method. We discuss presently how they return to the top-forms of the original NB diagrams upon taking the soft limits.

The on-shell diagram \(\mathcal {A}_{n+1}^{k+1}\) with one auxiliary line as shown in Fig.1c can be written in two equivalent forms:
$$\begin{aligned}&\int \frac{d^2\lambda _{I} d^2\widetilde{\lambda }_{I}d^{4}\widetilde{\eta }_{I} }{vol(GL(1))}\frac{\mathcal {A}_{n+2}^{k+1}\langle I \bar{I}\rangle ^3}{\left\langle {\bar{n}}I \right\rangle ^{2} \left\langle \bar{I} {\bar{n}} \right\rangle }\delta ([\bar{n} I])\delta ^{4}(\widetilde{\eta }_{{\bar{n}}}+{\langle \bar{I}{\bar{n}}\rangle \over \langle {\bar{I}} I\rangle }\widetilde{\eta }_{I}),\nonumber \\ \end{aligned}$$
(2)
$$\begin{aligned}&\oint _{\bar{\varGamma }} {dC^{k\times n} dc_{k+1}\cdots dc_n \over \text {Vol}(GL(k))} {(1\cdots k ) \over f(C,c_i)}\nonumber \\&\quad \times \delta ^{k\times 4}(C\cdot \widetilde{\eta })\delta ^{k\times 2}(C\cdot \widetilde{\lambda })\delta ^{2(n-k)}(\lambda \cdot {C^\prime }^\perp ) \nonumber \\&\quad \times \delta ^{2}\left( \sum _{i=k+1}^{n} c_i \tilde{\lambda }_i+c_{{\bar{n}}} \tilde{\lambda }_{{\bar{n}}}\right) \delta ^{4}\left( \sum _{i=k+1}^{n} c_i \widetilde{\eta }_{i}+c_{{\bar{n}}} \widetilde{\eta }_{{\bar{n}}}\right) , \end{aligned}$$
(3)
where \(c_{{\bar{n}}}=1\) and \({\bar{n}}\) denote the index of the auxiliary line. Equation (2) is obtained directly from Fig.1c by integrating over the internal line \({\bar{I}}\). Equation (3) is a general top-form of \(\mathcal {A}_{n+1}^{k+1}\), where we choose a particular parametrization of the Grassmannian matrix \({C^\prime }\) as
$$\begin{aligned} C^\prime =\left( \begin{array}{cccccc|c} &{} &{} &{} &{} &{} &{}0\\ &{} &{} &{} C&{} &{} &{}\vdots \\ &{} &{} &{} &{} &{} &{}0\\ \hline 0&{} \cdots &{}0 &{}c_{k+1}&{}\cdots &{} c_{n}&{}1 \end{array} \right) . \end{aligned}$$
Our method of adding the auxiliary line can be verified by comparing (2) and (3). Noting that
$$\begin{aligned} \delta ^{2}\left( \sum _{i=k+1}^{n} c_i \tilde{\lambda }_i+c_{{\bar{n}}} \tilde{\lambda }_{\bar{n}}\right) =\delta \left( \sum _{i=k+1}^n c_i {[i1]\over [{\bar{n}} 1]}+1\right) \delta ([{\bar{n}} I]), \end{aligned}$$
(2) and (3) can therefore be proved to contain the term
$$\begin{aligned} \delta ([\bar{n} I])\delta ^{4}(\widetilde{\eta }_{{\bar{n}}}+{\langle \bar{I}{\bar{n}}\rangle \over \langle {\bar{I}} I\rangle }\widetilde{\eta }_{I}), \end{aligned}$$
which can be removed from the overall constraint delta function. The remaining part of (2) corresponds to the NB diagram \(\mathcal {A}_n^k\) in the limit \(\lambda _{{\bar{n}}}\rightarrow 0\). On the other hand, after taking the soft limit (3) yields
$$\begin{aligned}&\mathcal {A}_n^k=\oint _{\bar{\varGamma }} {dC^{k\times n}dc_{k+1}\cdots dc_n \over \text {Vol}(GL(k))} {(1\cdots k)\delta ^{k\times 4}(C\cdot \widetilde{\eta })\over f(C,c_i)} \nonumber \\&\quad \times \delta ^{k\times 2}(C\cdot \widetilde{\lambda }) \delta ^{2\times (n-k)}(\lambda \cdot {C}^\perp ) \delta \left( \sum _{i=k+1}^n c_i {[i1]\over [{\bar{n}} 1]}+1\right) ~.\nonumber \\ \end{aligned}$$
(4)
This is easily proven by counting the degrees of freedom of the associated on-shell diagram in which only one element \(c_f\) among \(c_i\) is a free parameter. As we shall prove in the following section, a given NB diagram to have a top-form requires that \(c_i/c_r=\mathbf {R}(M_C)\). Using this relation, the integration
$$\begin{aligned} \int {dc_r\over c_r}\delta \left( \sum _{i=k+1}^n c_i {[i1]\over [{\bar{n}} 1]}+1\right) \end{aligned}$$
gives 1. Finally, we obtain the top-form of \(\mathcal {A}_n^k\) by expanding the minors of \({C^\prime }\) into C minors in the integrand.

5 Rational top-forms and rational soft limit:

Now we study which kind of nonplanar on-shell diagrams can have rational top-forms. We address this question by building an equivalent relation between the rational top-form and the rational soft limit. If the soft limit of an auxiliary line leads to additional constraints such that \(c_i\over c_j\) is a rational function of C-minors for all non-vanishing \(c_i\) in the added row of \({C^\prime }\), we call this soft limit a rational soft limit.

When the soft limit of the auxiliary line is a rational soft limit, then the NB diagram with auxiliary line has a rational top-form if and only if the original NB diagram has a rational top-form.

We first consider the free parameters \(\alpha \) in the top-form integrand f(C) as shown in Eq. (1). The C matrix parameters \(\alpha _C\) that can be expressed as \(\mathbf {R}(M_C)\) are also of the form \(\mathbf {R}(M_{C^\prime })\). The additional \({C^\prime }\) elements \(c_i\) are of the form \(c_{r}\mathbf {R}(\alpha _C)\) (indicating a rational soft limit for \(c_{r}\ne 0\)). Since \(c_{r}\) is naturally \(\mathbf {R}(M_{C^\prime })\), all free parameters in \({C^\prime }\) are then rational functions of minors, i.e. the top-form is rational. Inversely, given the linear auxiliary bridge and rational soft limit, any C parameter denoted by \(\mathbf {R}(M_{C^\prime })\) can be expanded as \(\mathbf {R}(M_C)\) directly according to the procedure above.

Then let us study the geometry constraints. Geometry constraints are linear relations among columns of the C matrix. In fact, the total space is taken as the \((k-1)\)-dimensional projective space. Each column labeled by the index of the external line can be mapped to a point in the projective space. For the diagram which can be constructed by attaching BCFW bridges, the constraints are all coplanarity constraints for the points of external legs [1]. For the NB diagrams, after attaching the auxiliary lines, the geometry constraints in \(C'\) are still coplanarity constraints. Hence we only need to discuss how the geometry constraints evolve in the rational soft limit.

The simplest case is that the geometry constraints in \(C'\) are all untangled. Then the coplanarity constraints are of the form
$$\begin{aligned} (i_1, i_2,\cdots , i_m)^{m-1}. \end{aligned}$$
If one of the indices, e.g. \(i_m\), in the above constraint denotes the auxiliary line, then the geometry constraint becomes \((i_1, i_2,\cdots , i_{m-1})^{m-2}\) in the soft limit. If none of the indices denotes the auxiliary line, then the geometry is invariant for \(m<k\). Since \(k\rightarrow k-1\) in the soft limit, the geometry constraints for \(m=k\) do not exist any more.

In general the geometry constraints are still coplanarity constraints in the soft limit. However, this is not obvious for the tangled cases. We will leave the explanation of the soft limit behavior for tangled geometry, e.g. \(((i_1 i_2\bigcap i_3 i_4),i_5,\cdots , i_m)^r\), to future work. For now we focus on the algebraic form of these geometry constraints, which is enough to obtain the top-form.

In a general case, the geometry constraints in \(C'\) can be expanded as
$$\begin{aligned} F'_1= & {} \sum _{i=k+1}^{n}c_{i} F_1^{c_i}, ~~F'_2=\sum _{i=k+1}^{n}c_{i} F_1^{c_i},\nonumber \\&\cdots \quad \quad F'_{n-k-1}=\sum _{i=k+1}^{n}c_{i} F_{n-k-1}^{c_i},\nonumber \\&\cdots \qquad \qquad F'_{S}=\sum _{i=k+1}^{n}c_{i} F_{S}^{c_i}, \end{aligned}$$
(5)
where S is an integer. There are no higher order terms with respect to \(c_i\)’s. In fact if there are higher order terms, they can be factorized into linear polynomials either with rational minors of C as coefficients or with non-rational minors. For the former case, one of the linear polynomials can be redefined as the geometry constraints. For the latter case, some \(c_i/c_j\) are non-rational, which is beyond the scope of this paper.

Among the constraints in Eq. (5), we can choose arbitrary \(n-k-1\) equations to solve for the \(c_i/c_r\). For other equations, we can substitute the solutions of \(c_i/c_r\) to get all the geometry constraints for C after taking the soft limit.

6 More Examples

6.1 An \(\overline{\text {MHV}}\) example

In this subsection we give an example of a different situation using an \(\overline{\text {MHV}}\) example (Fig. 3) for illustration an auxiliary line connected to a white vertex. Attaching an auxiliary line enables the BCFW-decomposition to identity by the following chain: \( (7,3)\rightarrow (7,5)\rightarrow (3,4)\rightarrow (2,3)\rightarrow (4,5)\rightarrow (3,4)\rightarrow (1,3)\rightarrow (4,6) \rightarrow (3,7)\). Before adding bridge-(7, 5) the on-shell diagram is planar. The Grassmannian constraints (the first row of Table 2) and the top-form can be obtained directly from the permutation [4]:
$$\begin{aligned} \frac{1}{(1234)(2345)(3456)(4567)(5671)(6712)(7123)}. \end{aligned}$$
Fig. 3

An \(\overline{\text {MHV}}\) example

Table 2

Geometry constraints evolution for \(\overline{\text {MHV}}\) example

 

\((2,(3,4,5)^{2},6)^{3} \)

\((3,4,5)^{2}\)

\( (5,6,7,1)^{3}\)

\((7,1,2,3)^{3}\)

(7, 5)

\((2,3,4,6)^{3}\)

\((3,4,5,7)^{3} \)

\((5,6,7,1)^{3}\)

\((7,1,2,3)^{3}\)

(7, 3)

 

\((3,4,5,7)^{3}\)

\((5,6,7,1)^{3}\)

\((7,1,2,3)_{3}\)

The transformation of constraints after adding the bridges (7, 5) and (7, 3) is shown in the second and third rows of Table 2. The top-form of \(\mathcal {A}_{7}^{4}\) becomes
$$\begin{aligned} \frac{-(2467)^{2}}{(2347)(1246)(2456)(3457)(2346)(4567)(1567)(1267)(1237)}. \end{aligned}$$
Without loss of generality, we choose the first four columns of the \(\widehat{C}\) matrix as the identity:Then the last column can be represented by these four columns by
$$\begin{aligned} \mathbf {c}=c_{1}{} \mathbf{{e}}_{1}+c_{2}{} \mathbf{{e}}_{2}+c_{3}{} \mathbf{{e}}_{3}+c_{4}{} \mathbf{{e}}_{4}. \end{aligned}$$
This way we can rewrite the minor with column-7 as
$$\begin{aligned} (1237)= & {} c_{4}(1234) (1567)=c_{2}(1256)+c_{3}(1356),\\ (1267)= & {} c_{3}(1263) (2467)=c_{1}(2461)+c_{3}(2463) ,\\ (2347)= & {} c_{1}(1243) (3457)=-c_{1}(1345)-c_{2}(2345),\\ (4567)= & {} -c_{1}(1456)-c_{2}(2456)-c_{3}(3456). \end{aligned}$$
Considering the three poles of \(\mathcal {A}_{7}^{4}\), since there is no constraint in the top-form of \(\mathcal {A}_{6}^{4}\), we should integrate around all of the three poles and remove three coefficients. Finally, there is only one coefficient left and others can be represented by it: \( c_{4}\rightarrow 0, c_{1}\rightarrow -\frac{(2345)}{(1345)}c_{2}, c_{3}\rightarrow -\frac{(1256)}{(1356)}c_{2}. \) The remaining coefficient in the top-form is \(\frac{dc_{2}}{c_{2}}\) and can be fixed by one of the columns in \(\widehat{C}^{\perp }\) (noting that \(\widehat{C}^{\perp }\) has one more column than \(C^{\perp }\), which can be removed directly). Finally, the top-form of \(\mathcal {A}_{6}^{4}\) is
$$\begin{aligned} {1\over f_p}\frac{-[(2345)(1246)(1356)-(1256)(2346)(1345)]^{2}}{(1246)(2456)(1345)(2346)(1356)(1235)}, \end{aligned}$$
where \(f_p=(1234)(2345)(3456)(4561)(5612)(6123)\). This can also be simplified as
$$\begin{aligned}&-f_p(142356)-f_p(143265)+f_p(132456)\\&-f_p(132654)+f_p(123465)-f_p(123465). \end{aligned}$$

6.2 An NMHV NB diagram example

In this subsection we present the details in the calculation and simplification in the NMHV example (Fig. 4).
Fig. 4

A non-planar NMHV 4-loop leading singularity

Since this diagram cannot be decomposed of BCFW bridges directly we introduce an auxiliary external momentum line, the leg-8. The diagram transforms to a planar one by removing the bridges (2, 8), (6, 8) and (4, 2). The total decomposition chain is \( (2,8)\rightarrow (6,8)\rightarrow (4,2)\rightarrow (1,2)\rightarrow (2,3)\rightarrow (2,4)\rightarrow (4,5) \rightarrow (4,6)\rightarrow (6,7)\rightarrow (1,6)\rightarrow (6,8). \)

Before adding bridge-(4, 2) the planar diagram top-form is
$$\begin{aligned} 1\over (1234)(2345)(3456)(4567)(5678)(6781)(7812)(8123) \end{aligned}$$
with constraints shown in the first row of Table 3.
Table 3

Geometry constraints evolution for NMHV example

 

\((1,2,3)^{2}\)

\((3,4,5)^{2}\)

\((5,6,7)^{2}\)

\((7,8,1)^{2}\)

(4, 2)

\((1,2,3,4)^{3}\)

\((3,4,5)^{2}\)

\((5,6,7)^{2}\)

\((7,8,1)^{2}\)

(6, 8)

\((1,2,3,4)^{3}\)

\((3,4,5)^{2}\)

\((5,6,7)^{2}\)

\((6,7,8,1)^{3} \)

(2, 8)

\((1,2,3,4)^{3}\)

\((3,4,5)^{2}\)

\((5,6,7)^{2}\)

 
After attaching all the BCFW bridges, we obtain the top-form integrand
$$\begin{aligned}&{1\over (1234)(2345)(3456)(4567)(1567)(8672)(6781)}\nonumber \\&\quad \times \frac{(1347)(6721)^{3}}{(7812)(3167)(1237)(1247)(1286)}, \end{aligned}$$
(6)
with geometry constraints as shown in the last row of Table 3. Then we expand the rank-4 minors into rank-3 minors
$$\begin{aligned} (1234)= & {} (123)c_{4} (2345)=-(235)c_{4}+(234)c_{5},\\ (1237)= & {} (123)c_{7} (3167)=-(317)c_{6}+(316)c_{7},\\ (1286)= & {} -(126) (6721)=-(721)c_{6}+(621)c_{7},\\ (8672)= & {} -(672) (3456)=(356)c_{4}-(346)c_{5},\\ (6781)= & {} -(671) (1347)=-(137)c_{4}+(134)c_{7},\\ (7812)= & {} (712) (1247)=-(127)c_{4}+(124)c_{7} ,\\ (1567)= & {} (167)c_{5}-(157)c_{6}+(156)c_{7} ,\\ (4567)= & {} (467)c_{5}-(457)c_{6}+(456)c_{7}.\\ \end{aligned}$$
Solving all the additional constraints inherited from the auxiliary line and the attached vertex, we get \( c_{4}\rightarrow 0, c_{5}\rightarrow 0, c_{7}\rightarrow \frac{(457)}{(456)}c_{6}\) and the final top-form integrand,
$$\begin{aligned} {1\over f_p}\frac{(134)(357)[(457)(126)-(456)(127)]^{3}}{(124)(126)(135)(145)(267)(367)(457)^2}, \end{aligned}$$
where \(f_p=(123)(234)(345)(456)(567)(671)(712)\). Using the Plüker relations the integrand \(1\over f(C)\) is
$$\begin{aligned}&{(125)\over (124)(126)(167)(235)(257)(143)(345)(567)}\nonumber \\&\quad +{(125)\over (124)(127)(165)(235)(267)(143)(345)(567)}\nonumber \\&\quad +{(125)\over (123)(126)(167)(234)(145)(257)(345)(567)}\nonumber \\&\quad +{(125)\over (123)(127)(165)(234)(145)(267)(345)(567)}. \end{aligned}$$
(7)
It is hard to simplify the form further by using the Plüker relations directly. A simpler technique is to para-metrize the C matrix asand expand the three-column minors in the two-column minors. Then the first term in (7) can be written as
$$\begin{aligned}&{-(12)(36)\over (124)(126) c_7 (16)(23)(27)c_3(14)(34)(67)(36)}\nonumber \\&\quad ={-1\over (124)(126)(27)c_3 (14) (34) (67) c_7 (36)}\nonumber \\&\qquad +{1\over (124)(126)c_7 (16) (37)c_3 (24) (34) (67) } \nonumber \\&\quad ={-1\over (124)(126)(257) (134)(345) (567)(367)}\nonumber \\&\qquad -{1\over (124)(126)(167) (234) (357)(345)(567)} . \end{aligned}$$
(8)
Similarly we can rewrite the second term to the fourth term in (7) as
$$\begin{aligned} (II)= & {} {1\over (124)(127)(167) (346) (235)(345)(567)}\nonumber \\&+ {1\over (124)(127)(134)(267)(356)(345)(567)}; \end{aligned}$$
(9)
$$\begin{aligned} (III)= & {} {1\over (123)(126)(143) (467) (275)(345)(567)}\nonumber \\&+{1\over (123)(126)(243)(467)(175)(345)(567)}; \end{aligned}$$
(10)
$$\begin{aligned} (IV)= & {} {1\over (123)(127)(143) (267) (456)(345)(567)}\nonumber \\&+{1\over (123)(127)(234)(167)(456)(345)(567)}. \end{aligned}$$
(11)

6.3 An on-shell diagram with two auxiliary lines

Our method can also deal with the on-shell diagrams to which we need add more than one auxiliary lines. We consider the diagram in Fig. 5 where \(k=4\) and \(n=10\). After attaching the BCFW bridges recursively,
$$\begin{aligned} (C8)\rightarrow & {} (A8)\rightarrow (62)\rightarrow (42)\rightarrow (34)\rightarrow (23)\rightarrow (12)\rightarrow (45)\\\rightarrow & {} (34)\rightarrow (46)\rightarrow (37)\rightarrow (78)\rightarrow (27)\rightarrow (79) \rightarrow (7A)\\\rightarrow & {} (AB)\rightarrow (2A)\rightarrow (AC), \end{aligned}$$
we can get the integrand \(f(C')\) of the top-form directly
$$\begin{aligned}&\frac{1}{(56789A)(6789AC)(5679AB)(789ABC)}\nonumber \\&\quad \times \frac{1}{(89ABC1)(BC1246)(ABC134)(9ABC13)}\nonumber \\&\quad \times \frac{1}{(BC1236)(BC1234)(C12346)(BC1345)(123456)}\nonumber \\&\quad \times \frac{(5679AC)^3(BC1346)^3}{(234567)(5678AC)(45679A)(345679)(56789C)}. \nonumber \\ \end{aligned}$$
(12)
The geometry constraints are also obtained immediately seen,
$$\begin{aligned}&(3,4,5)^2,(9,A,B)^2,(8,A,B,C)^3,(2,4,5,6)^3,\nonumber \\&(5,6,7,8,A,C,)^3, (1,4,5,6,7,9)^5, \nonumber \\&(B,C,1,2,4,6)^3,(7,A,B,C,1,3)^5. \end{aligned}$$
(13)
We first take the soft limit of line-2. We use the gauge \(GL(k+2)/GL(k+1)\) to set the \(C''\) asWe pick up five linear independent equations with variables \(c_i\), \(i\in [4,9]\) from the constraints \((3,4,5)^2, (9,A,B)^2, \) \((8,A,B,C)^3, (7,A,B,C,1,3)^5,(5,6,7,8,A,C)^3\) in Eq. (13),
$$\begin{aligned}&(35x_1x_2x_3)c_4-(34x_1x_2x_3)c_5=0\nonumber \\&(BAx_1x_2x_3)c_9=0\nonumber \\&(CABx_1x_2)c_8=0\nonumber \\&(3ABC1)c_7=0\nonumber \\&(C678A)c_5+(5C78A)c_6+(56C8A)c_7+(567CA)c_8=0,\nonumber \\ \end{aligned}$$
(14)
where \(x_i\) denotes an arbitrary index of the external line in each constraint equation. Obviously the chosen x should leave the coefficients of \(c_i\) in the above equations non-vanishing. We do not use the constraint containing line-2 in Eq. (13), since they do not generate any constraints for the \(c_i\). In the top-form, after taking the contour integration of \(dc_4\cdots dc_9\) around the pole generated by the above equations, we get \(c_7\rightarrow 0,\ c_8\rightarrow 0,\ c_9\rightarrow 0,\ c_4\rightarrow \frac{(34x_1x_2x_3)}{(35x_1x_2x_3)}c_5,\ c_6\rightarrow \frac{(678AC)}{(578AC)}c_5\) and we are left with one integration \(dc_5\). The poles of the contour integration in Eq. (12) are reduced as follows:
$$\begin{aligned} (5678AC)&=(578AC)(c_6-\frac{(678AC)}{(578AC)}c_5),\nonumber \\ (789ABC)&=-(89ABC)c_7,\nonumber \\ (89ABC1)&=-(19ABC)c_8,\nonumber \\ (9ABC13)&=-(13ABC)c_9,\nonumber \\ (BC1345)&=-(135BC)(c_4-\frac{(BC134)}{(BC135)}c_5). \end{aligned}$$
(15)
The other minors in Eq. (12) are reduced by substituting the solutions of Eq. (14),
$$\begin{aligned} (123456)= & {} (13456),~~ (234567)=-(34567),\\ (BC1246)= & {} (146BC), (BC1236)=(136BC),\\ (BC1234)= & {} (134BC), (C12346)=-(1346C),\\ (345679)= & {} \frac{(34579)(678AC)}{(578AC)}c_5,\\ (56789C)= & {} \frac{(5678C)(789AC)}{(578AC)}c_5,\\ (56789A)= & {} \frac{(5678A)(789AC)}{(578AC)}c_5,\\ (6789AC)= & {} \frac{(789AC)(678AC)}{(578AC)}c_5,\\ (5679AB)= & {} \frac{(5679A)(79ABC)}{(579AC)}c_5,\\ (ABC134)= & {} \frac{(13ABC)(3479A)}{(3579A)}c_5,\\ (5679AC)= & {} -\frac{(567AC)(789AC)}{(578AC)}c_5,\\ (BC1346)= & {} -\frac{(134BC)(378AC)(5678C)}{(578AC)(3578C)}c_5,\\ (45679A)= & {} \frac{(4579A)(378AC)(5679A)}{(3579A)(578AC)}c_5. \end{aligned}$$
Fig. 5

An \(N^4\)MHV example with two auxiliary lines

Then we get the top-form of the on-shell diagram in Fig. 5 after taking the soft limit of line-2,
$$\begin{aligned}&\frac{1}{(13456)(1346C)(136BC)(13ABC)(146BC)(19ABC)}\nonumber \\&\quad \times \frac{1}{(34567)(34579)(4578C)(5678A)(79ABC)(89ABC)}\nonumber \\&\quad \times \frac{(134BC)(379AC)^2(5678C)^2(567AC)^3}{(579AC)(3578C)^2(5679A)^2(678AC)^2}. \end{aligned}$$
(16)
The geometry constraints are
$$\begin{aligned}&(3,4,5,6)^2,\ (9,A,B)^2,\ (8,A,B,C)^3,\ \nonumber \\&(B,C,1,4,6)^4,\ (1,5,6,7,9)^4. \end{aligned}$$
(17)
We then take the soft limit of line-8. We use the gauge \(GL(k+1)/GL(k)\) to set the \(C'\) asHere we choose \(c_4=c_5=c_7=c_9=0\). Using the constraints \((3,4,5)^2,\ (4,5,6)^2\), \((9,A,B)^2, \ (B,C,1,4,6)^4,\) \( \ (1,5,6,7,9)^4\), we can find the poles at \(c_3\rightarrow 0,\ c_6\rightarrow 0,\ c_1\rightarrow 0,\ c_A\rightarrow \frac{(9Ax_1x_2)}{(9Bx_1x_2)}c_B,\ c_C\rightarrow \frac{(146C)}{(146B)}c_B\), which are shown in the integrand as
$$\begin{aligned} (13456)= & {} (3456)c_1,\\ (34567)= & {} -(3457)c_6,\\ (34579)= & {} (4579)c_3,\\ (136BC)= & {} (136B)(c_C-\frac{(136C)}{136B}c_B),\\ (79ABC)= & {} (79BC)\\&\left( c_A+\left( \frac{(146C)(79AB)}{(146B)(79BC)}-\frac{(79AC)}{(79BC)}\right) c_B\right) . \end{aligned}$$
Similar to the soft limit of line-2, the other minors are reduced as
$$\begin{aligned} (3578C)= & {} -(357C), (4578C)=-(457C),\\ (678AC)= & {} (67AC), (89ABC)=(9ABC),\\ (5678A)= & {} -(567A), (5678C)=-(567C),\\ {(134BC)\over (146BC)}= & {} {(134B)\over (146B)},\\ (1346C)= & {} \frac{(1346)(146C)}{(146B)}c_B,\\ (5679A)= & {} \frac{(5679)(9A13)}{(9B13)}c_B,\\ \end{aligned}$$
$$\begin{aligned} (13ABC)= & {} -\frac{(1369)(13AB)(13BC)}{(139B)(136B)}c_B,\\ (19ABC)= & {} -\frac{(1469)(14BC)(19AB)}{(146B)(149B)}c_B,\\ (579AC)= & {} -\frac{(579A)(1469)(14BC)}{(149B)(146B)}c_B,\\ (379AC)= & {} -\frac{(379A)(1469)(46BC)}{(469B)(146B)}c_B,\\ (567AC)= & {} \left( {(567A)(146C)\over (146B)}-{(567C)(9A13)\over (9B13)}\right) c_B. \end{aligned}$$
Then we get the integrand of the original on-shell diagram without auxiliary lines,
$$\begin{aligned}&\frac{1}{(1346)(1369)(3456)(3457)(4579)(5679)(579A)}\\&\quad \times \frac{(134B)}{(146C)(37AB)(13BC)(19AB)(79BC)(9ABC)}\\&\quad \times \frac{((367C)(379A)(146B)-(567A)(146C)(379B))^3}{(146B)^3(67AC)^2(357C)^2}, \end{aligned}$$
with the geometry constraints \((3,4,5,6)^2, (9,A,B,C)^2\).

7 Summary and outlook

We have obtained the top-form integrands for nonplanar leading singularities by BCFW decompositions. In the cases that one cannot attach a BCFW bridge we add an auxiliary external momentum line judiciously to enable the application of the chain of BCFW decompositions and take the soft limit on the auxiliary momentum line to recover the original diagrams. This combination of strategies is efficient in computing the leading singularity of nonplanar diagrams of arbitrary loops. We have also classified nonplanar on-shell diagrams according to whether they possess rational top-forms, and we proved the equivalence to linear BCFW bridges (and rational soft limit for diagrams with no external BCFW bridges). With the chain of BCFW-bridge decompositions obtained the rational top-forms of the nonplanar on-shell diagrams can be derived in a straightforward way. This method applies to leading singularities of nonplanar multi-loop amplitudes beyond MHV.

An immediate question is whether all on-shell diagrams representing nonplanar leading singularities belong to this class, so that all leading singularities can be expressed in the rational top-forms.

The top-form, being simple and compact, is a useful tool to uncover hidden symmetries (e.g. generalized Yangian symmetry beyond planarity [25]), which are otherwise highly tangled in nonplanar leading singularities. When combined with the generalized unitarity cuts, the top-form holds promise in constructing the integrals as well as revealing the symmetries and dualities of the loop-level scattering amplitudes.

Mathematically our method of performing the BCFW decompositions is related to the toric geometry arising in the characterization of a matroid stratification. Further exploration on the relationship between BCFW decompositions and matroid stratification will also shed light on the geometry of underlying Grassmannian manifolds.

Notes

Acknowledgements

G. Chen thanks Nima Arkani-Hamed, Tianheng Wang for helpful discussion and useful comments. We thank Peizhi Du, Shuyi Li and Hanqing Liu for constructive discussion. Yuan Xin thanks Bo Feng for introducing the background of the recent developments of the scattering amplitude. This research project has been supported by the Fundamental Research Funds for the Central Universities under contract 020414340080, the Youth Foundation of China under contract 11405084. This research project has been supported in parts by the NSF China under Contract Nos. 11775110, 1169-0034. We also acknowledge the European Union’s Horizon 2020 Research and Innovation (RISE) programm under the Marie Skĺodowska-Curie grant agreement No.-644121, and the Priority Academic Program Development for Jiangsu Higher Education Institutions (PAPD).

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Authors and Affiliations

  • Baoyi Chen
    • 2
  • Gang Chen
    • 1
    • 2
  • Yeuk-Kwan E. Cheung
    • 2
  • Ruofei Xie
    • 2
  • Yuan Xin
    • 2
  1. 1.Department of PhysicsZhejiang Normal UniversityJinhuaPeople’s Republic of China
  2. 2.Department of PhysicsNanjing UniversityNanjingPeople’s Republic of China

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