Skip to main content
Springer logoLink to Springer
. 2015 Jun 9;75(6):254. doi: 10.1140/epjc/s10052-015-3472-z

Interference effects in BSM processes with a generalised narrow-width approximation

Elina Fuchs 1,, Silja Thewes 1, Georg Weiglein 1
PMCID: PMC4464706  PMID: 26097408

Abstract

A generalisation of the narrow-width approximation (NWA) is formulated which allows for a consistent treatment of interference effects between nearly mass-degenerate particles in the factorisation of a more complicated process into production and decay parts. It is demonstrated that interference effects of this kind arising in BSM models can be very large, leading to drastic modifications of predictions based on the standard NWA. The application of the generalised NWA is demonstrated both at tree level and at one-loop order for an example process where the neutral Higgs bosons h and H of the MSSM are produced in the decay of a heavy neutralino and subsequently decay into a fermion pair. The generalised NWA, based on on-shell matrix elements or their approximations leading to simple weight factors, is shown to produce UV- and IR-finite results which are numerically close to the result of the full process at tree level and at one-loop order, where an agreement of better than 1% is found for the considered process. The most accurate prediction for this process based on the generalised NWA, taking into account also corrections that are formally of higher orders, is briefly discussed.

Introduction

The description of the fundamental interactions of nature in terms of quantum field theories that are evaluated perturbatively has been extraordinarily successful in the context of elementary particle physics. Nevertheless, this theoretical formulation is plagued by a long-standing problem [13], since the asymptotic in- and outgoing states of quantum field theories are defined at infinite times corresponding to stable incoming and outgoing particles, while collider physics processes usually involve numerous unstable particles, see e.g. Refs. [47]. While in principle it would be possible to perform calculations of the theoretical predictions for the full process of stable incoming and outgoing particles, this is in many cases not feasible in practice (and still leaves the problem of the treatment of intermediate particles that can become resonant). Instead, one often seeks to simplify the task of calculating a more complicated process by separately treating the production of on-shell particles and their decays, where the latter can happen in several separate steps, each resulting in on-shell outgoing particles. Such an approach of simplifying the task of computing a complicated process involving many particles in the final state is in particular crucial in the context of incorporating higher-order corrections.

The separation of a more complicated process into several sub-processes involving on-shell particles as incoming and outgoing states is achieved with the help of the “narrow-width approximation” (NWA) for particles having a total width that is much smaller than their mass. The application of the NWA is beneficial since the sub-processes can often be calculated at a higher loop order than it would be the case for the full process, and it is also useful in terms of computational speed. Indeed, many Monte-Carlo generators make use of the NWA. An important condition limiting the applicability of this approximation, however, is the requirement that there should be no interference of the contribution of the intermediate particle for which the NWA is applied with any other close-by resonance, see e.g. Refs. [810]. While within the Standard Model (SM) of particle physics this condition is usually valid for relevant processes at high-energy colliders such as the LHC or a future Linear Collider, many models of physics beyond the SM (BSM) have mass spectra where two or more states can be nearly mass-degenerate. If the mass gap between two intermediate particles is smaller than the sum of their total widths, the interference term between the contributions from the two nearly mass-degenerate particles may become large.

For instance, mass degeneracies can be encountered in the Minimal Supersymmetric extension of the Standard Model (MSSM) [1113]. In particular, the MSSM may contain approximately mass-degenerate first and second generation squarks and sleptons. In the decoupling limit [14], the MSSM predicts a SM-like light Higgs boson, which can be compatible with the signal discovered by ATLAS [15] and CMS [16] at a mass of about Mh125 GeV, and two further neutral Higgs bosons and a charged Higgs boson H±, which are significantly heavier and nearly mass-degenerate. While in the CP-conserving case the heavy neutral Higgs bosons H and A are CP-eigenstates and therefore do not mix with each other, CP-violating loop contributions can induce sizable interference effects, see e.g. Ref. [10]. The compatibility of degenerate NMSSM Higgs masses with the observed Higgs decay rate into two photons was recently pointed out e.g. in Ref. [17]. Another example are degenerate Higgs bosons in (non-supersymmetric) two-Higgs doublet models, see e.g. Refs. [18, 19]. Furthermore, degeneracies can also occur in models of (universal) extra dimensions where the masses at one Kaluza–Klein level are degenerate up to their SM masses and loop corrections, see for example Refs. [2022]. Small mass differences of sequential Z and W bosons are analysed in an extension of the SM as an effective field theory in Ref. [23]. On the other hand, models with new particles on various mass levels often exhibit long cascade decays, so that there is a particular need in these cases for an approximation with which the complicated full process can be simplified into smaller pieces that can be treated more easily. However, several cases have been identified in the literature in which the NWA is insufficient due to sizeable interference effects, e.g. in the context of the MSSM in Refs. [8, 9, 2426] and in the context of two- and multiple-Higgs models and in Higgsless models in Ref. [27].

In the following we present a generalised NWA (gNWA), which extends the standard NWA (sNWA) by providing a factorisation into on-shell production and decay while taking into account interference effects. In Ref. [10] such a method was introduced at the tree level and applied to interference effects in the MSSM Higgs sector. This method was further extended in Ref. [28], in particular by incorporating partial loop contributions into an interference weight factor. A similar coupling-based estimation of an interference between new heavy quarks at lowest order was suggested in Ref. [29]. Interfering new, nearly degenerate vector bosons were considered in Ref. [23] in an approach of the product of involved couplings and on-shell parton luminosities. In the present paper we formulate a gNWA based on an on-shell evaluation of the interference contributions which is applicable at the loop level, incorporating factorisable virtual and real corrections. We validate the method for an example process by confronting the one-loop result within the gNWA with the result of the full process at the one-loop level. We furthermore investigate different levels of approximations, where we compare the on-shell matrix elements in the interference term with possible further simplifications based on interference weight factors. In the considered example process we study interference effects between the two neutral CP-even MSSM Higgs bosons h and H in the decay of a heavy neutralino and the subsequent decay into a fermion pair. Besides the validation against the full result for this process we also discuss additional improvements by the incorporation of corrections that are formally of higher orders. The discussed cases are meant to illustrate that the proposed method is applicable to a wide range of possible processes in different models.

The paper is structured as follows. Section 2 reviews the standard NWA before introducing the interference-improved extension in two different versions in Sect. 3. The notation of the parts of the MSSM that are needed for the phenomenological discussion in the following sections is defined in Sect. 4, with particular emphasis on the mixing of Higgs bosons. In Sect. 5, the gNWA is applied at the tree level to the example process of Higgs production from the decay of a heavier neutralino and its subsequent decay into a pair of τ-leptons. The numerical results for those contributions are discussed in Sect. 6. In Sect. 7 the application of the gNWA at the loop level is demonstrated. For comparison, the full one-loop calculation of the example process is performed in Sect. 8, including vertex, propagator, box and bremsstrahlung corrections. The numerical comparison and accordingly the validation of the gNWA at NLO is discussed in Sect. 9, where also the accuracy of the gNWA is investigated. Section 10 contains our conclusions.

Standard narrow-width approximation

The narrow-width approximation is a useful way to simplify the calculation of complicated processes involving the resonant contribution of an unstable particle. The basic idea is to factorise the whole process into the on-shell production and the subsequent decay of the resonant particle. The following picture in Fig. 1 visualises this splitting using the example of an arbitrary process abcef with an intermediate particle d.

Fig. 1.

Fig. 1

The resonant process abcef is split into the production abcd and decay def with particle d on-shell

In the following, we focus on scalar propagators. Nonetheless, although the production and decay are calculated independently, the spin of an intermediate particle can be taken into account by means of spin correlations [30, 31] giving rise to spin–density matrices. While we do not consider the non-zero spin case explicitly, the formalism of spin–density matrices should be applicable to the gNWA discussed below in the same way as for the sNWA.

Unstable particles and the total decay width

Since the total width Γ plays a crucial role in resonant production and decay, we will briefly discuss resonances and unstable particles, see e.g. Refs. [32, 33]. While stable particles are associated with a real pole of the S-matrix, for unstable particles the associated self-energy develops an imaginary part, so that the pole of the propagator is located off the real axis within the complex plane. For a single pole Mc, the scattering matrix as a function of the squared centre-of-mass energy s can be written in the vicinity of the complex pole in a gauge-invariant way as

M(s)=Rs-Mc2+F(s), 1

where R denotes the residue and F represents non-resonant contributions. Writing the complex pole as Mc2=M2-iMΓ, the mass M of an unstable particle is obtained from the real part of the complex pole, while the total width is obtained from the imaginary part. Accordingly, the expansion around the complex pole leads to a Breit–Wigner propagator with a constant width,

ΔW(q2):=1q2-M2+iMΓ. 2

In the following, we will use a Breit–Wigner propagator of this form to express the contribution of the unstable scalar d with mass M and total width Γ in the resonance region (a Breit–Wigner propagator with a running width can be obtained from a simple reparametrisation of the mass and width appearing in Eq. (2)).

The NWA is based on the observation that the on-shell contribution in Eq. (2) is strongly enhanced if the total width is much smaller than the mass of the particle, ΓM. Within its range of validity (see the discussion in the following section) the NWA provides an approximation of the cross section for the full process in terms of the product of the production cross section (or the previous step in a decay cascade) times the respective branching ratio:

σabcefσabcd×BRdef. 3

Conditions for the narrow-width approximation

The NWA can only be expected to hold reliably if the following prerequisites are fulfilled (see e.g. Refs. [8, 34]):

  • A narrow mass peak is required in order to justify the on-shell approximation. Otherwise off-shell effects may become large, cf. e.g. [24, 35, 36].

  • Furthermore, the propagator needs to be separable from the matrix element. However, loop contributions involving a particle exchange between the initial and the final state give rise to non-factorisable corrections. Hence, the application of the NWA beyond lowest order relies on the assumption that the non-factorisable and non-resonant contributions are sufficiently suppressed compared to the dominant contribution where the unstable particle is on resonance. Concerning the incorporation of non-factorisable but resonant contributions from photon exchange, see e.g. Ref. [37].

  • Both sub-processes have to be kinematically allowed. For the production of the intermediate particle, this means that the centre of mass energy s must be well above the production threshold of the intermediate particle with mass M and the other particles in the final state of the production process, i.e. sM+mc for the process shown in Fig. 1. Otherwise, threshold effects must be considered [38].

  • On the other hand, the decay channel must be kinematically open and sufficiently far above the decay threshold, i.e. Mmf, where mf are the masses of the particles in the final state of the decay process, here me+mf. Off-shell effects can be enhanced if intermediate thresholds are present. This is the case for instance for the decay of a Higgs boson with a mass of about 125 GeV into four leptons. Since for an on-shell Higgs boson of this mass this process is far below the threshold for on-shell WW and ZZ production, it suffers from a significant phase-space suppression. Off-shell Higgs contributions above the threshold for on-shell WW and ZZ production are therefore numerically more important than one would expect just from a consideration of Γ/M [39].

  • As another crucial condition, interferences with other resonant or non-resonant diagrams have to be small because the mixed term would be neglected in the NWA. The major part of the following chapters is dedicated to a generalisation of the NWA for the inclusion of interference effects of nearly mass degenerate states, see also Refs. [10, 28].

Factorisation of the phase space and cross section

In order to fix the notation used for the formulation of the gNWA in Sect. 3, we review some kinematic relations.

The phase space The phase space Φ is a Lorentz invariant quantity. Its differential is denoted as differential Lorentz invariant phase space (dlips) or dΦn. It is characterised by the number n of particles in the final state [40]

dΦndlipsP;p1,,pn=(2π)4δ(4)P-f=1npff=1nd3pf(2π)32Ef. 4

Factorisation Equation (3) is based on the property of the phase space and the matrix element to be factorisable into sub-processes. The phase space element dΦn with n particles in the final state as in Eq. (4) will now be expressed as a product of the k-particle phase space Φk with k<n and the remaining Φn-k+1 [40, 41],

dΦn=dΦkdq22πdΦn-k+1, 5

where q denotes the momentum of the resonant particle. Now Φk(q) can be interpreted as the production phase space Pp1,,pk-1,q and Φn-k+1(q) as the decay phase space qpk,,pn. The factorisation of dΦn is exact, no approximation has been made so far. Next, we rewrite the amplitude with a scalar propagator as a product of the production (P) and decay (D) part. Beyond the tree level, this is only possible if non-factorisable loop-contributions are absent or negligible,

M=MP1q2-M2+iMΓMD|M|2=|MP|21(q2-M2)2+(MΓ)2|MD|2. 6

One can distinguish two categories of processes. On the one hand, for a scattering process a,bX to any final state X (in particular a,bc,e,f for the example in Fig. 1), the flux factor is given by F=2λ1/2(s,ma2,mb2) with the kinematic function [41]

λ(x,y,z):=x2+y2+z2-2(xy+yz+zx). 7

On the other hand, for a decay process aX (for example ac,e,f), the flux factor is determined by the mass of the decaying particle, F=2ma. Then the full cross section is given as (the sum/average over spin states where appropriate is implicitly understood)

σ=1FdΦ|M|2. 8

For the decomposition into production and decay, we do not only factorise the matrix elements as in Eq. (6). Based on Eq. (5), also the phase space of the full process is factorised into the production phase space ΦP and the decay phase space ΦD (here defined for the example process in Fig. 1, but they can be generalised to other external momenta), which depend on the momentum of the resonant particle:

dΦ=dlips(s;pc,pe,pf)dΦP=dlips(s;pc,q)dΦD=dlips(q;pe,pf). 9

Under the assumption of negligible non-factorisable loop contributions, one can then express the cross section in (8) as

σ=1Fdq22πdΦP|MP|2×1(q2-M2)2+(MΓ)2dΦD|MD|2. 10

In this analytical formula of the cross section, the production and decay matrix elements and the sub-phase spaces are separated from the Breit–Wigner propagator. However, the full q2-dependence of the matrix elements and the phase space is retained. The off-shell production cross section of a scattering process with particles a,b in the initial state and the production flux factor F reads

σP(q2)=1FdΦP|MP(q2)|2. 11

The decay rate of the unstable particle, def, with energy q2 is obtained from the integrated squared decay matrix element divided by the decay flux factor FD=2q2,

ΓD(q2)=1FDdΦD|MD(q2)|2. 12

Hence one can rewrite the full cross section from Eq. (10) as

σ=dq22πσP(q2)2q2(q2-M2)2+(MΓ)2ΓD(q2). 13

In the limit where (ΓM)0 the Dirac δ-distribution emerges from the Cauchy distribution,

lim(MΓ)01(q2-M2)2+(MΓ)2=δ(q2-M2)πMΓ. 14

For the integration of the δ-distribution, the integral boundaries are shifted from qmax2,qmin2, i.e. the upper and lower bound on q2, respectively, to ± because the contributions outside the narrow resonance region are expected to be small. So this extension of the integral should not considerably alter the result. The zero-width limit implies that the production cross section, decay width and the factor q2 are evaluated on-shell at q2=M2. This applies both to the matrix elements and the phase space elements. The described approximation leads to the well-known factorisation into the production cross section times the decay branching ratio,

σ(MΓ)0-+dq22πσP(q2)2q2δ(q2-M2)πMΓΓD(q2)=σP(M2)·ΓD(M2)ΓσP·BR, 15

with the branching ratio BR=ΓD/Γ, where ΓD denotes the partial decay width into the particles in the final state of the considered process, and Γ is the total decay width of the unstable particle. While Eq. (15) has been obtained in the limit (MΓ)0, it is expected to approximate the result for non-zero Γ up to terms of O(ΓM).

Going beyond the approximation of Eq. (15) for the treatment of finite width effects, the on-shell approximation can be applied just to the matrix elements for production and decay (if both subprocesses are kinematically allowed, as mentioned in Sect. 2.2) while keeping a finite width in the integration over the Breit–Wigner propagator in the form of Eq. (13). This is gauge invariant and motivated by the consideration that the Breit–Wigner function is rapidly falling causing that only matrix elements close to the mass shell q2=M2 contribute significantly. It results in a modified NWA improved for off-shell effects, see e.g. Refs. [39, 42],

σ(ofs)=σP(M2)dq22π2M(q2-M2)2+(MΓ)2ΓD(M2). 16

Formulation of a generalised narrow-width approximation

Cross section with interference term

If all conditions in Sect. 2.2 are met, the NWA is expected to work reliably up to terms of O(ΓM). This section addresses the issue of how to extend the NWA such that interference effects can be included, leading to a generalised NWA [10, 28]. Interference effects can be large if there are several resonant diagrams whose intermediate particles are close in mass compared to their total decay widths:

|M1-M2|Γ1+Γ2. 17

In these nearly mass-degenerate cases, the Breit–Wigner functions Δ1BW(q2),Δ2BW(q2) overlap significantly, and an integral of the form

qmin2qmax2dq2Δ1BW(q2)Δ2BW(q2)·f(M,pi,) 18

is not negligible. The boundaries qmin2,qmax2 are the lower and upper limits of the kinematically allowed region of q2, and f summarises a possible dependence on matrix elements M and momenta pi in the phase space. Such interference effects might especially be relevant in models of new physics where an enlarged particle spectrum allows for more possibilities of mass degeneracies in some parts of the parameter space.

Let h1,h2 be two resonant intermediate particles, for example two Higgs bosons, with similar masses occurring in a process abcef, i.e. abchi,hief (cf. Fig. 1 with d=h1,h2). If non-factorisable loop corrections can be neglected, the full matrix element (dropping the q2-dependence of the matrix elements to simplify the notation) is given by (as mentioned above, see Sect. 2, we explicitly treat the case of scalar resonant particles; spin correlations of intermediate particles with non-zero spin can be taken into account using spin–density matrices)

M=Mabch11q2-M12+iM1Γ1Mh1ef+Mabch21q2-M22+iM2Γ2Mh2ef. 19

The squared matrix element contains the two separate contributions of h1,h2 and in the second line of Eq. (20) the interference term,

|M|2=|Mabch1|2|Mh1ef|2(q2-M12)2+M12Γ12+|Mabch2|2|Mh2ef|2(q2-M22)2+M22Γ22+2ReMabch1Mabch2Mh1efMh2ef(q2-M12+iM1Γ1)(q2-M22-iM2Γ2). 20

So the full cross section from Eq. (13) with the matrix element from Eq. (20) can be written as

σabcef=dq22πσabch1(q2)2q2Γh1ef(q2)(q2-Mh12)2+(Mh1Γh1)2+σabch2(q2)2q2Γh2ef(q2)(q2-Mh22)2+(Mh2Γh2)2+dlips(s;pc,q)dq2dlips(q;pe,pf)2π·2λ1/2(s,ma2,mb2)×2ReMabch1Mabch2Mh1efMh2ef(q2-M12+iM1Γ1)(q2-M22-iM2Γ2). 21

We will use Eq. (21) as a starting point for approximations of the full cross section. The first two terms can again be approximated by the finite-narrow-width approximation according to Eq. (16), or by the usual narrow-width approximation in the limit of a vanishing width from Eq. (15) as σ×BR. The interference term still consists of an integral over the q2-dependent matrix elements, the product of Breit–Wigner propagators and the phase space.

On-shell matrix elements

Our approach is to evaluate the production (P) and decay (D) matrix elements

Pi(q2)Mabchi(q2),Di(q2)Mhief(q2) 22

on the mass shell of the intermediate particle hi [28]. This is motivated by the assumption of a narrow resonance region [Mhi-Γhi,Mhi+Γhi] so that off-shell contributions of the matrix elements in the integral are suppressed by the non-resonant tail of the Breit–Wigner propagator if P and D vary only mildly1 with q2. Then the interference term from the last line of Eq. (21) is approximated by

σint=dΦPdq2dΦD2πF×2ReP1(q2)P2(q2)D1(q2)D2(q2)(q2-M12+iM1Γ1)(q2-M22-iM2Γ2) 23
=2FRedq22πΔ1BW(q2)Δ2BW(q2)×dΦP(q2)P1(q2)P2(q2)×dΦD(q2)D1(q2)D2(q2)2FRedq22πΔ1BW(q2)Δ2BW(q2)×dΦP(q2)P1(M12)P2(M22)×dΦD(q2)D1(M12)D2(M22). 24

Equation (24) represents our master formula for the interference contribution. At this stage, we have only evaluated the matrix elements on the mass shell of the particular Higgs boson by setting q2=Mhi2 (this is also important for ensuring the gauge invariance of the considered contributions). So the on-shell matrix elements can be taken out of the q2-integral. But the dependence of the matrix elements on further invariants and momenta is kept. For 2-body decays, it is possible to carry out the phase space integration without referring to the specific form of the matrix elements. In general, however, the matrix elements are functions of the phase space integration variables.

The approximation in Eq. (24) is a simplification of the full expression in Eq. (23) since the integrand of the q2-integral is simplified. We will use Eq. (24) in the numerical calculation of an example process in Sect. 5.

We will furthermore investigate additional approximations of the integral structure in Eq. (24), which would simplify the application of the gNWA. This issue is discussed at the tree level in the following section.

On-shell phase space and tree level interference weight factors

The following discussion, which focuses on the tree-level case, concerns a technical simplification of the master formula in Eq. (24). It will be numerically applied in Fig. 5 below and extended to the 1-loop level in Sect. 7. As a possible further simplification on top of the on-shell approximation for matrix elements, one can also evaluate the production and decay phase spaces on-shell. This is based on the same argument as for the on-shell evaluation of the matrix elements because off-shell phase space elements are multiplied with the non-resonant tail of Breit–Wigner functions. Now the q2-independent matrix elements and phase space integrals can be taken out of the q2-integral,

σint2FRedΦPP1(M12)P2(M22)×dΦDD1(M12)D2(M22)×dq22πΔ1BW(q2)Δ2BW(q2). 25

The choice at which mass, M1 or M2, to evaluate the production and decay phase space regions is not unique. We thus introduce a weighting factor between the two possible processes, as an ansatz based on their production cross sections and branching ratios:

wi:=σPiBRiσP1BR1+σP2BR2. 26

Then we define the on-shell phase space regions as

dΦP/D:=w1dΦP/D(q2=M12)+w2dΦP/D(q2=M22). 27

In Eq. (25), a universal integral over the Breit–Wigner propagators emerges:

I:=qmin2qmax2dq22πΔ1BW(q2)Δ2BW(q2), 28

which is analytically solvable,

I=arctanΓ1M1M12-q2+arctanΓ2M2M22-q2+i2(ln[Γ12M12+(M12-q2)2]-ln[Γ22M22+(M22-q2)2])2πi(M12-M22-i(M1Γ1+M2Γ2))qmin2qmax2. 29

In the limit of equal masses and widths, M=M1=M2 and Γ=Γ1=Γ2, the product of Breit–Wigner propagators would become the absolute square, and the integral is reduced to

I(M,Γ)=qmin2qmax2dq21(q2-M2)2+(MΓ)2=-1MΓarctanM2-q2MΓqmin2qmax2. 30

This absolute square of the Breit–Wigner function is also present in the usual NWA in Eq. (14), and for vanishing Γ it can be approximated by a δ-distribution. Here, however, we allow for different masses and widths from the two resonant propagators. We evaluate only the matrix elements and differential phase space on-shell, but we do not perform a zero-width approximation. This approach is analogous to the finite-narrow-width approximation without the interference term in Eq. (16).

Fig. 5.

Fig. 5

The 13 decay width of χ~40χ~10τ+τ- at tree level with contributions from hH including their interference (black) confronted with the NWA: sNWA without the interference term (grey, dotted), gNWA including the interference term based on on-shell matrix elements denoted by M (red, dashed) and on the R-factor approximation denoted by R (blue, dash-dotted)

Under the additional assumption of equal masses, the interference part can be approximated in terms of cross sections, branching ratios and couplings in order to avoid the explicit calculation of the product of unsquared amplitudes and their conjugates. This will also avoid the phase space integrals in the interference term as in Eq. (25).

For this purpose, each matrix element is written as the coupling of the particular production or decay process, CPi or CDi, times the helicity part p(Mi2) or d(Mi2), respectively,

Pi(Mi2)=CPip(Mi2),Di(Mi2)=CDid(Mi2). 31

The on-shell calculation of helicity matrix elements is demonstrated in Sect. 5.3 where also left- and right-handed couplings are distinguished. Here we use the schematic notation of Eq. (31), but it could directly be replaced by the L/R-sum as in Eq. (75) below.

If we then make the additional assumption M1M2, the helicity matrix elements coincide, p(M12)p(M22), d(M12)d(M22), thus the matrix elements differ just by fractions of their couplings,

P2(M22)CP2CP1P1(M12),D2(M22)CD2CD1D1(M12). 32

This enables us to replace the products of an amplitude involving the resonant particle 1 with a conjugate amplitude of resonant particle 2 by absolute squares of amplitudes as follows, where i,j{1,2}, ij, and no summation over indices is implied:

σint(25)2Re1FdΦPP1P212MidΦDD1D2×2Midq22πΔ1BW(q2)Δ2BW(q2) 33
(31)2Re1FdΦP|Pi|2CPjCPi12MidΦD|Di|2CDjCDi×2Midq22πΔ1BW(q2)Δ2BW(q2) 34
=(11,12)σPiΓDi·2Mi·2Re×CPjCDjCPiCDidq22πΔ1BW(q2)Δ2BW(q2) 35
=σPiBRi·2MiΓi·2Rexi·I. 36

In the last step, we divided and multiplied by the total width Γi to obtain the branching ratio BRi=ΓDiΓi. The universal integral I over the overlapping Breit–Wigner propagators is given in Eq. (28). Furthermore, we defined a scaling factor as the ratio of couplings [10, 28, 29],

xi:=CPjCDjCPiCDi=CPiCPjCDiCDj|CPi|2|CDi|2. 37

Using Eq. (36) and the scaling factor xi with i=1,j=2 or vice versa allows to express σint alternatively in terms of the cross section, branching ratio, mass and width of either of the resonant particle 1 or 2. Since no summation over i or j is implied in Eq. (36), both contributions are accounted for by the weighting factor wi[0,1] from Eq. (26).

Next, we summarise the components of σint apart from σPi and BRi, which also occur in the usual NWA, in an interference weight factor

Ri:=2MiΓiwi·2RexiI. 38

Hence, in this approximation of on-shell matrix elements and production and decay phase spaces with the additional condition of equal masses, the interference contribution can be written as the weighted sum

σintσP1BR1·R1+σP2BR2·R2, 39

or in terms of only one of the resonant particles,

σintσPiBRi·2R~i, 40
R~i:=2MiΓi·RexiIRi2wi. 41

Finally, we are able to express the cross section of the complete process in this R-factor approximation, comprising the exchange of the resonant particles 1 and 2 as well as their interference, in the following compact form

σσP1BR1·(1+R1)+σP2BR2·(1+R2) 42
σPiBRi·(1+2R~i)+σPjBRj 43

Furthermore, it is possible to replace the term σiBRi in the two separate processes without the interference term by the finite-width integral from Eq. (16).

Discussion of the steps of approximations

In the previous sections, we presented two levels of approximations for the interference term with two resonant particles. The first approximation in Sect. 3.2 represents our main result. It relies only on the on-shell evaluation of the matrix elements, justified by a narrow resonance region, but no further assumptions (beyond those already used in the sNWA) are implied. Different masses and finite widths are taken into account. This version requires the explicit calculation of unsquared on-shell amplitudes, preventing the use of e.g. convenient spinor trace rules. Furthermore, the phase space integration depends on q2 so that the universal, process-independent Breit–Wigner integral I from Eq. (28) does not appear here.

The second approximation in Sect. 3.3 has been formulated only at tree level so far. It is based on the additional approximation, motivated by the same argument as for the matrix elements, of setting the differential Lorentz invariant phase spaces on-shell at either mass, scaled by a weighting factor. This makes the q2-integration easier because only the universal integral I is left. Furthermore, it avoids the unusual calculation of on-shell amplitudes in an explicit representation by expressing the interference part as an interference weight factor R in terms of cross sections, branching ratios, masses and widths, which are already needed in the simple NWA, plus the universal integral I and a scaling factor x which consists of the process-specific couplings. Yet, this approximation holds only for equal masses. As discussed in the context of Eq. (18), the interference term is largest if the Breit–Wigner shapes overlap significantly due to the relation ΔMΓ1+Γ2. Nevertheless, the masses are not necessarily equal in the interference region. Instead, the overlap criterion in Eq. (17) can as well be satisfied if one of the widths is relatively large. In this respect, the equal-mass condition is more restrictive than the overlap criterion. However, the equal-mass constraint is just applied on the matrix elements and phase space, whereas different masses and widths are distinguished in the Breit–Wigner integral. The R-factor method is technically easier to handle because the constituents of R can be obtained by standard routines in the program packages such as FormCalc [4347] and FeynHiggs [4851] that we use in the numerical computation. For one example process, this is done in Sect. 5. An extension of the generalised narrow-width approximation to the 1-loop level is discussed in Sect. 7.

Particle content and mixing in the MSSM

Before we discuss the application of the gNWA to an example process within the MSSM, we briefly summarise here the different particle sectors of the MSSM in order to clarify the notation and conventions.

Propagator mixing in the Higgs sector

Higgs sector at tree level The MSSM contains two Higgs doublets,

H1=H11H12=v1+12(ϕ10-iχ10)-ϕ1-,H2=H21H22=ϕ2+v2+12(ϕ20+iχ20), 44

with the vacuum expectation values v1,v2, respectively, whose ratio tanβv2v1 determines together with MH± (or MA) the MSSM Higgs sector at tree level. In principle, complex parameters can enter through loops, but in this methodical study we consider the MSSM with real parameters. The neutral fields ϕ10,ϕ20,χ10,χ20 are rotated into the mass eigenstates hHAG, where h and H are neutral CP-even Higgs bosons (rotated from ϕ10,ϕ20 by the mixing angle α), A is the neutral CP-odd Higgs boson and G denotes the neutral Goldstone boson. Besides, there are the charged Higgs and Goldstone bosons, H±,G±.

Mixing in the MSSM Higgs sector Higher-order corrections have a crucial impact on the phenomenology in the Higgs sector. We adopt the renormalisation scheme in the Higgs sector from Refs. [52, 53], where MA (or MH±) is renormalised on-shell while a DR¯-renormalisation is used for the Higgs fields and tanβ. For the prediction of the considered process we incorporate important higher-order corrections from the Higgs sector already at the Born level by using for the Higgs-boson masses and total decay widths the predictions from FeynHiggs [4851], which contain the full one-loop and dominant two-loop contributions.

Furthermore, because of the presence of off-diagonal self-energies like Σ^ij with i,j=h,H,A, the propagators of the neutral Higgs bosons mix with each other and in general also with contributions from the gauge and Goldstone bosons, see e.g. Refs. [52, 53]. The Higgs-boson masses therefore have to be determined from the complex poles of the Higgs propagator matrix.

For correct on-shell properties of external Higgs bosons the residues of the propagators have to be normalised to one. This is achieved by finite wave function normalisation factors, which can be collected in a matrix Z^, such that for a one-particle irreducible vertex Γ^i with an external Higgs boson i the effect of Higgs mixing amounts to

Γ^iZ^ihΓ^h+Z^iHΓ^H+Z^iAΓ^A+, 45

where the ellipsis indicates the mixing with the Goldstone and Z-bosons, which are not comprised in the Z^-factors, but have to be calculated explicitly. The (non-unitary) matrix Z^ can be written as (see Ref. [53])

Z^=Z^hZ^hZ^hHZ^hZ^hAZ^HZ^HhZ^HZ^HZ^HAZ^AZ^AhZ^AZ^AHZ^A, 46

with

Z^i=1p2iΔii|p2=Mca2,Z^ij=Δij(p2)Δii(p2)|p2=Mca2, 47

where the wave function normalisation factors are evaluated at the complex poles

Mca2=Mha2-iMhaΓha 48

for a=1,2,3. We choose a=1 for i=h, a=2 for i=H and a=3 for i=A. Mha is the loop-corrected mass and Γha the total width of ha. In the CP-conserving case, the Z^-matrix is reduced to the 2×2 mixing between h and H.

An amplitude involving resonant Higgs-boson propagators therefore needs to incorporate in general the full loop-corrected propagator matrix (and also the mixing contributions with the gauge and Goldstone bosons). It can be shown [10, 54] that in the vicinity of the resonance the full propagator matrix contribution can be approximated by

i,jΓ^iAΔij(p2)Γ^jBα,i,jΓ^iAZ^αiΔαBW(p2)Z^αjΓ^jB, 49

involving the Breit–Wigner propagator ΔαBW(p2) as given in Eq. (2), where Γ^iA,Γ^jB are the one-particle irreducible vertices AB of the Higgs bosons i,j, and i,j,α=h,H,A are summed over.

The neutralino and chargino sector

The superpartners of the neutral gauge and Higgs bosons mix into the four neutralinos χ~i0, i=1,2,3,4, as mass eigenstates whose mass matrix is determined by the bino, wino and higgsino mass parameters M1,M2,μ and the parameter tanβ,

Mχ~0=M10-MZcβsWMZsβsW0M2MZcβcW-MZsβcW-MZcβsWMZcβcW0-μMZsβsW-MZsβcW-μ0. 50

The admixture of gauginos and higgsinos in each neutralino can be determined from the components of the matrix N which diagonalises Mχ~0 by NMχ~0N-1.

The charginos χ~i±,i=1,2, as mass eigenstates are superpositions of the charged wino and higgsino,

Mχ~±=M22MWsβ2MWcβμ. 51

The chosen example process requires the couplings at the Higgs–neutralino–neutralino and the Higgs–fermion–fermion vertices. For the neutralinos χ~i0,χ~j0 with i,j=1,2,3,4 and the neutral Higgs bosons hk={h,H,A,G} for k=1,2,3,4, the right-handed CR and left-handed CL neutralino-Higgs couplings are given by

CRijk=-CLijk=ie2cWsWcijk,withcijk=(-sαNi3-cαNi4)(sWNj1-cWNj2)+(ij),k=1,(+cαNi3-sαNi4)(sWNj1-cWNj2)+(ij),k=2,(+isβNi3-icβNi4)(sWNj1-cWNj2)+(ij),k=3,(-icβNi3-isβNi4)(sWNj1-cWNj2)+(ij),k=4, 52

where sαsinα,cαcosα and likewise for β. With the left-/right-handed projection operators ωR/L12(1±γ5), the 3-point function of the neutralino-Higgs vertex is at tree level composed of

Γχ~10,χj,hktree=ωRCRijk±ωLCLijk, 53

where the + applies to the CP-even Higgs bosons h and H, whilst the - appears for the CP-odd Higgs boson A and the Goldstone boson G. Mixing of Higgs bosons is taken into account by a linear combination of the couplings and Z-factors (see Sect. 4.1). In the following, the couplings ChkXY always mean the mixed couplings (for k,l,m=1,2,3; no summation over indices implied),

ChkXYZ^hkhkChkXY+Z^hkhlChlXY+Z^hkhmChmXY. 54

For the calculation of higher-order corrections to the neutralino-chargino sector, it is essential to identify a stable renormalisation scheme according to the gaugino parameter hierarchy of M1,M2 and μ as it was pointed out in Refs. [10, 55, 56]. Choosing the external neutralinos and charginos in the considered process to be on-shell does not necessarily lead to the most stable renormalisation scheme. Among the four neutralinos and two charginos, three can be renormalised on-shell in relation to the three gaugino parameters M1,M2 and μ. The most bino-, wino- and higgsino-like states should be chosen on-shell so that the three parameters are sufficiently constrained by the renormalisation conditions. Otherwise, an unstable choice of the input states can lead to unphysically large values for the parameter counterterms and mass corrections. On-shell renormalisation conditions were derived in Refs. [55, 5763] for the MSSM with real parameters and in Refs. [56, 64, 65] for the complex case. Schemes with two charginos and one neutralino on-shell are referred to as NCC, with one chargino and two neutralinos as NNC and with three neutralinos input states as NNN. In view of our example process (see Sect. 5) and the gaugino hierarchy of the scenario, we will comment on our choice of a renormalisation scheme in Sect. (8.1.1).

The sfermion and the gluino sectors

The mixing of sfermions f~L,f~R within one generation into mass eigenstates f~1,f~2 is parametrised by the matrix

Mf~=Mf~L2+mf2+MZ2cos2β(I3f-QfsW2)mfXfmfXfMf~R2+mf2+MZ2cos2βQfsW2, 55
Xf:=Af-μ·cotβ,f=up-typetanβ,f=down-type. 56

The trilinear couplings Af as well as μ can be complex. Their phases enter the Higgs sector via sfermion loops, but as mentioned above here we only take real parameters into account. The sfermion masses at tree level are the eigenvalues of Mf~. In the considered example process with hH decaying into τ+τ-, the couplings of Higgs bosons to τ-leptons are involved,

Chττtree=+igmτsα2MWcβ,CHττtree=-igmτcα2MWcβ. 57

The mass of the gluino g~ is given by |M3|.

Generalised narrow-width approximation at leading order: example process χ~40χ~10h/Hχ~10τ+τ-

The gNWA will be validated for a simple example process. The focus lies on providing a test case for the method rather than on the phenomenology of the process itself. For a comparison with the gNWA, we choose a process which can be calculated also at the 1-loop level without the on-shell approximation.

In the following, we will consider Higgs production from the decay of the heaviest neutralino and its subsequent decay into a pair of τ-leptons, χ~40χ~10h/Hχ~10τ+τ-, which is a useful example process because it is computable as a full 3-body decay and it can be decomposed into two simple 2-body decays, see Fig. 2.

Fig. 2.

Fig. 2

χ~40χ~10τ+τ- with h or H as intermediate particle in the two interfering diagrams. The decay process is either considered as a one 3-body decay or b decomposed in two 2-body decays

Moreover, the intermediate particles are scalars. Thus, for this process the treatment of interference effects can be trivially disentangled from any spin correlations between production and decay. Due to the neutralinos in the initial state and in the first decay step, soft bremsstrahlung only appears in the final state, and there is no photon exchange between the initial and final state. Restricting this test case to the MSSM with real parameters, only the two CP-even states hH mix due to CP-conservation, instead of the 3×3 mixing of hHA in the complex case. We neglect non-resonant diagrams from sleptons, which is a good approximation for the case of heavy sleptons. Slepton contributions to neutralino 3-body decays have been analysed in Ref. [63]. As a first step, we also neglect the exchange of an intermediate pseudoscalar A, Goldstone boson G and Z-boson for the purpose of a pure comparison of the factorised and the full Higgs contribution. For the most accurate prediction within the gNWA, which will be discussed in Sect. 9.4, we will add the tree-level AG- and Z-exchange, but they do not interfere with h and H in the case of real parameters.

The decay width will be calculated using FeynArts [6670] and FormCalc [4347]2 both as a 3-body decay with the full matrix element and in the narrow-width approximation as a combination of two 2-body decays – with and without the interference term. In this and the following section, the gNWA will be applied at the tree level. The application at the loop level will follow conceptually in Sect. 8 and numerically in Sect. 9.

3-body decays: leading order matrix element

In order to compare the gNWA to the unfactorised LO result, we calculate the amplitude Mhk of the 3-body decay via hk=h,H. From the matrix element of the form

Mhk=iChkχ~i0χ~j0Chkττu¯(p4,s4)v(p3,s3)×1q2-Mhk2+iMhkΓhku¯(p2,s2)u(p1,s1) 58

we obtain the spin-averaged, squared amplitude consisting of the separate hH contributions and the interference contribution,

|M|2¯=(p1·p2+mχ~10mχ~40)(p3·p4-mτ2)×|Chχ~10χ~40|2|Chττ|2(q2-mh2)2+mh2Γh2+|CHχ~10χ~40|2|CHττ|2(q2-mH2)2+mH2ΓH2+2ReChχ~10χ~40CHχ~10χ~40ChττCHττ·ΔhBW(q2)ΔHBW(q2), 59

where the momenta and masses are labelled as p1p2,p3,p4 with m1mχ~40,m2mχ~10,m3=m4mτ. In order to calculate the decay width in one of the Gottfried-Jackson frames [30], the products of momenta are rewritten in terms of two combined invariant masses, here e.g. m23,m24:

p1·p2=12(m232+m242)-mτ2,p3·p4=12(m12+m22-m232-m242),q2=(p1-p2)2=m12+m22-m232-m242. 60

This yields the partial decay width for the 3-body decay [40],

Γ=1(2π)3132mχ~403|M|2dm232dm242 61

which we will use for a comparison with the gNWA.

Decomposition into 2-body decays

In this section, we calculate the 2-body decay widths of the subprocesses needed in the NWA. The matrix element for the production of hk=h,H is

Mχ~40χ~10hk=iu¯2Chkχ~40χ~10u1, 62
|Mχ~40χ~10hk|2¯=|Chkχ~40χ~10|22(p1·p2+mχ~40mχ~10). 63

In the rest frame of χ~40 we have p1·p2=m1E2 with

E2=m12+m22-Mhk22m1. 64

Then the decay width of χ~40χ~10hk for the production of hk=h,H equals

Γ(χ~40χ~10hk)=|Chkχ~40χ~10|216πmχ~403((mχ~40+mχ~10)2-Mhk2)×(mχ~402-mχ~102-Mhk2)2-4mχ~102Mhk2. 65

Summing over spins in the final states, the partial decay widths of h and H into a pair of τ-leptons and the branching ratios are at tree level, improved by 2-loop Higgs masses and total widths from FeynHiggs [4851],

Γ(hkττ)=1π|Chkττ|2Mhk24-mτ23/2Mhk2,BRk=Γ(hkτ+τ-)Γhktot, 66

where Γhktot is the total width. Loop-corrections to the partial decay widths of these subprocesses are calculated with FormCalc [4347] in Sect. 9.1.

Unsquared matrix elements

For the calculation of the interference term according to Eq. (24), we need the on-shell matrix elements of the production and decay part. Instead of evaluating absolute values of squared, spin-averaged matrix elements by applying spinor traces, we now aim at expressing the unsquared matrix elements explicitly in order to evaluate them on the appropriate mass shell. Therefore, we need to represent spin wave functions in terms of energy and mass. Following Ref. [71], a Dirac spinor with an arbitrary helicity can be written as

u(p)=E+mχE-mσ·p^χ, 67

where χ is a two-component spinor. The eigenstates χ of the helicity operator σ·p^ with eigenvalues λ=±12 satisfy

12σ·p^χλ=λχλ. 68

For the unit vector p^ in the direction parametrised by the polar angle θ and azimuthal angle ϕ relative to the z-axis, the two-component spinors are expressed as

χ+1/2(p^)=cosθ2eiϕsinθ2,χ-1/2(p^)=-e-iϕsinθ2cosθ2. 69

For the specific choice of pez we have θ=0 and ϕ is arbitrary so that it can be set to 0. Thus, the 2-spinors take the simpler form

χ1/2(p^=ez)=e110,χ-1/2(p^=ez)=e201. 70

We label the unit vectors in space as ex,ey,ez whereas the basis of the 2-spinors is denoted by e1,e2. The two-component spinors in the opposite momentum direction p^=-ez are constructed using

χ-λ(-p^)=ξλχλ(p^) 71

from Ref. [71] with ξλ=1 in the Jacob-Wick convention for a second particle spinor [72], resulting in

χ+1/2(-ez)=e2,χ-1/2(-ez)=e1. 72

Defining ϵ+:=E+m and ϵ-:=E-m for a simpler notation, we can rewrite the particle and antiparticle four-component spinors as

uλ(p)=ϵ+χλ(p^)2λϵ-χλ(p^)=ρλψλ,vλ(p)=ϵ-χ-λ(p^)-2λϵ+χ-λ(p^)=σλφλ. 73

Here we introduced the nomenclature ρ/ψ for the upper/lower 2-spinor within a particle 4-spinor u and likewise σ/φ for an antiparticle v. For later use, we now list the combinations of λ=±12 and p^=±ez explicitly:

u+(ez)=ϵ+e1ϵ-e1,u-(ez)=ϵ+e2-ϵ-e2,u+(-ez)=ϵ+e2ϵ-e2,u-(-ez)=ϵ+e1-ϵ-e1,v+(ez)=ϵ-e2-ϵ+e2,v-(ez)=ϵ-e1ϵ+e1,v+(-ez)=ϵ-e1-ϵ+e1,v-(-ez)=ϵ-e2ϵ+e2. 74

In the following, we will apply this formalism to Higgs production and decay within our example process.

Higgs production As illustrated in Fig. 2b, the incoming spinor u1 (in the example case χ~40) decays into u2 (χ~10) and a scalar (h / H). The matrix element P of this production process is decomposed into a right- and left-handed part,

P=u¯2CRωRu1+u¯2CLωLu1, 75

where CR/L are form factors. Using γ0,γ5 in the Dirac representation, and the 2-spinor notation introduced in Eq. (73), we calculate the spinor chains with arbitrary helicity of λ1,λ2=±12,

pR:=u¯2ωRu1=12(ρ2-ψ2)(ρ1+ψ1), 76
pL:=u¯2ωLu1=12(ρ2+ψ2)(ρ1-ψ1). 77

Given the 2-body decay in the rest frame of particle 1, it follows that E1=m1 and consequently ϵ-=0,ψ1=0. In order to obtain the helicity matrix elements pR/Lλ2λ1, we insert the explicit spinors from Eq. (74) into the generic Eq. (77):

pR++=u¯2+ωRu1+=12(ϵ2+-ϵ2-)ϵ1+e1·e1=12E2+m2-E2-m22m1,pL++=12E2+m2+E2-m22m1,pR--=pL++,pL--=pR++,pR/L+-=pR/L-+e1·e20. 78

Since the helicity matrix elements are real, their complex conjugates pR/L=u¯1ωL/Ru2 are equal to the results in Eq. (78). The products of matrix elements are summed over all helicity combinations (but no averaging is done yet), with i,jR,L, leading to3

Aij:=λ1,λ2=±1/2pi·pj, 79
ARR=ARR+++ARR--=2m1E2=m12+m22-M2,ALL=ALL+++ALL--=ARR,ARL=ARL+++ARL--=2m1m2,ALR=ALR+++ALR--=ARL, 80

where the energy relation of a 2-body decay with m1m2,M was applied:

E2=m12+m22-M22m1. 81

Finally, the squared production matrix element is constructed as

PP=i,j=R,LCiCjAij=(|CR|2+|CL|2)(m12+m22-M2)+(CRCL+CLCR)2m1m2. 82

If the left- and right-handed form factors coincide (CL=CRC), Eq. (82) is reduced to

(PP)C=2|C|2((m1+m2)2-M2). 83

However, in the interference term we need the product PhPH with different Higgs masses in E2 from Eq. (81). This distinction leads to

Aij=λ1,λ2=±1/2pihpjH, 84
ARR=ALL=m1(ϵ2+hϵ2+H+ϵ2-hϵ2-H), 85
ARL=ALR=m1(ϵ2+hϵ2+H-ϵ2-hϵ2-H). 86

As before, we give the resulting product of matrix elements for the independent CR/L and for simpler use in the special case of CR/LC,

PhPH=(CRhCRH+CLhCLH)m1(ϵ2+hϵ2+H+ϵ2-hϵ2-H)+(CRhCLH+CLhCRH)m1(ϵ2+hϵ2+H-ϵ2-hϵ2-H) 87
C4ChCHm1ϵ2+hϵ2+H=2ChCH×(m1+m2)2-Mh2(m1+m2)2-MH2. 88

Eq. (87) shows that the method of on-shell matrix elements enables us to distinguish between different masses of the intermediate particles, in this example Mh and MH.

Higgs decay In the decay of a Higgs boson into a pair of fermions, the representation of antiparticle spinors from Eq. (74) is also needed. Furthermore, the fermions are generated back to back in the rest frame of the decaying Higgs boson. So if we align the momentum direction of the particle spinor u4 with the z-axis, p^4=ez, the momentum of the antiparticle spinor v3 points into the direction of p^3=-ez.

Analogously to Eq. (75), the decay matrix element is in general composed of a left- and right-handed part,

D=u¯4CRωRv3+u¯4CLωLv3, 89
dR:=u¯4(ez)ωRv3(-ez)=12(ρ4-ψ4)(σ3+φ3), 90
dL:=u¯4(ez)ωRv3(-ez)=12(ρ4+ψ4)(σ3-φ3). 91

With the mass M of the decaying Higgs boson, the fermion masses m3=m4m and the resulting energies E3=E4M2, the spinor chains dR,dL are now calculated for all helicity configurations of λ3,λ4=±12,

dR++=dL--=E2-m2-E,dL++=dR--=E2-m2+E,dR/L+-=dR/L-+=0. 92

Summing over all helicity combinations, we obtain

ARR=ALL=M2-2m2,ARL=ALR=-2m2. 93

So the product of on-shell decay matrix elements results in

DD=(|CR|2+|CL|2)(M2-2m2)-(CRCL+CLCR)2m2. 94

In case of identical left- and right-handed couplings C of the decay vertex, Eq. (94) simplifies to

DD=2|C|2(M2-4m2). 95

As in the production case, we are interested in the contribution to the on-shell interference term, so we distinguish between Eh=Mh2 and EH=MH2,

ARR=ALL=2(Eh2-m2)(EH2-m2)+EhEH,ARL=ALR=2(Eh2-m2)(EH2-m2)-EhEH. 96

Finally, the product of decay matrix elements with different masses reads

DhDH=2(CRhCRH+CLhCLH)×(Eh2-m2)(EH2-m2)+EhEH+2(CRhCLH+CLhCRH)×(Eh2-m2)(EH2-m2)-EhEH 97
C8ChCHMh24-m2MH24-m2, 98

where the last line applies for identical L / R form factors.

The outcome of the explicit spinor representations in the context of factorising a longer process into production and decay is the possibility to express the interference term with on-shell matrix elements depending on the mass of the intermediate particle. The method was here introduced in a generic way and then applied to the example of Higgs production and decay with two external fermions in each subprocess in the rest frames of the decaying particles.

Numerical evaluation at lowest order

Modified Mhmax scenario

In order to apply the gNWA to the example process of χ~40χ~10h/Hχ~10τ+τ- numerically, we specify a scenario. In this study, we restrict the MSSM parameters to be real so that there is no new source of CP-violation compared to the SM and only the two CP-even neutral Higgs bosons, h and H, mix and interfere with each other. The aim here is not to determine the parameters which are currently preferred by recent limits from experiments, but to provide a setting in which interference effects between h and H become large in order to investigate the performance of the generalised narrow-width approximation for this simple example process.

The Mhmax scenario [73, 74] is defined such that the loop corrections to the mass Mh reach their maximum for fixed tanβ,MA and MSUSY. This requires a large stop mixing, i.e. a large off-diagonal element Xt of the stop mixing matrix in Eq. (55). A small mass difference ΔMMH-Mh requires a rather low value of MA, or equivalently MH±, and a high value of tanβ. On the other hand, tanβ must not be chosen too large because otherwise the bottom Yukawa coupling would be enhanced to an non-perturbative value. We modify the Mhmax scenario such that Mh is not maximised, but the mass difference ΔM is reduced by raising Xt. As one of the Higgs sector input parameters, we choose MH± for a later extension to CP-violating mixings instead of MA, which is more commonly used in the MSSM with real parameters. The charged Higgs mass is scanned over the range MH±[151 GeV, 155 GeV]. The other parameters are defined in Table 1, and we assume universal trilinear couplings Af=At.

Table 1.

Parameter settings of the modified Mhmax scenario in the numerical analysis. A value in brackets indicates that the parameter is varied around this central value

M1 M2 M3 MSUSY Xt μ tβ MH±
100 GeV 200 GeV 800 GeV 1 TeV 2.5 TeV 200 GeV 50 (153 GeV)

Under variation of the input Higgs mass MH±, the resulting masses and widths of the interfering neutral Higgs bosons hH change as shown in Fig. 3 with results from FeynHiggs [4851] including dominant 2-loop corrections. Figure 3(a) displays the dependence of the masses of h (blue, dotted) and H (green, dashed) on MH±. Within the analysed parameter range of MH±=151155GeV, their mass difference ΔM (red) in Fig. 3b is around its minimum at MH±153GeV smaller than both total widths Γh (blue, dotted) and ΓH (green, dashed). While Γh decreases, ΓH increases with increasing MH±. This is caused by a change of the predominantly diagonal or off-diagonal structure of the Z^-matrix which has a cross-over around MH±153 GeV in this scenario. Since both widths contribute to the overlap of the two resonances, the ratio RMΓ=ΔM/(Γh+ΓH) gives a good indication of the parameter region of most significant interference. This is visualised (in orange) in Fig. 3c and compared to the ratios ΔM/Γh (blue, dotted) and ΔM/ΓH (green, dashed), which only take one of the widths into account and are therefore a less suitable criterion for the importance of the interference term. Figure 3d presents the ratio Γi/Mi for i=h (blue, dotted) and H (green, dashed) as a criterion for a narrow width. Both ratios lie in the range of about 0.5–3.5%, and this represents the expected order of the NWA uncertainty.

Fig. 3.

Fig. 3

Higgs masses and widths from FeynHiggs [4851] including dominant 2-loop corrections in the modified Mhmax scenario. a Higgs masses Mh (blue, dotted) and MH (green, dashed). b Mass difference ΔMMH-Mh (red) compared to total widths Γh (blue, dotted) and ΓH (green, dashed). c Mass difference ΔM divided by total width of h (blue, dotted), H (green, dashed) and sum of both widths (orange). d Ratio Γi/Mi for h (blue, dotted) and H (green, dashed)

Results for tree level process χ~40χ~10h/Hχ~10τ+τ-

In order to understand the possible impact of interference terms, we confront the prediction of the standard NWA with the 3-body decay width of our example process χ~40χ~10τ+τ- at the tree level (improved by 2-loop predictions for the masses, widths and Z^-factors) in the modified Mhmax scenario.

First of all, we verify that the other conditions from Sect. 2.2 for the NWA are met. The widths of the involved Higgs bosons do not exceed 3.5% of their masses, hence they can be considered narrow (see Fig. 3). At tree level, there are no unfactorisable contributions so that the scalar propagator is separable from the matrix elements. Besides, our scenario is far away from the production and decay thresholds since Mhk2mτ holds independently of the parameters, and with neutralino masses of mχ~40264.9GeV and mχ~1092.6GeV, also mχ~40-(mχ~10+Mhk)>32GeV does not violate the threshold condition. The neutralino masses are independent of MH±. Thus, the NWA is applicable for the individual contributions of h and H, so the factorised versions

ΓNWAi:=ΓPi(χ~40χ~10hi)BRi(hiτ+τ-) 99

should agree with the separate terms of the 3-body decays via the exchange of only one of the Higgs bosons, hi,

Γ13i:=Γ(χ~40hiχ~10τ+τ-) 100

within the uncertainty of OΓhiMhi. This is tested in Fig. 4. The blue lines compare Γ13h (solid) with the factorised process ΓNWAh (dotted), the green lines represent the corresponding expressions for H. The standard narrow-width approximation is composed of the incoherent sum of both factorised processes, i.e.,

ΓsNWA=ΓPhBRh+ΓPHBRH. 101

This is confronted with the incoherent sum of the 3-body decays which are only h-mediated or H-mediated. For a direct comparison with the sNWA, the interference term is not included,

Γ13incoh=Γ13h+Γ13H. 102

The sNWA (dotted) and the incoherent sum of the 3-body decay widths are both shown in grey. Their relative deviation of 0.8–3.3 % is of the order of the ratio Γ/M from Fig. 3d. Consequently, the NWA is applicable to the terms of the separate h / H-exchange within the expected uncertainty.

Fig. 4.

Fig. 4

The 13 decay width (solid) of χ~40χ~10τ+τ- at tree level with separate contributions from h (blue), H (green) and their incoherent sum (grey) confronted with the sNWA (dotted)

However, the fifth condition in Sect. 2.2 concerns the absence of a large interference with other diagrams. But with ΔM<Γh+ΓH throughout the analysed parameter range (see Fig. 3c), we expect a sizeable interference effect in this scenario owing to a considerable overlap of the Breit–Wigner propagators and a sizeable mixing between h and H. Since the masses and widths of the interfering Higgs bosons depend on MH±, the size of the interference term varies with the input charged Higgs mass. Based on the minimum of the ratio RΓM=ΔM/(Γh+ΓH) and a significant mixing between h and H, we expect the most significant interference contribution near MH±=153 GeV.

Figure 5 presents the partial decay width Γ(χ~40χ~10τ+τ-) in dependence of the input Higgs mass MH±. In the sNWA (grey), the interference term is absent. In contrast, the full 3-body decay4 (black) takes the h and H propagators and their interference into account.

Comparing the prediction of the sNWA with the full 3-body decay width reveals an enormous discrepancy between both results, especially in the region of the smallest ratio RΓM around MH±153GeV, due to a large negative interference term. Consequently, the NWA in its standard version is insufficient in this parameter scenario.

In the generalised narrow-width approximation, on the other hand, the sNWA is extended by incorporating the on-shell interference term. The red line indicates the prediction of the complete process in the gNWA using the on-shell evaluation of unsquared matrix elements in the interference term as derived conceptually in Eq. (24) and explicitly in Sect. 5.3. Furthermore, the blue line demonstrates the result of the gNWA using the additional approximation of interference weight factors R defined in Eq. (38). While the sNWA overestimates the full result by a factor of up to 5.5 on account of the neglected destructive interference, both variants of the gNWA result in a good approximation of the full 3-body decay width.

The slight relative deviation between either form of the gNWA and the full result amounts to (ΓgNWA-Γ13)/ΓsNWA0.4-1.7% if normalised to the sNWA and to (ΓgNWA-Γ13)/Γ130.5-9.2% if normalised to the 3-body decay width. The largest relative deviation between ΓgNWA and Γ13 arises in the region where the reference value Γ13 itself is very small so that a small deviation has a pronounced relative effect. This uncertainty, however, is not intrinsically introduced by the approximated interference term, but it stems from the factorised constituents ΓNWAh,ΓNWAH already present in the sNWA, see Fig. 4.

Application of the gNWA to the loop level

Motivated by the good performance of the gNWA at the tree level, in this section we investigate the application of the generalised narrow-width approximation at the loop level by incorporating 1-loop corrections of the production and decay part into the predictions. Before treating the full 3-body decay width at the next-to leading order (NLO) in Sect. 8, we will start with the method of on-shell matrix elements in Sect. 7.1 and turn to the R-factor approximation in Sect. 7.2.

At the 1-loop level we write the product of the production cross-section times partial decay width in the standard NWA as

σP·BRσP1ΓD0+σP0ΓD1Γtot, 103

where the total width is obtained from FeynHiggs [4851] incorporating corrections up to the 2-loop level as in the definition of the branching ratio and in the Breit–Wigner propagator. While restricting the numerator of Eq. (103) formally to one-loop order to enable a consistent comparison with the full process, at the end (in Sect. 9.4) all constituents of the NWA will be used at the highest available precision, i.e. σPbest·BRbest for the most advanced prediction with the branching ratio obtained from FeynHiggs.

On-shell matrix elements at 1-loop order

In analogy to the procedure in Sect. 3.2 at the tree level, on-shell matrix elements are used here in the 1-loop expansion. Special attention must be paid to the cancellation of infrared (IR) divergences from virtual photons (or gluons) in 1-loop matrix elements and real photon (gluon) emission off charged external legs. In preparation for the example process χ~40χ~10h/Hχ~10τ+τ- (see Sect. 5), we focus on IR-divergences from photons in loops of the decay part and soft final state photon radiation.

The aim is to approximate only the 1-loop contribution, but to keep the full momentum dependent expression at the Born level with Mi0=Mi0(q2),

|M0|2=|Mh0|2+|MH0|2+2Re[Mh0MH0]. 104

In contrast, the 1-loop matrix elements are factorised into the on-shell production and decay parts times the momentum dependent Breit–Wigner propagator ΔiBWΔiBW(q2). The squared matrix elements are expanded up to the 1-loop order. Since the emission of soft real photons is proportional to the Born contribution, the virtual contribution is supplemented by the absolute value squared of the tree-level matrix element, multiplied by the QED-factor δSB of soft bremsstrahlung [75, 76],

2Re[M0M1]+δSB|M0|22Re[(Ph1Dh0+Ph0Dh1+δSBPh0Dh0)Ph0Dh0·|ΔhBW|2]+2Re[(PH1DH0+PH0DH1+δSBPH0DH0)PH0DH0·|ΔHBW|2]+2Re[{(Ph1Dh0+Ph0Dh1)PH0DH0+Ph0Dh0(PH1DH0+PH0DH1)+δSBPh0Dh0PH0DH0}·ΔhBWΔHBW]. 105

The first line of Eq. (105) represents the pure contribution from h, factorised into production and decay, the second line accordingly for H. The third and fourth lines constitute the 1-loop and bremsstrahlung interference term as the product of h- and H-matrix elements and Breit–Wigner propagators. For a consistent comparison with the full 1-loop result, each term is restricted to 1-loop corrections in only one of the matrix elements.

The 1-loop prediction of the full process in the approximation of on-shell matrix elements consists – besides the Born cross section without an approximation5 – of the squared contribution of h and H and the interference term σMint1 at the strict 1-loop level,6

σM1=σfull0+σPh1ΓDh0+σPh0ΓDh1Γhtot+σPH1ΓDH0+σPH0ΓDH1ΓHtot+σMint1, 106
σMint1=2FRedq22πΔhBW(q2)ΔHBW(q2)×dΦP(q2)(Ph1PH0+Ph0PH1)×dΦD(q2)Dh0DH0+dΦP(q2)Ph0PH0×dΦD(q2)(Dh1DH0+Dh0DH1+δSBDh0DH0). 107

For the prediction with the most precise constituents, we use 2-loop branching ratios, BRibest. We include also the products of 1-loop matrix elements. Their contribution to the interference term is denoted by σMint+,

σMint+=2FRedq22πΔhBW(q2)ΔHBW(q2)×dΦP(q2)(Ph1PH0+Ph0PH1)×dΦD(q2)(Dh1DH0+Dh0DH1+δSBDh0DH0). 108

The approximation of the whole process based on on-shell matrix elements and incorporating higher-order corrections wherever possible is denoted by σMbest, which reads then

σMbest=σfull0+i=h,H(σPibestBRibest-σPi0BRi0)+σMint1+σMint+. 109

The best production cross section σPibest and branching ratios BRibest mean the sum of the tree level, strict 1-loop and all available higher-order contribution to the respective quantity. Therefore, the products of tree level production cross sections and branching ratios are subtracted because their unfactorised counterparts are already contained in the full tree level term σfull0. If a more precise result of the production cross sections is available, it can be used instead of the explicit 1-loop calculation that was performed in our example process.

IR-finiteness of the factorised matrix elements

On-shell evaluation The UV-divergences of the virtual corrections are cancelled by the same counterterms as in the full process at 1-loop order. Although it would be technically possible in most processes to compute the full bremsstrahlung term without the NWA, i.e. δSB|Mfull0|2, the IR-divergences from the on-shell decays need to be exactly cancelled by those from the real photon emission. But the IR-singularities in the sum of the factorised (on-shell) virtual corrections and the momentum-dependent real ones would not match each other. Consequently, the tree level matrix elements are also factorised, and the IR-divergent parts of the 1-loop decay matrix elements Dh1(Mh2,M¯2),DH1(MH2,M¯2) and the soft QED-factor δSB(M¯2) have to be calculated at the same mass M¯=Mh or MH. The LO matrix elements are evaluated at their mass-shell, i.e. Di0(Mhi2). The NLO matrix elements are split into the part containing loop integrals on the one hand and the helicity matrix elements on the other hand. While the individual Higgs masses can be inserted into the finite helicity matrix elements (see Sect. 5.3 ), the loop integrals have to be evaluated at the same mass M¯2 as in δSB to preserve the IR-cancellations. Hence, a choice must be made whether to define M¯=Mh or MH. We evaluate the numerical difference in Sect. 9.3.

The production matrix elements are completely evaluated on their respective mass-shells, Pi0(Mhi2) and Pi1(Mhi2). This is possible because the initial state in this example contains only neutral particles. But the calculation can be directly generalised to charged initial states according to the procedure described for the decay matrix elements. The IR-singularities in the product of initial and final state radiation are then cancelled by those from a virtual photon connecting charged legs of the initial and final state. Such non-factorisable contributions can be treated in a pole approximation in analogy to the double-pole approximation (DPA) that has been used for instance for the process e+e-W+W-4 leptons, see Ref. [77]. An alternative approach for the treatment of IR-singularities is formulated in Refs. [4, 37]. There, the singular parts from the real photon contribution are extracted, and the DPA is only applied for those terms which exactly match the singularities from the virtual photons. In our calculation, we do not split up the real corrections in this way, but employ instead the procedure described above. We discuss a possibility of splitting the diagrams with virtual photons into an IR-singular and a finite subgroup in Sect. 7.1.2.

Cancellation of IR-divergences According to the Kinoshita–Lee–Nauenberg (KLN) theorem [78, 79], the IR-divergence from a virtual photon is cancelled by the emission of a real photon off a charged particle from the initial or final state, i.e., in our example process as soft bremsstrahlung in the final state of a Higgs decay. We will derive the IR-finiteness of the on-shell matrix elements in analogy to the cancellation of the IR divergencies for the full 3-body decay. Writing the momentum-dependent 3-body matrix elements with the resonant particle either hi=h or H as the sum of the tree level (Mhi0) and virtual (Mhiv) contributions,

Mhi(q2)=Mhi0(q2)+Mhiv(q2), 110

and adding to the squared matrix element the corresponding contribution from real soft photon (MhiBr) radiation, we find

|Mh+MH|2+|MhBr+MHBr|2=hi=h,H(|Mhi|2+|MhiBr|2)+2Re[MhMH+MhBrMHBr]. 111

Because the complete sum in Eq. (111) and the individual h- and H-terms are IR-finite, the interference term must be IR-finite by itself. With the proportionality of the bremsstrahlung contribution to the tree level term,

MhBr(q2)MHBr(q2)=δSB(q2)Mh0(q2)MH0(q2), 112

and keeping only the terms of O(α) relative to the lowest order, the interference term Intα(q2) results in

Intα(q2)=2Re[Mh(q2)MH(q2)|α+MhBr(q2)MHBr(q2)] 113
=2Re[Mhv(q2)MH0(q2)+Mh0(q2)MHv(q2)+δSB(q2)Mh0(q2)MH0(q2)]. 114

As described above, the on-shell evaluation is performed at the individual mass Mhi in all production and tree level matrix elements and the helicity elements, whereas the soft photon factor δSB and the 1-loop form factors of the decay are evaluated at the same mass M¯ in the on-shell interference term Intosα of O(α) relative to the lowest order,

Intosα=2Re[Mhv(Mh2,M¯2)MH0(MH2)+Mh0(Mh2)MHv(MH2,M¯2)+δSB(M¯2)Mh0(Mh2)MH0(MH2)] 115
=2Re[{(Phv(Mh2)Dh0(Mh2)+Ph0(Mh2)Dhv(Mh2,M¯2))·PH0(MH2)DH0(MH2)+Ph0(Mh2)Dh0(Mh2)·(PHv(MH2)DH0(MH2)+PH0(MH2)DHv(MH2,M¯2))+δSB(M¯2)Ph0(Mh2)Dh0(Mh2)PH0(MH2)DH0(MH2)}×Δh(q2)ΔH(q2)]. 116

Since the virtual production matrix elements are IR-finite in our example process, we can drop the first term in each of the brackets in the first and second line of Eq. (116) for the discussion of IR-singularities, which are contained in Intosα|IR,

Intosα|IR=2Re[Ph0(Mh2)PH0(MH2)·Δh(q2)ΔH(q2)·(Dhv(Mh2,M¯2)DH0(MH2)+Dh0(Mh2)DHv(MH2,M¯2)+δSB(M¯2)Dh0(Mh2)DH0(MH2))]. 117

Moreover, the Mhi2-dependent helicity matrix elements dhi(Mhi2) from Sect. (5.3) can be factored out by Dhi=Chidhi so that the IR-singularities from IntosαIR can be further extracted:

Intosα|IR=2Re[Ph0(Mh2)PH0(MH2)·Δh(q2)ΔH(q2)·dh(Mh2)dH(MH2)(Chv(M¯2)CH0+Ch0CHv(M¯2)+δSB(M¯2)Ch0CH0)]. 118

Compared to Eq. (114) which can also be factorised into q2-dependent form factors and helicity matrix elements, the structure of the IR-singularities is the same. In Eq. (118), all of those contributions are just evaluated at M¯2 instead of q2. Hence the cancellation works analogously so that Eq. (115) is an IR-finite formulation of the factorised interference term. Because the Z^-factors can be factored out in the same way for the on-shell approximation as for the full matrix elements, their inclusion preserves the cancellations of IR-divergences.

Separate calculation of photon diagrams

As an alternative to the method described above, it is possible to reduce the number of diagrams whose loop integrals need to be evaluated at the common mass M¯ instead of their on-shell mass Mi by splitting the 1-loop decay matrix elements into an IR-finite and an IR-divergent part,

Di1=Di1,noγ+Di1,γ. 119

Both subgroups of diagrams are rendered UV-finite by the corresponding counterterms. Since the diagrams without any photon are already IR-finite, their loop integrals can safely be calculated on-shell, Di1,noγ(Mhi2). Hence, only the loop-integrals of the photon contribution need to be evaluated at a fixed mass M¯, resulting in Di1,γ(Mhi2,M¯2) and δSB(M¯2).

If the fixed Higgs mass were inserted into both the loop integrals and the helicity matrix elements, the IR-cancellation would work in the same way as for the unfactorised process, just with the special choice of q2=M¯2. In our approach, the helicity matrix elements are determined at the specific masses Mhi as it is demonstrated in Eqs. (87) and (97). Furthermore, those mass values are equal in the matrix elements at lowest and higher orders as loop-corrected masses are used also at the improved Born level. Because the Mhi-dependent helicity matrix elements can be factored out, the IR-singularities cancel in the decay contribution to the interference term of O(α) relative to the lowest order, with Di0 at Mhi2,

DhDHα=Dh1,γ(Mh2,M¯2)DH0+Dh0DH1,γ(MH2,M¯2)+δSB(M¯2)Dh0DH0. 120

On the one hand, this approach requires the separate calculation of purely photonic and non-photonic contributions. On the other hand, it enables the on-shell evaluation of IR-finite integrals and is thus closer to the full result. However, in case of a virtual photino contribution one needs to be careful not to break supersymmetry by treating the photon differently than its superpartner. Thus, the possibility of such a separate treatment of the photon diagrams, whose numerical impact is small in the studied example process, should be considered in view of the investigated model and its particle content.

Interference weight factors at 1-loop order

In the previous section, we derived how to include virtual and real contributions in the product of factorised matrix elements in a UV- and IR-finite way. However, special attention is needed to ensure the correct treatment of the on-shell matrix elements of the interference contribution.

We now discuss additional approximations with which the R-factor method introduced in Sect. 3.3 can be extended beyond the tree level. We develop a method that facilitates an approximation of the interference term based on higher-order cross sections and decay widths, but only tree level couplings. This technically simpler treatment comes at the price of the further assumption, as in the tree level version of the interference weight factor, that both Higgs masses be equal. Thus, the method presented in this section is an optional, additional approximation with respect to Eq. (105).

Under the assumption of equal masses, the product of unsquared matrix elements for the production and decay of h and H can be re-expressed at the tree level in terms of either h or H with the help of Eq. (37). Hence, one can choose to keep the 1-loop matrix elements and to replace only the tree level ones so that only lowest-order couplings will be present in the x-factor. We will now apply this prescription to the third term in Eq. (105) containing the 1-loop virtual corrections to the interference term Intv:

Intv=2Re[{(Ph1Dh0+Ph0Dh1)PH0DH0+Ph0Dh0(PH1DH0+PH0DH1)}ΔhBWΔHBW]2Re[(Ph1Dh0+Ph0Dh1)Ph0Dh0·CPH0CPh0CDH0CDh0·ΔhBWΔHBW]+2Re[{PH0DH0·CPh0CPH0CDh0CcDH0(PH1DH0+PH0DH1)ΔhBWΔHBW}]=2Re[(Ph1Ph0|Dh0|2+|Ph0|2Dh1Dh0)xh0·ΔhBWΔHBW]+2Re[(PH1PH0|DH0|2+|PH0|2DH1DH0)xH0·ΔHBWΔhBW]. 121

Hence we exploited the choice of expressing the product of h- and H-matrix elements either in a weighted sum of both or in terms of one of them. The latter choice, as selected in Eq. (121), has the advantage that the matrix elements containing loop contributions of h and only tree level contributions of H are transformed in terms of h and vice versa. Including the flux factor and the phase space integrals as in Eq. (35), adding soft bremsstrahlung according to the last line of Eq. (105) and keeping in mind that

1FdΦP2Re[Pi1Pi0]=σPi1,12MidΦD(2Re[Di1Di0]+δSB|Di0|2)=ΓDi1, 122

the expressions from Eq. (121) lead to

σint1,R=σPh1ΓDh0+σPh0ΓDh1ΓhtotR~h+σPH1ΓDH0+σPH0ΓDH1ΓHtotR~H, 123

where R~i has been defined in Eq. (41). Equation (123) is meant for the consistent comparison with the full result in the strict one-loop expansion. Using the most precise predictions of all components and the unfactorised tree level result leads to the final prediction:

σRbest=σfull0+i=h,H(σPibestBRibest-σPi0BRi0)+σRint1+σRint+, 124
σRint1=(σPh1BRh0+σPh0BRh1)R~h+(σPH1BRH0+σPH0BRH1)R~H, 125
σRint+=12σPh1(BRh1R~h+BRH1R~hH)+12σPH1(BRH1R~H+BRh1R~Hh), 126

where σRint1 denotes the contribution to the interference term for which the product of production cross sections and partial decay widths is restricted to the 1-loop level, but the branching ratios are at all levels normalised to the 2-loop total width from FeynHiggs [4851]. In addition, σRint+ contains terms beyond the 1-loop level. In Eq. (126), we introduced the generalised interference weight factors R~ij,

R~ij=2MjΓjRe{xijI}, 127

involving the scaling factors xij,

xij=CPhCPHCDhCDH|CPi|2|CDj|2, 128

to account for the product of 1-loop production and decay matrix elements in Eq. (108). For the most precise prediction, the 1-loop branching ratios in Eqs. (125, 126) can additionally be replaced by BRibest-BRi0 which is beyond the M-method in Eq. (108). As in Eq. (109) for the M-method, the products of tree level production cross section and branching ratios have to be subtracted because their contribution is already accounted for by σfull0. The most precise branching ratios can be obtained from FeynHiggs [4851] including full 1-loop and leading 2-loop corrections.

Full 3-body decay at the one-loop level

The numerical validation of the gNWA at the next-to-leading order requires the calculation of the process χ~40χ~10τ+τ- with intermediate h and H as the full 3-body decay including virtual and real corrections.

Reference [63] provides a 1-loop calculation of the decay of the next-to-lightest neutralino χ~20 into χ~10 and a pair of leptons, thus a similar process, but with a dominant contribution from an on-shell slepton, while the Higgs propagators are treated as non-resonant. In the following, we focus on the diagrams contributing to resonant intermediate Higgs bosons, as well as box-diagrams with and without Higgs bosons. The 1-loop integrals are computed with LoopTools [43, 80].

Contributing diagrams

Virtual corrections at the neutralino-Higgs vertex

Virtual SM and MSSM particles contribute to the correction of the χ~i0χ~j0hk-vertex. A selection of diagrams is displayed in Fig. 6. We treat here the intermediate Higgs bosons H^e appearing outside of the vertex loop contribution as “external”, while Hf denotes an internal Higgs boson within the loop (e,f=1,2,3). Furthermore, HH± denotes the charged Higgs bosons. The neutralinos are labelled by χ~n0,n=1,2,3,4 and the charginos by χ~m,m=1,2. The first example diagram contains up-type quarks and a squark of generation m=1,2,3.

Fig. 6.

Fig. 6

Example triangle diagrams of the 3-body decay χ~40χ~10τ+τ- with 1-loop corrections at the χ~40χ~10H^e-vertex, where H^e denotes a Higgs boson mixed by Z^-factors, Hf an internal Higgs boson (see text) and HH±. u and u~ represent the up-type (s)quarks, χ~0 are the neutralinos and χ~ the charginos

For H^e the mixing with Z^-factors is taken into account, i.e., Eq. (45) is applied for both vertices of H^e. This treatment has been applied in order to enable a comparison with the factorised production and decay contributions in the gNWA. The appearance of Z^-factors in external Higgs boson lines is related to the fact that we use a renormalisation scheme without on-shell conditions for the Higgs-boson fields. In such a case, like the DR¯ renormalisation of the Higgs fields employed here, the Z^-factors are introduced to ensure correct on-shell properties of external Higgs bosons [81, 82]. In the NWA, the Higgs bosons appear as external particles in the on-shell production and decay, and we therefore treat the intermediate Higgs bosons of resonant propagators in the full 3-body decay in the same way for comparison purposes.

The triangle corrections appearing at the χ~i0χ~j0hk-vertex are renormalised by the counterterm

δCijkR/L=e2cWsWδcijk()+δZe-δsWsW-δcWcWCijkR/L+12l=14(δZliR/LCljkR/L+δZ¯jlL/RCilkR/L+δZhkhlCijkR/L) 129

in the on-shell scheme, see Ref. [64] and references therein. In Eq. (129), hl=h,H,A,G for l=1,2,3,4, denote the neutral Higgs and Goldstone bosons. The parameters M1,M2,μ are related to the choice of the three electroweakinos which are renormalised on-shell and thus define the choice for the on-shell renormalisation scheme for the neutralino-chargino sector, as mentioned in Sect. 4.2. In our scenario, we identify χ~10 as the most bino-like, χ~30 as the most higgsino-like and χ~40 as the most wino-like state and hence renormalise these three neutralinos on-shell. By this choice of an NNN scheme, we avoid large mass corrections to the remaining neutralino and the charginos. Alternatively, χ~20 instead of χ~40 could be identified as the most wino-like state because the two corresponding elements in the matrix N, which diagonalises the neutralino mass matrix (see Sect. 4.2), have nearly the same magnitude. Thus, this alternative choice would lead to a comparable sensitivity to the three parameters of this sector and thereby also to a stable renormalisation scheme. But since χ~40 is involved in our process as an external particle, we prefer to set it on-shell. The 1-loop effect on the 2-body decay widths Γ(χ~40χ~10h/H) is shown in Fig. 12.

Fig. 12.

Fig. 12

2-body decay widths of a χ~40χ~10hi and c hiτ+τ- with hi=h (blue) and H (green) at the tree level (dashed) or at the 1-loop level (solid), and the relative effect of the loop contributions (b), (d)

Virtual corrections at the Higgs- τ+τ- vertex and real photon emission

Furthermore, the hkτ+τ--vertex diagrams shown in Fig. 7 are UV-divergent, and the last diagram is also IR-divergent due to the virtual photon. The UV-divergences are cancelled by the counterterm, analogous to the SM, δChkτ+τ-=δChkττLωL+δChkττRωR, with [75, 83]

δChkτ+τ-L/R=Chkτ+τ-tree·δZe+12δZhkhk+12δZhHChlττtreeChkττtree-δMW22MW2-δsWsW+sβ2δtβ+δmτmτ+12{δZτL/R+δZτR/L}, 130

where k,l=h,H and δZτL/R are the left-/right-handed field renormalisation constants of the τ-lepton. The tree-level couplings Chkτ+τ-tree are given in Eq. (57). The IR-divergent terms vanish for squared matrix elements in the combination of virtual corrections containing a photon in the loop with real photons emitted as soft bremsstrahlung off one of the τ-leptons. Soft photons are defined by the energy cut-off Esoftmax. As a prescription for the energy cut-off we use here a fraction of the mass of the decaying particle, namely EγEsoftmax=0.1mχ~40. All photons below this energy are considered as soft so that they are described by the soft photon factor δSB multiplying the tree level result,

ΓSB=δSBΓtree. 131

We use the result for δSB of Ref. [75] implemented in FormCalc [4347]. More details on the separation of soft and hard, collinear and non-collinear QED corrections for this process can be found in Ref. [63].

Fig. 7.

Fig. 7

Example triangle diagrams of the 3-body decay χ~40χ~10τ+τ- with 1-loop corrections at the H^eτ+τ--vertex, where the particles are labelled as is Fig. 6

Self-energies involving mixing of neutral bosons

The diagrams with self-energy corrections of the intermediate (“external”) Higgs boson H^e are classified in two categories. On the one hand, there are the mixing contributions between the three neutral Higgs bosons (reduced to 2×2 mixing in case of real MSSM parameters). They are approximated by the Z^-factors, which were checked to accurately reproduce the full Higgs propagator mixing close to the complex pole (see Sect. 4.1; Refs. [10, 54]). Consequently, no explicit propagator corrections with Higgs self-energies are included. With the Z^-factors, the strict one-loop order is extended to take more precise mixing effects in the Higgs sector into account. On the other hand, the Z^-factors do not contain mixing with other neutral particles. Hence, the propagator corrections of a Higgs with the neutral Goldstone boson G and the Z-boson are calculated explicitly. Some example diagrams are shown in Fig. 8. However, in case of CP-conservation, the mixing between h / H and G / Z vanishes.

Fig. 8.

Fig. 8

Example self-energy diagrams contributing to the 3-body decay χ~40χ~10τ+τ- with 1-loop corrections to the Higgs propagator which mixes with the neutral Goldstone boson G and the Z-boson. As in Fig. 6, H^e denotes a Z^-mixed neutral Higgs boson and Hf an internal Higgs boson

Box diagrams

Finally, the χ~40 cannot only decay into χ~10τ+τ- via a resonant Higgs boson, but also through box diagrams. Figure 9 depicts some example diagrams with and without Higgs bosons. No counterterms are necessary because the boxes are UV-finite by themselves. The box diagrams are explicitly calculated including the full MSSM spectrum in the loops, but, as expected, those non-resonant contributions are found to be numerically suppressed. This is important for the comparison with the gNWA at the 1-loop level in Sect. 9.2 since the boxes cannot be factorised.

Fig. 9.

Fig. 9

Example box diagrams of the 3-body decay χ~40χ~10τ+τ- (with and without Higgs bosons), where the particles are labelled as is Fig. 6. Only internal Higgs bosons Hf appear in the loop

Comparison of the tree level and 1-loop result

Figure 10 shows the resulting decay width of χ~40 into χ~10 and a τ+τ--pair as the full 3-body decay. As mentioned in Sect. 6.2, the Z-, A-, G- and slepton-exchange is not included in this section, but the interference between all other contributions to the 3-body decay is taken into account. The tree-level and 1-loop results are based on the product of Z^-factors and Breit–Wigner propagators with higher-order Higgs masses, total widths and Z^-factors. Despite being an approximation of the complete Higgs propagator mixing, see Eq. (49), it is here referred to as the full result that will consistently serve as a reference for the validation of the gNWA at the 1-loop level.

Fig. 10.

Fig. 10

The 13 decay width Γ(χ~40χ~10τ+τ-). Upper panel Tree-level mediated by resonant hH including their interference (dashed) and full 1-loop result with vertex, soft photon and propagator corrections to the resonant hH-exchange and, in addition, non-resonant box contributions (solid), both supplemented by higher-order Higgs masses, total widths and Z^-factors. Lower panel Relative loop contribution r=(Γloop-Γtree)/Γtree in percent

The full 1-loop decay width includes the vertex corrections at the production and the decay vertex and box contributions as well as self-energy corrections to the propagator and bremsstrahlung off the τ-leptons in the final state.

The NLO decay width (solid) is enhanced relative to the LO result (dashed) in most of the analysed parameter interval, up to 11%, as the plot of the ratio r=(Γloop-Γtree)/Γtree shows. However, around MH±152 GeV, the 1-loop corrections vanish.

Numerical validation of the gNWA at the loop level

In this example, the calculation of the full process at the 1-loop level is still manageable, where full here means the 3-body decays with Breit–Wigner propagators and Z^-factors, though without the Z-, A- and G-boson exchange. But we aim at validating the generalised narrow-width approximation at the 1-loop level so that it can be applied on kinematically more complicated processes for which the factorisation into production and decay is essential to enable the computation of higher order corrections.

Our strategy is to combine the NLO corrections for the production and decay subprocesses in such a way that the gNWA prediction can be consistently compared to the full 1-loop calculation. Only the box diagrams are left out in the gNWA compared to the 3-body decays.

2-body decays

The gNWA at NLO requires the 1-loop contributions to the 2-body decays as subprocesses. For the production, we calculate the full 1-loop corrections to Γ(χ~40χ~10h/H) in the NNN on-shell renormalisation scheme, see Refs. [56, 64, 65], with the same choice of on-shell states as in the 3-body-decay described in Sect. 8.1.1. Higgs mixing is taken into account by Z^-factors, but mixing with G-/Z-bosons is generated explicitly, which, however, vanishes in this CP-conserving scenario. Some example diagrams for vertex corrections are shown in Fig. 11a. Figure 12a presents the resulting 2-body decay widths for the production of h (blue) and H (green) at the tree level (dashed) and the 1-loop level (solid). While the 1-loop corrections increase Γ(χ~40χ~10h), they decrease the production of H from the decay of χ~40. The substantial relative effect can be seen in Fig. 12c.

Fig. 11.

Fig. 11

Example diagrams of the 2-body decays for a Higgs production in χ~40χ~10h/H at NLO and b Higgs decay in h/Hτ+τ- at NLO with virtual and real corrections

For the decay, the full vertex corrections to hiτ+τ- are included. Furthermore, real soft photon emission off the τ-leptons in the final state is included. In order to allow for a meaningful comparison between the gNWA and the full calculation, the energy cut-off is defined by the same value Esoftmax=0.1mχ~40 as in the 3-body decay. Example diagrams are displayed in Fig. 11b, where the first diagram belongs to the IR-finite ones, but the second and third diagrams are IR-divergent. The emission of a real photon is not directly calculated as a 3-body decay, but still with the 2-body phase space in the soft-photon approximation. The numerical influence of the corrections of O(α) on Γ(hiτ+τ-) is shown in Fig. 12c. The 1-loop and real corrections slightly decrease both decay rates (for hi=h,H) by 1.2–1.5% as displayed in Fig. 12d.

On-shell matrix elements and R-factor approximation

The on-shell factorisation of the interference term has already been applied at the leading order in Sect. 6.2. In this section, we will investigate its accuracy at the next-to-leading order. Since a wide range of processes even with many external particles can be computed at lowest order without applying the NWA, we use the full leading order result of the three-body decay (i.e., without NWA) and add the 1-loop contribution for which we use the gNWA. With this procedure, we apply the on-shell approximation only when necessary without introducing an avoidable uncertainty at the tree level.7

In Fig. 13, we compare the numerical results of the method of on-shell matrix elements using Eqs. (106) and (107), denoted by M, and of the interference weight factor approximation from Eq. (123), denoted by R~, with the full 1-loop result as calculated in Sect. 9. The upper panel shows the prediction of the partial width Γ(χ~40χ~10τ+τ-). The lines of the gNWA based on matrix elements (red, dashed) and the full 1-loop calculation (black, solid) lie nearly on top of one another. Also the additional R~-factor approximation (blue, dash-dotted) yields a good qualitative agreement with the full result, but less accurate than achieved by the on-shell matrix elements. The lower panel visualises the relative deviation of the decay width predicted by the two versions of the gNWA from the full result. As expected, the R-factor method reproduces the full result best where the difference between Mh and MH is smallest, i.e., in the centre of the analysed parameter interval. But the assumption of equal masses becomes worse away from the centre of the analysed interval, leading to a deviation from the full 1-loop result of up to 4.5%. Thus, for those parameters the matrix element method performs clearly better within an accuracy of better than 1%.

Fig. 13.

Fig. 13

Upper panel The decay width χ~40χ~10τ+τ- at the 1-loop level with resonant hH-exchange and, for the full 3-body decay (black, solid), with box contributions. The gNWA with on-shell matrix elements is denoted by M (red, dashed), and the gNWA with interference weight factors is denoted by R~ (blue, dash-dotted). Lower panel The relative deviation of the gNWA (matrix element and R-factor approximation) from the full 1-loop result in percent

In order to further investigate how well the gNWA predicts the interference term at the 1-loop level, we take a closer look in Fig. 14 at the pure loop contribution Γloop,pure=Γloop-Γtree of the full three-body decay (black, solid), the gNWA using on-shell matrix elements (red, dashed, denoted by M) and the R~-factor approximation (blue, dash-dotted, denoted by R~). While at the tree level we found that both versions of the gNWA work comparably well (see Fig. 5), the M-method provides a significantly better prediction of the interference term at the 1-loop level.

Fig. 14.

Fig. 14

Pure loop contributions in the full calculation (black, solid) and approximated by the gNWA using the matrix element method denoted by M (red, dashed) and using the R-factor approximation denoted by R~ (blue, dash-dotted)

When the gNWA is used to approximate one-loop effects, we need to compare the accuracy of the approximation with the overall size of the loop correction. Figure 15 provides a comparison between the precision of the gNWA with respect to the full calculation (for on-shell matrix elements denoted by M in red and the R-factor approximation denoted by R~ in blue) and the relative size of the 1-loop correction to the 3-body decay width in black. While the loop correction ranges from -1 to 11% in this example case, the deviation of the matrix element method from the full result remains below 1%. The uncertainty of this approximation is therefore significantly smaller than the typical size of the loop correction in this case. The deviation of the R-factor approximation from the full result is found to be larger, within -34.5% in this case, but it is still about a factor of two smaller than the size of the loop correction in the region where the latter is sizable.

Fig. 15.

Fig. 15

Precision of the gNWA at the 1-loop level using the matrix element method denoted by M (red, dashed) and using the R-factor approximation denoted by R~ (blue, dash-dotted) compared to the relative size of the loop contribution in the full calculation (black). The ±1% region is indicated in grey

The plot shows that the overall performance of the gNWA with the M-method is good except for the region around MH±152– 152.5 GeV where the M-method uncertainty exceeds the relative size of the full loop correction slightly. But here the full loop correction is in fact very small. Keeping in mind that the full calculation is subject to uncertainties itself (e.g. from missing higher-order corrections) which might reach the level of 1% (for illustration, the ±1% range is indicated in the plot), the M-method can be regarded as adequate to approximate loop corrections to the interference term within the expected uncertainty of the full result (as long as non-factorisable corrections remain numerically suppressed). On the other hand, the R-factor method gives rise to larger deviations and should therefore be regarded as a simple estimate of the higher-order result including interference effects.

Separate treatment of photon contributions

As discussed in Sect. 7.1.2, the factor δSB, which multiplies the squared tree level matrix element to account for the contribution of soft bremsstrahlung, and the IR-divergent loop integrals must be evaluated at the same mass to enable the cancellation of IR-singularities between real and virtual photon contributions. In order to reduce the ambiguity whether to choose the common mass M¯=Mh or MH, the IR-finite diagrams can be evaluated at their correct mass shell. Figure 16 compares the dependence of the gNWA result on the ambiguous mass choice, i.e., the relative deviation between ΓgNWA(M¯=Mh) and ΓgNWA(M¯=MH), for the matrix element method. The dashed green line represents the universal treatment where the loop integrals in all decay one-loop matrix elements are evaluated at M¯2 whereas the solid red line shows the separate calculation of the photonic contribution as described in Sect. 7.1.2. The impact of the dependence of the gNWA on the choice of the mass M¯ is found to be rather small, giving rise to a maximum deviation of 0.23% for the universal treatment of all one-loop matrix elements for the decay. Restricting this approximation just to the photonic contribution is seen to have an insignificant effect in this example, reducing the deviation to 0.2%.

Fig. 16.

Fig. 16

Impact of the dependence of the gNWA on the choice of the mass M¯ (see text). The relative deviation between ΓMh and ΓMH, where ΓMiΓgNWAM(M¯2=Mi2), is shown for the universal treatment of all one-loop matrix elements for the decay and for the case where the photonic contribution is treated separately

gNWA prediction with most precise input values

As a first step, we defined the gNWA at the 1-loop order for a consistent comparison between the gNWA and the full 1-loop calculation. As an exception, the Higgs masses, total widths and wave function normalisation factors Z^ have been obtained from FeynHiggs [4851] at the 2-loop order and used both in the gNWA and the full calculation. In this section we want to exploit the factorisation and include all components at the highest available precision. This means for the gNWA with the on-shell matrix element method and the R-factor approximation that we use the calculated 1-loop production part and the FeynHiggs branching ratios in ΓP(χ~40χ~10hi)·BRD(hiτ+τ-). Furthermore, the product of on-shell matrix elements from Eq. (105) is expanded up to the product of 1-loop matrix elements in Eq. (109). The higher-order extension of the R-factor approximation is defined in Eq. (124).

So far we have neglected additional contributions that do not play a role in the discussion of the interference effects between contributions with h and H exchange in the decay of χ~40χ~10τ+τ- for the considered CP-conserving scenario. In order to obtain a more phenomenological prediction of Γ(χ~40χ~10τ+τ-) we now take into account also the resonant exchange of the CP-odd Higgs boson A, the neutral Goldstone boson G and the Z-boson, as well as the non-resonant 3-body decay via a τ~. We include the contributions from A,G,Z and τ~-exchange at the tree-level, while at the loop level we incorporate the most precise gNWA result (where those additional contributions are neglected). Figure 17a shows the prediction of the higher-order improved gNWA, supplemented by the full tree-level contribution including A,G,Z and τ~-exchange diagrams, as solid lines using on-shell matrix elements (red) and the R-factor approximation (blue). The corresponding results where the A,G,Z and τ~-exchange contributions have been neglected are indicated by the dashed lines. The contributions from A,G,Z and τ~ are found to yield a non-negligible upward shift in this example.

Fig. 17.

Fig. 17

a The gNWA using the most accurate predictions for all parts of the process, supplemented with a tree-level result with (solid) and without (dashed) the additional A,G,Z and τ~-exchange contributions, for the M-method (red) and the R~-approximation (blue). b The relative effect of the most precise branching ratios and the product of 1-loop terms on the prediction of the gNWA with on-shell matrix elements (red, denoted by M) and the R-factor approximation (blue, denoted by R~)

Figure 17b shows the impact of including the most precise branching ratios and the product of 1-loop matrix elements in the gNWA, denoted by ΓgNWAbest. For the matrix element method (in red, denoted by M), this amounts to up to 1.2% relative to the 1-loop formulation used above for the comparison with the result for the 3-body decay. For the R-factor approximation (in blue, denoted by R~), the effect of up to 0.4% is smaller because the effect on the interference term beyond the 1-loop order turns out to be negative. With reference to the gNWA including only h and H, the relative impact of the higher-order corrections is slightly higher (1.6% for the matrix element method and 0.6% for the R-factor approximation).

The numerical size of the contributions beyond the 1-loop order depends on the process and scenario, but the gNWA allows for their inclusion also in the interference term.

Conclusions

In this paper, we have developed a generalisation of the standard narrow-width approximation that extends the applicability of this important tool to scenarios where interference effects between nearly mass-degenerate particles are important. This can be the case in many extensions of the SM where the spectrum of the new particles is such that the mass difference between two or more particles is smaller than one of their total decay widths. In such a case, their resonances overlap so that the interference cannot be neglected if the two states mix. In order to still enable the convenient factorisation of a more complicated process into production and decay of an intermediate particle, we have demonstrated how to factorise also the interference term. This is achieved by evaluating the production and decay matrix elements on the mass-shells of the resonant particles in analogy to the terms present in the standard NWA. If one additionally assumes equal masses of the intermediate particles, it is possible to further approximate the interference contribution by an interference weight factor, R, in terms of production cross sections, decay branching fractions, ratios of couplings and a universal, process independent integral over Breit–Wigner propagators.

We have developed this generalised narrow-width approximation both at the tree-level and at one-loop order. Following the analytic derivations, we have discussed the application to a simple example process in the context of the MSSM with real parameters. We have considered the three-body decay of the heaviest neutralino via a resonant neutral, CP-even Higgs boson, h or H, into the lightest neutralino and a pair of τ-leptons. This process is well-suited for a test of the gNWA since it is sufficiently simple so that the full process can be calculated at the loop level and compared with the predictions of the gNWA. Within the gNWA this process can be decomposed into basic kinematic building blocks, namely two subsequent 2-body decays, and the interference contributions involve only scalar particles. The discussion of interference effects can therefore be disentangled from spin-correlation issues. Furthermore, the process involves charged external particles, so that the issue of the cancellation of IR divergencies between virtual loop corrections and bremsstrahlung contributions is relevant, while the fact that only the final state particles are charged makes the treatment of the IR-divergent contributions very transparent.

We have validated the gNWA at the Born level (supplemented by higher-order Higgs masses, widths and mixing factors) and at the 1-loop level including corrections of O(α) with respect to the lowest order. Within the considered parameter region, the chosen modified Mhmax-scenario leads to a small difference between the loop-corrected masses of Mh and MH below their total widths. This configuration results in a large negative interference term so that in the standard NWA, where the interference contribution is not taken into account, the 3-body decay width is overestimated by a factor of up to five in this example. Hence, the standard NWA is clearly insufficient in this scenario. The inclusion of the factorised interference term, however, leads to an agreement with the unfactorised decay width within few percent. At the tree level, the method of on-shell matrix elements and the R-factor approximation lead to very similar results.

However, at the Born level the methods for calculating multi-leg processes without further approximations are very advanced. Accordingly, a particular interest in the NWA concerns its application to the loop level, where the difficulty in computing processes involving a variety of different mass scales grows very significantly with the number of external legs of the process. In many cases the factorisation into different sub-processes provided by the NWA is essential to enable the computation of higher-order contributions. In cases where a full tree level calculation is feasible, the NWA can therefore be applied just at the loop level in order to facilitate the computation of the higher-order corrections, while the lowest order contributions are evaluated without further approximations in order to avoid an unnecessary theoretical uncertainty.

For a validation of the gNWA beyond the LO we have performed the 1-loop calculation of Γ(χ~40χ~10τ+τ-) including all vertex corrections, self-energies involving Higgs-Goldstone/Z mixing, Higgs-Higgs mixing contributions via finite wave function normalisation factors, box diagrams, as well as soft photon radiation. All higher order corrections except for the box diagrams factorise, which makes a separate calculation of the 1-loop production and decay part possible as long as the non-factorisable contributions remain sufficiently small. We have shown that within the gNWA the factorised interference term at the next-to-leading order is both UV- and IR-finite. In order to preserve the cancellations of IR-singularities between virtual and real photon contributions also in the on-shell matrix elements, all IR-divergent integrals in matrix elements and the soft-photon factor were evaluated at the same mass value. This prescription could be further improved by extracting the singular parts from the real photon contribution and applying the NWA only to those terms which match the singularities from the virtual photons. Furthermore, we have extended the interference weight factor to the 1-loop level. In the numerical comparison to the 3-body decay width, the gNWA based on 1-loop on-shell matrix elements agrees with the full 1-loop result within an accuracy of better than 1%, which is much below the typical size of the loop corrections in this case. The gNWA with interference weight factors, on the other hand, deviates from the full result by up to 4%, which is still about a factor of two smaller than the size of the loop correction in the region where the latter is sizable. Therefore the method of on-shell matrix elements appears to be a well-suited approach for predicting the interference term at 1-loop order within roughly the remaining theoretical uncertainty of the full result, while the additional R-factor approximation may be of interest as a technically simpler rough estimate of the higher-order result including interference effects.

In our discussion we have first focussed on the strict O(α) contribution relative to the lowest order within the gNWA (except for masses, total widths and wave function normalisation factors, for which we have incorporated dominant 2-loop contributions throughout this work) for the purpose of a consistent comparison with the 3-body decay width. In the most accurate final result the factorisation into subprocesses for production and decay has the virtue that higher-order corrections can naturally be implemented into each of the subprocesses, which formally corresponds to a higher-order effect for the full process. This applies also to the interference term, where we have discussed the incorporation of higher-order contributions for the two considered versions of the gNWA.

While much of our discussion has been directed to the specific example process that we have investigated, we have provided a generic formulation of the gNWA and we have commented on various features that are relevant for more complicated processes. The method presented here should therefore be transferable to processes with more external legs, with a more complicated structure of IR divergencies, and to cases where the interference arises between particles of non-zero spin.

Based on the methodical study presented here, a next step will be a more detailed investigation of phenomenological applications of the gNWA. This will be addressed in a forthcoming publication.

Acknowledgments

We thank Alison Fowler for the initial step of this work in her PhD thesis [10] and for providing us with her FeynArts model file. Furthermore, we are thankful to Aoife Bharucha for useful discussions on the renormalisation of the neutralino sector and to Thomas Hahn and Sven Heinemeyer for support with FormCalc and FeynHiggs. E.F. thanks Howard Haber and the other SCIPP members at UC Santa Cruz as well as the CERN theory group, especially Andreas Weiler, for hospitality and interesting discussions, and the Studienstiftung des deutschen Volkes, DAAD and the PIER Helmholtz Graduate School for financial support. The work of G.W. is supported in part by the Collaborative Research Centre SFB 676 of the DFG, “Particles, Strings and the Early Universe”, and by the European Commission through the “HiggsTools” Initial Training Network PITN-GA-2012-316704.

Footnotes

1

We refer to partonic cross sections, but the overall q2-dependence can be affected by folding with pdfs.

2

We used FeynArts-3.7, FormCalc-7.4, LoopTools-2.8 and FeynHiggs-2.9.3.

3

These helicity matrix elements correspond to the FormCalc-HelicityMEs via Aij=4·MatF(i,j). The factor of 4 arises because the FormCalc expressions are multiplied later on by 2 for each external fermion.

4

In this section, the full tree level refers to the sum of h- and H-mediated 3-body decays including the interference term (but without A- and Z-boson exchange or non-resonant propagators) at the improved Born level, i.e. including Higgs masses, total widths and Z^-factors at the leading 2-loop level from FeynHiggs [4851].

5

If the full Born cross section cannot be calculated, this term can be replaced by the gNWA at the Born level.

6

With strict 1-loop we refer to the expansion of the products of matrix elements whereas 2-loop Higgs masses, total widths and wave function renormalisation factors are employed.

7

As a further step, one could split the real photon contribution into IR-singular and finite terms and apply the NWA only on the singular ones according to Refs. [4, 37].

Contributor Information

Elina Fuchs, Email: elina.fuchs@desy.de.

Georg Weiglein, Email: georg.weiglein@desy.de.

References

  • 1.Matthews P, Salam A. Relativistic field theory of unstable particles. Phys. Rev. 1958;112:283–287. doi: 10.1103/PhysRev.112.283. [DOI] [Google Scholar]
  • 2.Veltman M. Unitarity and causality in a renormalizable field theory with unstable particles. Physica. 1963;29:186–207. doi: 10.1016/S0031-8914(63)80277-3. [DOI] [Google Scholar]
  • 3.R. Eden, P. Landshoff, D. Olive, J. Polkinghorne, The Analytic S-Matrix. Cambridge University Press, Cambridge (1966)
  • 4.M.W. Grunewald, G. Passarino, E. Accomando, A. Ballestrero, P. Bambade et al., Reports of the working groups on precision calculations for LEP2 physics. In: Proceedings. Four Fermion Production in Electron Positron Collisions. arXiv:hep-ph/0005309 [hep-ph]
  • 5.Argyres EN, Beenakker W, van Oldenborgh GJ, Denner A, Dittmaier S, et al. Stable calculations for unstable particles: restoring gauge invariance. Phys. Lett. 1995;B358:339–346. doi: 10.1016/0370-2693(95)01002-8. [DOI] [Google Scholar]
  • 6.Beenakker W, van Oldenborgh GJ, Denner A, Dittmaier S, Hoogland J, et al. The Fermion loop scheme for finite width effects in e+e- annihilation into four fermions. Nucl. Phys. 1997;B500:255–298. doi: 10.1016/S0550-3213(97)00316-7. [DOI] [Google Scholar]
  • 7.Aeppli A, van Oldenborgh GJ, Wyler D. Unstable particles in one loop calculations. Nucl. Phys. 1994;B428:126–146. doi: 10.1016/0550-3213(94)90195-3. [DOI] [Google Scholar]
  • 8.Berdine D, Kauer N, Rainwater D. Breakdown of the narrow width approximation for new physics. Phys. Rev. Lett. 2007;99:111601. doi: 10.1103/PhysRevLett.99.111601. [DOI] [PubMed] [Google Scholar]
  • 9.J. Reuter, Off-Shell and Interference Effects for SUSY Particle Production. eConf C0705302, SUS14 (2007). arXiv:0709.0068 [hep-ph]
  • 10.A. Fowler, Higher order and CP-violating effects in the neutralino and Higgs boson sectors of the MSSM. PhD Thesis, Durham (2010)
  • 11.Nilles HP. Supersymmetry, supergravity and particle physics. Phys. Rept. 1984;110:1–162. doi: 10.1016/0370-1573(84)90008-5. [DOI] [Google Scholar]
  • 12.Haber HE, Kane GL. The search for supersymmetry: probing physics beyond the standard model. Phys. Rept. 1985;117:75–263. doi: 10.1016/0370-1573(85)90051-1. [DOI] [Google Scholar]
  • 13.Barbieri R. Looking beyond the standard model: the supersymmetric option. Riv. Nuovo Cim. 1988;11N4:1–15. doi: 10.1007/BF02725953. [DOI] [Google Scholar]
  • 14.Haber HE, Nir Y. Multiscalar models with a high-energy scale. Nucl. Phys. B. 1990;335:363. doi: 10.1016/0550-3213(90)90499-4. [DOI] [Google Scholar]
  • 15.G. Aad and others [ATLAS Collaboration], Observation of a new particle in the search for the Standard Model Higgs boson with the ATLAS detector at the LHC. Phys. Lett. B 716, 1–29 (2012). arXiv:1207.7214 [hep-ex]
  • 16.S. Chatrchyan et al. [CMS Collaboration], Observation of a new boson at a mass of 125 GeV with the CMS experiment at the LHC. Phys. Lett. B 716, 30–61 (2012). arXiv:1207.7235 [hep-ex]
  • 17.Gunion JF, Jiang Y, Kraml S. Could two NMSSM Higgs bosons be present near 125 GeV? Phys. Rev. D. 2012;86:071702. doi: 10.1103/PhysRevD.86.071702. [DOI] [Google Scholar]
  • 18.Ferreira P, Santos R, Haber HE, Silva JP. Mass-degenerate Higgs bosons at 125 GeV in the two-Higgs-doublet model. Phys. Rev. D. 2013;87(5):055009. doi: 10.1103/PhysRevD.87.055009. [DOI] [Google Scholar]
  • 19.Drozd A, Grzadkowski B, Gunion JF, Jiang Y. Two-Higgs-doublet models and enhanced rates for a 125 GeV Higgs. JHEP. 2013;1305:072. doi: 10.1007/JHEP05(2013)072. [DOI] [Google Scholar]
  • 20.Appelquist T, Cheng H-C, Dobrescu BA. Bounds on universal extra dimensions. Phys. Rev. D. 2001;64:035002. doi: 10.1103/PhysRevD.64.035002. [DOI] [Google Scholar]
  • 21.Cheng H-C, Matchev KT, Schmaltz M. Bosonic supersymmetry? Getting fooled at the CERN LHC. Phys. Rev. D. 2002;66:056006. doi: 10.1103/PhysRevD.66.056006. [DOI] [Google Scholar]
  • 22.Hooper D, Profumo S. Dark matter and collider phenomenology of universal extra dimensions. Phys. Rept. 2007;453:29–115. doi: 10.1016/j.physrep.2007.09.003. [DOI] [Google Scholar]
  • 23.de Blas J, Lizana J, Perez-Victoria M. Combining searches of Z’ and W’ bosons. JHEP. 2013;1301:166. doi: 10.1007/JHEP01(2013)166. [DOI] [Google Scholar]
  • 24.M. Gigg, P. Richardson, Simulation of finite width effects in physics beyond the standard model. arXiv:0805.3037 [hep-ph]
  • 25.Kalinowski J, Kilian W, Reuter J, Robens T, Rolbiecki K. Pinning down the invisible Sneutrino. JHEP. 2008;10:090. doi: 10.1088/1126-6708/2008/10/090. [DOI] [Google Scholar]
  • 26.C.F. Uhlemann, Narrow-width approximation in the minimal supersymmetric standard model. Diploma Thesis, Würzburg (2007)
  • 27.Cacciapaglia G, Deandrea A, De Curtis S. Nearby resonances beyond the Breit–Wigner approximation. Phys. Lett. B. 2009;682:43–49. doi: 10.1016/j.physletb.2009.10.090. [DOI] [Google Scholar]
  • 28.E. Fuchs, Interference effects in the MSSM in a generalised narrow-width approximation. Master’s thesis, Göttingen/ DESY, II. Physik-UniGö-MSc-2012/03 (2012)
  • 29.Barducci D, Belyaev A, Blamey J, Moretti S, Panizzi L, et al. Towards model-independent approach to the analysis of interference effects in pair production of new heavy quarks. JHEP. 2014;1407:142. doi: 10.1007/JHEP07(2014)142. [DOI] [Google Scholar]
  • 30.Gottfried K, Jackson JD. On the connection between production mechanism and decay of resonances at high-energies. Nuovo Cim. 1964;33:309–330. doi: 10.1007/BF02750195. [DOI] [Google Scholar]
  • 31.Dicus DA, Sudarshan E, Tata X. Factorization theorem for decaying spinning particles. Phys. Lett. B. 1985;154:79. doi: 10.1016/0370-2693(85)91571-0. [DOI] [Google Scholar]
  • 32.Wackeroth D, Hollik W. Electroweak radiative corrections to resonant charged gauge boson production. Phys. Rev. 1997;D55:6788–6818. [Google Scholar]
  • 33.Freitas A, Hollik W, Walter W, Weiglein G. Electroweak two loop corrections to the M(W)–M(Z) mass correlation in the standard model. Nucl. Phys. 2002;B632:189–218. doi: 10.1016/S0550-3213(02)00243-2. [DOI] [Google Scholar]
  • 34.Kauer N. Narrow-width approximation limitations. Phys. Lett. B. 2007;649:413–416. doi: 10.1016/j.physletb.2007.04.036. [DOI] [PubMed] [Google Scholar]
  • 35.Uhlemann CF, Kauer N. Narrow-width approximation accuracy. Nucl. Phys. B. 2009;814:195–211. doi: 10.1016/j.nuclphysb.2009.01.022. [DOI] [Google Scholar]
  • 36.E. Accomando, D. Becciolini, A. Belyaev, S. Moretti, C. Shepherd-Themistocleous, Z’ at the LHC: interference and finite width effects in Drell–Yan. JHEP 1310, 153 (2013). arXiv:1304.6700 [hep-ph]
  • 37.Denner A, Dittmaier S, Roth M, Wackeroth D. Electroweak radiative corrections to e+ e- - W W - 4 fermions in double pole approximation: the RACOONWW approach, Nucl. Phys. 2000;B587:67–117. doi: 10.1016/S0550-3213(00)00511-3. [DOI] [Google Scholar]
  • 38.Kauer N. A threshold-improved narrow-width approximation for BSM physics. JHEP. 2008;04:055. doi: 10.1088/1126-6708/2008/04/055. [DOI] [Google Scholar]
  • 39.Kauer N, Passarino G. Inadequacy of zero-width approximation for a light Higgs boson signal. JHEP. 2012;1208:116. doi: 10.1007/JHEP08(2012)116. [DOI] [Google Scholar]
  • 40.J. Beringer et al. [Particle Data Group], Review of particle physics (RPP). Phys. Rev. D 86, 010001 (2012)
  • 41.E. Byckling, K. Kajantie, Particle Kinematics. Wiley, New York (1972)
  • 42.Kauer N. Inadequacy of zero-width approximation for a light Higgs boson signal. Mod. Phys. Lett. A. 2013;28:1330015. doi: 10.1142/S0217732313300152. [DOI] [Google Scholar]
  • 43.Hahn T, Perez-Victoria M. Automatized one-loop calculations in four and D dimensions. Comput. Phys. Commun. 1999;118:153–165. doi: 10.1016/S0010-4655(98)00173-8. [DOI] [Google Scholar]
  • 44.T. Hahn, Generating and calculating one loop Feynman diagrams with FeynArts, FormCalc, and LoopTools. arXiv:hep-ph/9905354 [hep-ph]
  • 45.Hahn T. Automatic loop calculations with FeynArts, FormCalc, and LoopTools. Nucl. Phys. Proc. Suppl. 2000;89:231–236. doi: 10.1016/S0920-5632(00)00848-3. [DOI] [Google Scholar]
  • 46.Hahn T, Rauch M. News from FormCalc and LoopTools. Nucl. Phys. Proc. Suppl. 2006;157:236–240. doi: 10.1016/j.nuclphysbps.2006.03.026. [DOI] [Google Scholar]
  • 47.Hahn T. A mathematica interface for FormCalc-generated code. Comput. Phys. Commun. 2008;178:217–221. doi: 10.1016/j.cpc.2007.09.004. [DOI] [Google Scholar]
  • 48.Heinemeyer S, Hollik W, Weiglein G. The masses of the neutral CP—even Higgs bosons in the MSSM: accurate analysis at the two loop level. Eur. Phys. J. C. 1999;9:343–366. [Google Scholar]
  • 49.Heinemeyer S, Hollik W, Weiglein G. FeynHiggs: a program for the calculation of the masses of the neutral CP-even Higgs bosons in the MSSM. Comput. Phys. Commun. 2000;124:76–89. doi: 10.1016/S0010-4655(99)00364-1. [DOI] [Google Scholar]
  • 50.Degrassi G, Heinemeyer S, Hollik W, Slavich P, Weiglein G. Towards high-precision predictions for the MSSM Higgs sector. Eur. Phys. J. C. 2003;28:133–143. doi: 10.1140/epjc/s2003-01152-2. [DOI] [Google Scholar]
  • 51.Heinemeyer S, Hollik W, Rzehak H, Weiglein G. The Higgs sector of the complex MSSM at two-loop order: QCD contributions. Phys. Lett. B. 2007;652:300–309. doi: 10.1016/j.physletb.2007.07.030. [DOI] [Google Scholar]
  • 52.Frank M, Hahn T, Heinemeyer S, Hollik W, Rzehak H, Weiglein G. The Higgs boson masses and mixings of the complex MSSM in the Feynman-diagrammatic approach. JHEP. 2007;02:047. doi: 10.1088/1126-6708/2007/02/047. [DOI] [Google Scholar]
  • 53.Williams KE, Rzehak H, Weiglein G. Higher order corrections to Higgs boson decays in the MSSM with complex parameters. Eur. Phys. J. C. 2011;71:1669. doi: 10.1140/epjc/s10052-011-1669-3. [DOI] [Google Scholar]
  • 54.A. Fowler, E. Fuchs, G. Weiglein, Breit–Wigner approximation of full Higgs propagator mixing in the MSSM (in preparation)
  • 55.Chatterjee A, Drees M, Kulkarni S, Xu Q. On the on-shell renormalization of the chargino and neutralino masses in the MSSM. Phys. Rev. D. 2012;85:075013. doi: 10.1103/PhysRevD.85.075013. [DOI] [Google Scholar]
  • 56.Bharucha A, Fowler A, Moortgat-Pick G, Weiglein G. Consistent on shell renormalisation of electroweakinos in the complex MSSM: LHC and LC predictions. JHEP. 2013;1305:053. doi: 10.1007/JHEP05(2013)053. [DOI] [Google Scholar]
  • 57.Lahanas A, Tamvakis K, Tracas N. One loop corrections to the neutralino sector and radiative electroweak breaking in the MSSM. Phys. Lett. 1994;B324:387–396. doi: 10.1016/0370-2693(94)90211-9. [DOI] [Google Scholar]
  • 58.Pierce D, Papadopoulos A. Radiative corrections to neutralino and chargino masses in the minimal supersymmetric model. Phys. Rev. 1994;D50:565–570. doi: 10.1103/physrevd.50.565. [DOI] [PubMed] [Google Scholar]
  • 59.Pierce D, Papadopoulos A. The complete radiative corrections to the gaugino and Higgsino masses in the minimal supersymmetric model. Nucl. Phys. 1994;B430:278–294. doi: 10.1016/0550-3213(94)00303-3. [DOI] [PubMed] [Google Scholar]
  • 60.Eberl H, Kincel M, Majerotto W, Yamada Y. One loop corrections to the chargino and neutralino mass matrices in the on-shell scheme. Phys. Rev. D. 2001;64:115013. doi: 10.1103/PhysRevD.64.115013. [DOI] [Google Scholar]
  • 61.Fritzsche T, Hollik W. Complete one loop corrections to the mass spectrum of charginos and neutralinos in the MSSM. Eur. Phys. J. 2002;C24:619–629. doi: 10.1007/s10052-002-0992-0. [DOI] [Google Scholar]
  • 62.Oller W, Eberl H, Majerotto W, Weber C. Analysis of the chargino and neutralino mass parameters at one loop level. Eur. Phys. J. 2003;C29:563–572. doi: 10.1140/epjc/s2003-01246-9. [DOI] [Google Scholar]
  • 63.Drees M, Hollik W, Xu Q. One-loop calculations of the decay of the next-to-lightest neutralino in the MSSM. JHEP. 2007;0702:032. doi: 10.1088/1126-6708/2007/02/032. [DOI] [Google Scholar]
  • 64.Fowler A, Weiglein G. Precise predictions for Higgs production in neutralino decays in the complex MSSM. JHEP. 2010;1001:108. doi: 10.1007/JHEP01(2010)108. [DOI] [Google Scholar]
  • 65.Bharucha A, Heinemeyer S, von der Pahlen F, Schappacher C. Neutralino decays in the complex MSSM at one-loop: a comparison of on-shell renormalization schemes. Phys. Rev. D. 2012;86:075023. doi: 10.1103/PhysRevD.86.075023. [DOI] [Google Scholar]
  • 66.Kublbeck J, Bohm M, Denner A. FeynArts: computer algebraic generation of Feynman graphs and amplitudes. Comput. Phys. Commun. 1990;60:165–180. doi: 10.1016/0010-4655(90)90001-H. [DOI] [Google Scholar]
  • 67.A. Denner, H. Eck, O. Hahn, J. Kublbeck, Feynman rules for fermion number violating interactions. Nucl. Phys. B 387, 467–484 (1992)
  • 68.Kublbeck J, Eck H, Mertig R. Computeralgebraic generation and calculation of Feynman graphs using FeynArts and FeynCalc. Nucl. Phys. Proc. Suppl. 1992;29A:204–208. [Google Scholar]
  • 69.Hahn T. Generating Feynman diagrams and amplitudes with FeynArts 3. Comput. Phys. Commun. 2001;140:418–431. doi: 10.1016/S0010-4655(01)00290-9. [DOI] [Google Scholar]
  • 70.Hahn T, Schappacher C. The implementation of the minimal supersymmetric standard model in FeynArts and FormCalc. Comput. Phys. Commun. 2002;143:54–68. doi: 10.1016/S0010-4655(01)00436-2. [DOI] [Google Scholar]
  • 71.H.E. Haber, Spin formalism and applications to new physics searches. arXiv:hep-ph/9405376 [hep-ph]
  • 72.Jacob M, Wick G. On the general theory of collisions for particles with spin. Ann. Phys. 1959;7:404–428. doi: 10.1016/0003-4916(59)90051-X. [DOI] [Google Scholar]
  • 73.M.S. Carena, S. Heinemeyer, C.E.M. Wagner, G. Weiglein, Suggestions for improved benchmark scenarios for Higgs- boson searches at LEP2. arXiv:hep-ph/9912223
  • 74.Carena MS, Heinemeyer S, Wagner C, Weiglein G. Suggestions for benchmark scenarios for MSSM Higgs boson searches at hadron colliders. Eur. Phys. J. 2003;C26:601–607. doi: 10.1140/epjc/s2002-01084-3. [DOI] [Google Scholar]
  • 75.Denner A. Techniques for calculation of electroweak radiative corrections at the one loop level and results for W physics at LEP-200. Fortsch. Phys. 1993;41:307–420. [Google Scholar]
  • 76.T. Hahn, FormCalc 7 User’s Guide (2012)
  • 77.Denner A, Dittmaier S, Roth M. “Nonfactorizable photonic corrections to e+ e- - W W - four fermions,”. Nucl. Phys. 1998;B519:39–84. doi: 10.1016/S0550-3213(98)00046-7. [DOI] [Google Scholar]
  • 78.Kinoshita T. Mass singularities of Feynman amplitudes. J. Math. Phys. 1962;3:650–677. doi: 10.1063/1.1724268. [DOI] [Google Scholar]
  • 79.Lee T, Nauenberg M. Degenerate systems and mass singularities. Phys. Rev. 1964;133:B1549–B1562. doi: 10.1103/PhysRev.133.B1549. [DOI] [Google Scholar]
  • 80.T. Hahn, Feynman diagram calculations with FeynArts, FormCalc, and LoopTools. PoS, 078 (2010). arXiv:1006.2231 [hep-ph]
  • 81.Chankowsk PH, Pokorski S, Rosiek J. Complete on-shell renormalization scheme for the minimal supersymmetric Higgs sector. Nucl. Phys. 1994;B423:437–496. doi: 10.1016/0550-3213(94)90141-4. [DOI] [Google Scholar]
  • 82.Heinemeyer S, Hollik W, Rosiek J, Weiglein G. Neutral MSSM Higgs boson production at e+ e- colliders in the Feynman diagrammatic approach. Eur. Phys. J. 2001;C19:535–546. doi: 10.1007/s100520100631. [DOI] [Google Scholar]
  • 83.K. Williams, The Higgs Sector of the Complex Minimal Supersymmetric Standard Model. PhD thesis, Durham (2008)

Articles from The European Physical Journal. C, Particles and Fields are provided here courtesy of Springer

RESOURCES