Precise prediction for the W boson mass in the MRSSM

The mass of the W boson, MW, plays a central role for high-precision tests of the electroweak theory. Confronting precise theoretical predictions with the accurately measured experimental value provides a high sensitivity to quantum effects of the theory entering via loop contributions. The currently most accurate prediction for the W boson mass in the Minimal R-symmetric Supersymmetric Standard Model (MRSSM) is presented. Employing the on-shell scheme, it combines all numerically relevant contributions that are known in the Standard Model (SM) in a consistent way with all MRSSM one-loop corrections. Special care is taken in the treatment of the triplet scalar vacuum expectation value vT that enters the prediction for MW already at lowest order. In the numerical analysis the decoupling properties of the supersymmetric loop contributions and the comparison with the MSSM are investigated. Potentially large numerical effects of the MRSSM-specific Λ superpotential couplings are highlighted. The comparison with existing results in the literature is discussed.


Introduction
Supersymmetry (SUSY) is seen as one of the most attractive extensions of the Standard Model (SM) of particle physics.It provides a solution for the hierarchy problem of the SM and a prediction for the mass of the scalar resonance discovered at the LHC [1][2][3] if it is appropriately identified with one of the neutral Higgs bosons of the considered supersymmetric model.
So far, no further new state has been discovered at the LHC.The search limits from the LHC and previous colliders give rise to strong constraints on the parameter space of the Minimal Supersymmetric Standard Model (MSSM).The impact of those search limits may be much smaller for models with extended SUSY sectors.In particular, the introduction of R-symmetry [4] leads to models where the limits on the particle masses are significantly weaker and where accordingly the discovery of TeV-scale SUSY is still in reach of current experiments.
The LHC phenomenology of the Minimal R-symmetric Supersymmetric Standard Model (MRSSM) [5] and other models with R-symmetry has recently been explored in refs.[6][7][8][9][10][11][12][13][14][15].The signatures of the MRSSM differ from the ones of the MSSM as the model includes Dirac gauginos and higgsinos instead of Majorana ones.This goes hand in hand with additional states in the Higgs sector including an SU(2) triplet, which may acquire a vacuum expectation value breaking the custodial symmetry of the electroweak sector.Additionally, R-symmetry forbids all soft SUSY-breaking trilinear couplings between Higgs bosons and squarks or sleptons, which removes unwanted sources of flavour violation which exist in the MSSM.
Even with no direct signals of SUSY indirect probes like electroweak precision observables can provide sensitivity to SUSY contributions above the direct experimental reach.Here we study the prediction for the mass of the W gauge-boson, M W .The world average combining LEP and Tevatron results [16,17] is It may be improved by measurements of the LHC experiments, where a first ATLAS result at √ s = 7 TeV reports a value [18] of M ATLAS W = 80.370 ± 0.019 GeV . (1. 2) The statistical combination of the ATLAS measurement (1.2) with the one of eq.(1.1) yields an updated experimental result of [19] M LEP+Tevatron+ATLAS W = 80.379 ± 0.012 GeV . ( For a meaningful comparison to experiment a precise theory prediction is necessary.In the Standard Model (SM) the prediction includes contributions at the one-loop [20,21] and two-loop level [22][23][24][25][26][27][28][29][30][31][32][33], as well as leading three-and four-loop corrections [34][35][36][37][38][39][40][41][42][43].In refs.[44,45] a parametrisation of the M W prediction containing all known higher-order corrections in the on-shell scheme has been given.Updating the experimental results for the input values [19] 1 and identifying the scalar state discovered at the LHC with the Standard Model Higgs boson leads to a prediction for the W boson mass in the Standard Model of M SM,on-shell W = 80.356 GeV .(1.4)This result shows a slight downward shift compared to the previous calculation [46] due to the updated input parameters.Hence, the long-standing tension of the experimental measurement and theoretical prediction of just below 2σ remains.
As similar result for the W boson mass prediction in the SM has been obtained for a mixed on-shell/DR scheme in ref. [50] and updated in ref. [67].
The largest parametric uncertainty is induced by the top quark mass.For the experimental value m exp.t = 173.0± 0.4 GeV (1.5) the quoted experimental error accounts only for the uncertainty in extracting the measured parameter.This needs to be supplemented with the systematic uncertainty arising from relating the measured mass parameter to a theoretically well-defined quantity such as the MS mass.This uncertainty could be reduced very significantly with a measurement of the top quark mass from the t t threshold at a future e + e − collider Accurate theoretical predictions for the W boson mass have also been obtained for the most popular supersymmetric extensions of the SM, in particular for the MSSM [46][47][48], see also ref. [49] and references therein, and the NMSSM [46], in the on-shell scheme.Furthermore, results are available in the mixed on-shell/DR scheme for the MSSM first studied in ref. [51], which has been adapted for mass spectrum generators e.g.SPheno [? ] and SoftSUSY [? ] which also includes extensions to the NMSSM [? ].
For the MRSSM the W boson mass has been studied together with other electroweak precision observables in ref. [6].The MRSSM result of ref. [6] was obtained for the aforementioned mixed on-shell/DR scheme where only the gauge-boson masses M W and M Z are on-shell quantities, making use and adapting the tools SARAH and SPheno [52][53][54][55][56][57][58][59].Recently, a new implementation of this calculation in the program FlexibleSUSY 2.0 [60] has shown a large discrepancy in the MSSM with the result that was achieved in the on-shell scheme [46][47][48] and also a large discrepancy in the MRSSM with the result of ref. [6].
In this paper we present an improved prediction for the W boson mass in the MRSSM.Employing the on-shell scheme for the SM-type parameters, we obtain the complete oneloop contributions in the MRSSM and combine them with the state-of-the-art SM-type corrections up to the four-loop level.In the calculation of the MRSSM contributions a renormalisation of the triplet scalar vacuum expectation value v T is needed since this parameter enters the prediction for M W already at lowest order.We investigate the treatment of this parameter and implement a DR-type renormalisation.In our numerical analysis we study the decoupling limit where the SUSY particles are heavy and verify that the SM prediction is recovered in this limit.We investigate the possible size of the different MRSSM contributions and compare the results with the MSSM case.We also discuss the comparison of our result with the existing MRSSM results.
The paper is organised as follows: In section 2 we give a brief overview of the MRSSM field content and introduce the relevant model parameters required to discuss the calculation of the M W prediction in this model.In section 3 details on the calculation of the higher-order corrections to the muon decay process are presented.Section 4 contains the details on the implementation of the calculation, while in section 5 we present a quantitative study of the M W prediction in the MRSSM parameter space and a comparison of our results to previous calculations.We conclude in section 6.
2 The Minimal R-symmetric Supersymmetric Standard Model

Model overview
The minimal R-symmetric extension of the MSSM, the MRSSM, requires the introduction of Dirac mass terms for gauginos and higgsinos, since Majorana mass terms are forbidden by R-symmetry.This leads to the need for an extended number of chiral superfields containing the necessary additional fermionic degrees of freedom.
Therefore, the field content of the MRSSM is enlarged compared to the MSSM by doublet superfields Rd,u carrying R-charge under the R-symmetry as well as adjoint chiral superfields Ô, T , Ŝ for each of the gauge groups.The full field content of the MRSSM including the assignment of R-charges is given in table 1.
The R-charges of the superfields and the corresponding bosonic and fermionic components.
In the following we introduce the parameters of the MRSSM.All model parameters are taken to be real for the purpose of this work.The MRSSM superpotential is given as where the dot denotes the contraction with 12 = +1.In order to achieve canonical kinetic terms the triplet is defined as The usual µ term of the MSSM is forbidden by R-symmetry but similar terms can be written down connecting the Higgs doublets to the inert R-Higgs fields with the parameters µ d,u .Trilinear couplings Λ d,u and λ d,u couple the doublets to the adjoint triplet and singlet field, respectively.The Yukawa couplings Y d,e,u are the same as in the MSSM.The soft SUSY-breaking Lagrangian contains the soft masses for all scalars as well as the usual B µ term.Trilinear A-terms of the MSSM are forbidden by R-symmetry. 2 This part of the Lagrangian reads Dirac mass terms connecting the gauginos and the fermionic components of the adjoint superfields are introduced.They are generated from the R-symmetric operator involving the D-type spurion [61] 3 where M is the mediation scale of SUSY breaking , W α i represents the gauge superfield strength tensors, gi = g, W , B is the gaugino, and g i = Õ, T , S is the corresponding Dirac partner with opposite R-charge which is part of a chiral superfield Φi = Ô, T , Ŝ.The mass term is generated by the spurion field strength Ŵ α,i = θ α D i getting a vev D i = M M D i .Additionally, integrating out the spurion in eq.(2.4) generates terms coupling the D-fields to the scalar components of the chiral superfields, which leads to the appearance of Dirac masses also in the Higgs sector, During electroweak symmetry breaking (EWSB) the neutral EW scalars with no Rcharge develop vacuum expectation values (vevs) After EWSB the singlet and triplet vevs effectively shift the µ-parameters of the model, and it is useful to define the abbreviations The R = 0 Higgs sector contains four CP-even and three CP-odd neutral as well as three charged Higgs bosons.The Higgs doublets with R-charge 2 stay inert and do not receive a vev such that two additional complex neutral and charged scalars are predicted by the MRSSM.The sfermion sector is the same as in the MSSM with the restriction that mixing between the left-and right-handed sfermions is forbidden by R-symmetry.In the MRSSM the number of chargino and higgsino degrees of freedom is doubled compared to the MSSM as the neutralinos are Dirac-type and there are two separated chargino sectors where the product of electric and R-charge is either 1 or −1.
The mass matrices of the SUSY states can be found in ref. [6].The masses of the gauge bosons arise as usual with an important distinction which will be discussed in more detail in the following.

The W boson mass in the MRSSM
The expression for the W boson mass differs from the usual form of the MSSM and the SM due to the triplet vev v T .With the representation in eq.(2.2) the kinetic term for the scalar triplet is given as (2.7) The possible contribution to the gauge-boson masses from a triplet vev arises from the quartic part as where the τ i are the Pauli matrices.The two terms of the last expression cancel each other for the neutral component when the triplet vev is inserted.Hence, only the mass of the charged W boson receives an additional contribution.Then, the lowest-order masses of the Z and W bosons in the MRSSM are given as ) The appearance of v T in the expression for the W boson mass is also relevant for the definition of the weak mixing angle as the introduction of v T spoils the accidental custodial symmetry of the SM.
Numerically the contribution due to the triplet vev is strongly constrained by the measurement of electroweak precision observables, especially ∆ρ which leads to a limit of |v T | 3 GeV.A more detailed discussion of its influence on the W boson mass is given in sec.5.2.1.
The weak mixing angle which diagonalises the neutral vector boson mass matrix leading to the photon and Z boson is related to the gauge couplings as usual where we have introduced the notation θW , cW and sW in order to distinguish those quantitities from the ones defined in eq.(2.12) below.Together with the electric charge e derived from the fine-structure constant α = e 2 /4π the weak mixing angle θW can be used to replace the gauge couplings, Additionally, we define the ratio of the masses of the electroweak gauge bosons as (2.12) In the limit of vanishing v T the two quantities s 2 W and s2 W coincide with each other at tree-level as in the MSSM.For the extraction of the W boson mass from the muon decay constant it is helpful to solve eq.(2.12) for s2 taking the physical solution such that s2 W → s 2 W for v T → 0 holds as required.

Determination of the W boson mass
The Fermi constant G F is an experimentally very precisely measured observable that is obtained from muon decay.The comparison with the theoretical prediction for muon decay yields a relation between the Fermi constant, the W boson mass, the Z boson mass and the fine-structure constant.Therefore a common approach is to use G F as an input in order to derive a prediction for the W boson mass in the SM and in BSM models.Muons decay to almost 100% via µ − → e − ν µ νe .The Fermi model describes this interaction via a four-point interaction with the coupling G F .It is connected to the experimentally precisely measured muon lifetime τ extracted by the MuLan experiment [63] via Here, F (m 2 e /m 2 µ ) collects effects of the electron mass on the final-state phase space, and ∆q denotes the QED corrections to the Fermi model up to two loops [64][65][66]. 4Detailed expressions can be found for instance in Chapter 10 of the Particle Data Group report [19].
Equating the expression in the Fermi model with the SM prediction in the on-shell scheme yields the following relation between the Fermi constant G F , the fine-structure constant α = e 2 /(4π) in the Thomson limit, and the pole masses (defined according to a Breit-Wigner shape with a running width, see below) of the Z and W bosons, M Z and M W , respectively, SM: where all higher-order contributions besides the ones appearing in eq.(2.14) are contained in the quantity ∆r.The same functional relation holds also in the MSSM and the NMSSM. 5  4 In the past, conventionally a factor (1 + (3m 2 µ )/(5M 2 W )) has often been inserted in eq.(2.14) in order to take into account tree-level W propagator effects even though this correction term is not part of the Fermi model.With the enhanced accuracy of the MuLan experiment this previously numerically negligible factor has to be taken into account on the side of the full SM calculation when using the experimentally extracted value of GF from ref. [19]. 5As mentioned above, tree-level effects from the longitudinal part of the W propagator and, for the case of an extended Higgs sector, of the charged Higgs boson(s) are understood to be incorporated into ∆r.As effects of this kind are insignificant for our numerical analysis, we will neglect them in the following.
The weak mixing angle in eq.(2.15) is given by s Z in accordance with eq.(2.12).
In the MRSSM the relation of eq.(2.15) gets modified because of the contribution of the triplet vev v T entering at lowest order, MRSSM: where s2 W originates from the gauge coupling g 2 , see eq. (2.11) and eq.(2.12).We use the notation ∆r for the higher-order contributions in the MRSSM, where eq.(2.16) is expressed in terms of the quantities M W , M Z , α defined in the on-shell scheme as in eq.(2.15).Inserting eq.(2.13) into eq.(2.16) and solving for M 2 W yields As ∆r itself depends on M W it is technically most convenient to determine M W numerically through an iteration of this relation.In the limit v T → 0 the result of eq.(2.17) yields the well-known expression that is valid in the SM, since ∆r coincides with the usual definition of ∆r in this case.
As mentioned above, in the previous calculation [6] for the MRSSM a mixed scheme was used where only the gauge-boson masses M W and M Z are on-shell quantities.For completeness we provide a short description of this scheme.Following refs.[50,67], the running electromagnetic coupling αMS/DR and the running mixing angle ŝ2 W,MS/DR are used in this scheme together with the on-shell definitions of the masses.Here, MS/DR denotes renormalisation via modified minimal subtraction either in dimensional regularisation or reduction.Higher-order corrections are collected in several parameters that incorporate a resummation of certain reducible higher-order contributions, in particular where (2.20) Here ∆ρ 0 contains the tree-level shift arising from the triplet vev, while ∆ρ 0 contains the higher-order corrections including all MRSSM one-loop and leading SM two-loop effects, ΣT denotes the transverse part of the DR-renormalised self-energies of the gauge bosons, and indicates the real part.Analogously to eq. (2.16) one can write MRSSM: where the quantities defined in eqs.(2.19), (2.20) have been used, and ∆r W contains additonal higher-order corrections.The described approach has been used in previous work for the MRSSM and is the one implemented in several MSSM and NMSSM mass spectrum generators following refs.[51,68].For an approach in a pure minimal subtraction scheme see ref. [69].
In the following, we discuss the details of the on-shell calculation in the MRSSM according to eq. (2.16), making use of the state-of-the-art prediction of the SM part, and compare it to previously obtained results.

∆r in the MRSSM
For our on-shell calculation of the W boson mass in the MRSSM we include all MRSSM SUSY effects at one-loop level and all known higher-order contributions of SM type.This follows the approach taken for the MSSM [46,47] and the NMSSM [46].

General contributions
At the one-loop level, ∆r (α) receives contributions from the W boson self-energy, from vertex and box corrections, as well as from the corresponding counterterm diagrams.It can be written as (3.1)The field renormalisation of the W boson drops out as the field only appears internally.The expressions for the MRSSM vertex and box contributions are given in the appendix of ref. [6].
Using the on-shell scheme, we fix the renormalisation constants of the gauge-boson masses as where Σ is the transverse part of the unrenormalised gauge-boson self-energy taken at momentum p 2 , and as before denotes the real part.The field renormalisation constant of a massless left-handed lepton is The electric charge is renormalised as had where the quantity ∆α (5) had (M 2 Z ) is extracted from experimental data and accounts for the contributions of the five light quark flavours.
For the renormalisation of the weak mixing angle s2 W the appearance of v T leads to differences compared to the SM and the MSSM.The parameter s 2 W is renormalised with the renormalisation constants of the gauge-boson masses (3.5) The renormalisation constant of the weak mixing angle s2 W can be expressed in terms of δs 2 W , δe, δv T and δM 2 Z using the relation between s2 W and s 2 W given in eq.(2.12), W by the self-energies of the vector bosons gives If the triplet vev was absent, the on-shell renormalisation of the electroweak parameters would be the same as in the SM and the MSSM, and δs 2 W and δs 2 W would coincide.It is important to note in this context that in our renormalisation prescription s2 W is treated as a dependent parameter as specified in eq.(3.6).The renormalisation of the triplet vev is described in the following section.This prescription for the weak mixing angle ensures that the contributions to δs 2 W /s 2 W incorporate the typical quadratic dependence on m t that is induced by the contribution of the top/bottom doublet to the ρ parameter at one-loop order.This behaviour was found to be absent in renormalisation schemes where the weak mixing angle is treated as an independent parameter that is fixed as a process-specific effective parameter sin 2 θ eff , see refs.[70][71][72].

Renormalisation of v T
The triplet vev v T is an additional parameter of the electroweak sector in the MRSSM compared to the MSSM.As it appears in the lowest-order relation between the muon decay constant and M W , eq. (2.17), 6 its renormalisation is required for the prediction of M W .In principle, in the MRSSM one could instead have used M W as an experimental input parameter in order to determine v T via eqs.(2.9)-(2.13).Among other drawbacks, in such an approach the SM limit of the MRSSM, which involves v T → 0, could not be carried out.Instead, we prefer to keep M W as an observable that can be predicted, using in particular G F as an experimental input, and compared to the experimental result as it is the case in the SM and the MSSM.
For the calculation of M W performed in this work we renormalise v T such that Accordingly, δv T only contains the divergent contribution (in the modified minimal subtraction scheme) with a prefactor κ, where the correct choice of the latter ensures that the renormalised quantities are finite.The value of v T is taken as input at the SUSY scale m SUSY .The triplet vev is the only BSM parameter entering the tree-level expression of eq.(2.9).All other BSM parameters of the MRSSM only enter the loop contributions and do not need to be renormalised at the one-loop level.As v T is a parameter of the electroweak potential a comment on the tadpole conditions is in order.The tree-level tadpoles are given as and one may trade one model parameter for each of the tadpoles.The numerical values of those parameters are fixed implicitly by the conditions t i ≡ 0 so that they now are expressed as functions of all the other input parameters of the model.In our calculation of M W we choose the set of m 2 Hu , m 2 H d , m 2 T and v S as dependent parameters.Choosing instead v T as a parameter to be fixed by the tadpole equations would require a renormalisation of all parameters in these relations.This would lead to a finite counterterm δv T which would have a complicated form but would be expected to have a numerically very small impact on the prediction of M W as it is suppressed in eq.(3.7) by a prefactor of v 2 T /M 2 Z .Our calculation for the M W prediction in the MRSSM is embedded into the framework of SARAH/SPheno described in section 4 below.There, we use a different set of parameters derived from solving the tadpole equations, namely v T is treated as an output there and m 2 T as input.The value for v T calculated by the SARAH/SPheno routines is then passed to our implementation of the M W calculation as an input.This is necessary as v T is much smaller than m SUSY for realistic parameter points.Therefore, small variations in v T during the required iteration might have strong effects on the BSM mass spectrum and may lead to numerical instabilities.For example, at tree-level a chosen v T value might lead to physical Higgs states while tachyonic states might appear after adding the loop corrections to the mass matrices and tadpole equations.This is circumvented by using in a first step m 2 T as input and keeping it positive.In the following we describe the treatment of the tadpole conditions in the SARAH/SPheno framework in more detail and illustrate that the definition that we have chosen for v T ensures that it is suitable as input for our calculation of M W satisfying eq.(3.8).
In the SARAH/SPheno framework free parameters are renormalised in the DR scheme, and the masses of the SUSY states are calculated to a considered loop order.The tadpoles are an exception in this context as they are renormalised relying on on-shell conditions.Hence, their counterterms cancel the tadpole diagrams, and the tadpole contributions do not need to be considered as subdiagrams of other loop diagrams.This means that the bare tadpole t 0,i is given as where Γ i (0) are the unrenormalised one-loop one-point functions.The renormalised tadpoles ti are required to vanish, corresponding to the minimum of the effective potential.The parameters chosen as dependent parameters via the tadpole conditions for the SARAH/SPheno mass spectrum calculation are m2 Hu , m2 H d , ṽT and ṽS .As the tadpoles are renormalised via on-shell conditions, the renormalised dependent parameters respect the tree-level relations while the counterterms of these parameters (δ m2 Hu , δ m2 H d , δṽ T , δṽ S ) have to contain finite parts.Therefore, considering only the finite part of all appearing quantities (i.e., counterterms that only contain a divergent contribution have been dropped) the finite parts of the counterterms are given implicitly via the following relations: Note that the terms containing λ d,u and Λ d,u arise from the terms involving µ eff,± d and µ eff,± u in eq.(3.9).
In the loop calculation one can then define parameters m 2,loop Hu , m 2,loop as sum of the tree-level parameter and the finite part of the counterterm.For the triplet vev we choose (as above, a purely divergent counterterm is dropped) This definition of v loop T corresponds to a renormalisation of v T with a purely divergent counterterm as required in eq.(3.8).Therefore, v loop T as an output of this procedure is a suitable input for the our calculation of the M W prediction.This change in parameterisation leads to a numerical difference between the value of m 2 T used for the M W calculation on the one hand and for the derivation of the loop-corrected SUSY mass spectrum on the other.As we consider the SUSY corrections only up to the one-loop level for ∆r the one-loop shift of the model parameter m 2 T formally leads to a higher-order effect that is beyond the considered order for the SUSY loop corrections.Solving eq.(3.11) for δṽ T | finite yields The divergent part of δṽ T on the other hand can be compared to the general expressions given in ref.
[? ] and we find agreement.
A compact expression for v T can be derived by solving the third equation of (3.9) for it.At tree-level, we get the following The magnitude of v T can be affected in several ways.On the one hand it can become small as a consequence of large SUSY mass scales appearing in the denominator.Here, the combination m 2 T + 4(M D W ) 2 is the squared tree-level mass matrix entry for the CP-even Higgs triplet.On the other hand, the numerator can become small.For tan β > 1 the term proportional to v 2 u dominates.If then g 2 M D W is numerically close to −Λ u µ eff,0 u a partial cancellation is possible leading to a reduced value for v T . 7 In ref. [73] the influence of the triplet vev on the decoupling behaviour in a model where the Standard Model is extended by a real triplet was studied.It was found that nondecoupling behaviour exists when the triplet mass parameter approaches large values while the triplet-doublet-doublet trilinear coupling also grows.While a detailed investigation of this issue in the MRSSM would go beyond the scope of the present paper, we note that studying the numerical one-loop contributions to the triplet tadpole Γ T we do not find a non-decoupling effect for a comparable limit.Hence, this effect does not appear in our numerical analysis, see also the discussion in section 5.1 where we compare the MRSSM prediction with the one of the SM for the case where the SUSY mass scale is made large.Our results regarding the decoupling behaviour of the MRSSM contributions can be qualitatively understood in the following way.In an effective field theory analysis of the decoupling behaviour one would study the matching of the MRSSM to an effective SM+triplet model.There, the tree-level matching conditions would fix the quartic triplet coupling to zero as it does not appear due to R-symmetry in the MRSSM.This affects the number of free parameters of the effective model, preventing the occurrence of nondecoupling behaviour.However, if one-loop matching conditions for the quartic coupling 7 It should be noted that the expressions in parenthesis in the numerator also appear in the Higgs mass matrix elements mixing the doublets and triplet.Therefore, if the triplet scalar mass parameter is not large, a certain tuning is necessary to reduce the admixture of the triplet Higgs component with the state at 125 GeV in order to ensure that the latter is sufficiently SM-like.Such a tuning would at the same time reduce the numerical value of vT .In the numerical scenarios studied in this paper, however, such a tuning does not occur since in our numerical analysis below the triplet mass is always much larger than the mass of the SM-like state in the parameter regions where the MW prediction is close to the experimental measurement.
were taken into account these contributions could in principle give rise to a non-decoupling effect.As those contributions would correspond to a two-loop effect in the MRSSM for the calculation of M W they are outside of the scope of the present work, and we leave the investigation of contributions of this kind to further study.

Higher-order contributions
For a reliable prediction of M W in a BSM model it is crucial to take into account SM-type corrections beyond one-loop order.Only upon the incorporation of the relevant two-loop and even higher-order SM-type loop contributions it is possible to recover the state-ofthe-art SM prediction within the current experimental and theoretical uncertainties in the appropriate limit of the BSM parameters, see e.g. the discussion in ref. [46].In our predictions we incorporate the complete two-loop and the numerically relevant higher-order SM-type contributions.
A further important issue in this context is the precise definition of the gauge-boson masses according to a Breit-Wigner resonance shape with running or fixed width.While the difference between the two prescriptions formally corresponds to an electroweak twoloop effect, numerically the associated shifts are about 27 MeV for M W and 34 MeV for M Z .

Breit-Wigner shape
The definition of the masses of unstable particles according to the real part of the complex pole of their propagator is gauge-independent also beyond one-loop order, while the definition according to the real pole is not.Expanding the propagator around the complex pole leads to a Breit-Wigner shape with fixed width (f.w.).Experimentally, the gauge boson masses are extracted, by definition, from a Breit-Wigner shape with a running width (r.w.).Hence, it is necessary to translate from the internally used fixed-width mass M f.w.

W
to the running-width mass M r.w.
W at the end of the calculation where for the decay width of the W boson, Γ W , we use the theoretical prediction parametrised by G F including first order QCD corrections, For M Z , which is an input parameter in the prediction for M W , the conversion from the running-width to the fixed-width definition is carried out in the first step of the calculation.
In the following, the labels f.w. and r.w. will not be displayed as the fixed-width gauge boson masses only appear internally in the calculation.If not stated differently, the parameters M W and M Z always refer to the definition of the gauge boson masses according to a Breit-Wigner shape with running width.

Implementation and estimate of remaining theoretical uncertainties
As for the previous work on the MRSSM [6][7][8][9]77], our prediction for M W is embedded in the framework of SARAH/SPheno [52][53][54][55][56][57][58][59], see also the discussion in section 3.1.2.We use SARAH-4.12.3 and SPheno-4.0.3 for this work.The complete calculation of the SUSY pole masses at the one-loop level in this framework is done in the DR renormalisation scheme.For this purpose no counterterms are calculated explicitly, but rather an implicit renormalisation is performed, such that divergences (including terms of γ E and log 4π) are dropped keeping only the finite part of loop functions.The input parameters of the calculation are the SUSY parameters at the SUSY mass scale m SUSY and α, G F , M Z as well as the quark and lepton masses.As explained in section 3.1.2,within the SARAH/SPheno framework the tadpole equations of the MRSSM including the relevant higher-order corrections are solved to obtain m 2 Hu , m 2 H d , v S and v T at m SUSY in terms of the other model parameters.In order to determine the SUSY mass spectrum two-loop renormalisation group equations are used to run between the electroweak scale and the SUSY scale.At the SUSY scale the pole masses of the superpartners are calculated at the one-loop order.The Higgs boson masses are calculated including also two-loop effects.9 As discussed in section 2.3, in the previous calculation [6] for the MRSSM the predictions for M W and also the weak mixing angle ŝ2 W,DR were derived from eqs. (2.19)-(2.21)using a mixed on-shell/DR calculation following ref.[51].
The prediction for M W presented in this work, which employs the on-shell scheme and incorporates the state-of-the-art SM-type contributions, has been integrated into the described framework by extending the generated SARAH/SPheno output by additional routines implementing the calculation described in the previous sections.For this part of the calculation, all SM parameters are renormalised on-shell while the SUSY masses are obtained from the input parameters via lowest-order relations.As described in section 3.1.2,v T is renormalised as DR parameter and taken at the SUSY scale.No renormalisation of the other SUSY parameters is required as they enter only at the one-loop level.This ensures the validity of symmetry relations between the SUSY parameters.The obtained fully analytical expressions for the one-loop parts are combined with the state-of-the-art higherorder corrections of SM-type as described in section 3.2.2.The evaluation of eq.(2.17) is carried out iteratively until numerical convergence is obtained.The prediction for the W boson mass obtained in this way is then employed to extract ŝ2 W,DR and calculate the DR gauge couplings using the parameter ρ according to eq. (2.20).These quantities are used as part of the SUSY mass spectrum calculation.
Concerning the remaining theoretical uncertainties of the prediction for the W boson mass in the MRSSM, one needs to account for theoretical uncertainties that are induced by the experimental errors of the input parameters as well as for uncertainties from unknown higher-order corrections.Among the experimental errors of the input parameters the one associated with the top-quark mass is the most relevant one leading to about a 4.5 MeV effect on the prediction of M W for a top pole mass uncertainty of δm t = 0.75 GeV.While the experimental value given in eq.(1.5) has a smaller error, as discussed above it does not take into account the systematic uncertainty arising from relating the measured mass parameter to a theoretically well-defined quantity that can be used as input for the prtediction of M W .The uncertainties on the hadronic contribution to ∆α and on M Z contribute up to 2.5 MeV each to the uncertainty of the M W prediction.The experimental error on the muon decay constant G F is negligible compared to the other sources.The same is true in the SM prediction for the experimental error on the Higgs boson mass.
The theoretical uncertainties from unknown higher-order contributions have been estimated in ref. [44] to be at the level of about 4 MeV in the SM for a light Higgs boson (M SM h < 300 GeV). 10 Uncertainties from unknown higher-order SUSY loop contributions have been estimated for the MSSM and the NMSSM in refs.[46,47].Since SUSY loop 9 SARAH/SPheno in principle supports EFT matching to the SM for the calculation of the mass of the SM-like Higgs boson.However, this would require specific adjustments for the case of the MRSSM. 10In ref. [67] an estimate of 6 MeV was given for the uncertainty by comparing the on-shell prediction with a mixed-scheme calculation done at the same perturbative order.
effects decouple for heavy SUSY scales, also the uncertainty associated with unknown higher-order SUSY contributions shrinks with higher SUSY masses, while those uncertainties can be substantial for relatively light SUSY states.At the two-loop level, corrections from gluinos, stops and sbottoms give the largest effect in the MSSM.As explained above, contributions of this kind are not included in our MRSSM prediction because the Dirac nature of the gluino in the MRSSM would require a dedicated calculation of MRSSM two-loop contributions.Nevertheless, the contributions in the MSSM and MRSSM can be expected to be of similar size, and we estimate an uncertainty of at most 5 MeV for m SUSY > 1 TeV from the O(αα s ) corrections.As usual, the dependence of the MRSSM prediction on unknown values of BSM parameters is not treated as a theoretical uncertainty, but this dependence rather indicates the level of sensitivity for constraining those parameters by confronting the M W prediction in the MRSSM with the experimental result for this high-precision observable.

Numerical results
In the following, we show how the prediction for M W in the MRSSM depends on the general SUSY mass scale of the model.Then, we discuss how the different SUSY sectors affect the prediction.The SM input parameters [19] are always set as follows where for ∆α (5) had the result [78] is used.

General SUSY contributions and decoupling behaviour
We investigate the decoupling behaviour for M W by defining a general SUSY mass scale m SUSY as follows for the soft breaking parameters of eqs.(2.3) and (2.4) as well as the µ d and µ u parameter of the superpotential: (5.1) The superpotential parameters are fixed to the value of the benchmark point BMP1 given in ref. [7,77], the dimensionless couplings are set as Λ d = −1, Λ u = −1.03,λ d = 1.0 and λ u = −0.8.The ratio of the doublet vevs has been set to tan β = 3.
In figure 1 we show the dependence of M W and M h on the common SUSY mass scale m SUSY defined above.The mass splitting between fermionic and bosonic mass parameters is required to achieve a prediction for the SM-like Higgs boson mass M h close to the experimental value measured at the LHC.The MRSSM prediction for M h is shown on ) is used.The red dotted line and the shaded area show on the left the experimental central value for M W and its 1 σ uncertainty band according to eq. ( 1.3), while on the right the experimental value for the mass of the detected Higgs boson is supplemented by a band of ±3 GeV indicating a rough estimate of theoretical uncertainties from unknown higher-order corrections.All dimensionless superpotential parameters are chosen as for BMP1 of ref. [7].
the right-hand side of fig. 1.The prediction for M W in the MRSSM is compared in the left plot with the SM prediction for M W where the mass of the Higgs boson in the SM is identified with the corresponding MRSSM prediction for the mass of the SM-like Higgs boson, M SM h = M MRSSM h (m SUSY ).It can be seen that with a rising SUSY mass scale the SUSY contributions decouple, and the prediction for M W approaches the SM limit for large SUSY masses.On the other hand, for small values of m SUSY the prediction for M W shows a steep rise while the prediction for M h is significantly lowered.As one can infer from a comparison of the two curves in the left plot, the effect of shifting the value of the Higgs-boson mass in the SM-type contributions accounts only for a a small fraction of the increase in M W for small m SUSY , while the bulk of the effect is caused by generic MRSSM contributions.
The comparison of the behaviour of the prediction for M W in figure 1 with the case of the MSSM and the NMSSM (see e.g.refs.[46,47]) shows that in the MRSSM the decoupling to the SM result occurs at higher values of the SUSY mass scale, while the increase of M W for a decreasing SUSY scale is more pronounced than in the MSSM and the NMSSM.The difference between the MRSSM prediction and the SM prediction with  in particular related to the enlarged matter content in the MRSSM, where the additional degrees of freedom arise from the adjoint and the R-Higgs superfields, and to the fact that the Λ/λ superpotential parameters contribute to M W in a similar way as the top Yukawa coupling.In the considered scenario the Λ u/d couplings are of order one and have a large effect on the prediction.For low SUSY masses the triplet vev has a relevant influence on M W already at tree-level.The impact of the triplet vev becomes negligible for larger SUSY mass scales as v T goes to zero, see the discussion in section 3.1.2.
In the simplified scenario with a common mass scale m SUSY of figure 1 one can see that the range of m SUSY values yielding a prediction for M W within the 1σ band of the experimental central value does not coincide with the parameter region where the mass of the SM-like Higgs boson is close to 125 GeV.The prediction for M h in the MRSSM has a significant dependence on the parameters µ d and µ u .This can be seen in figure 2 where the same parameters as in figure 1 are used except that µ d and µ u are not scaled with m SUSY /2 as in eq. ( 5.1) but kept fixed at µ d = µ u = 400 GeV.For fixed values of µ d and µ u the MRSSM prediction for M W still approaches the SM prediction for large values of m SUSY , but the numerical difference between the two predictions remains sizeable up to even higher values of m SUSY than in figure 1.On the other hand, the fixed value of µ d = µ u = 400 GeV brings the regions of m SUSY that are preferred by the M W and M h predictions into better agreement with each other.

Impact of different MRSSM contributions
In the following we investigate how the different contributions in the MRSSM affect M W separately. First we describe the influence of the triplet vev on the prediction for M W . Then we describe how the different MRSSM sectors contribute to M W individually.Especially the extended Higgs and neutralino sectors are relevant in this context as they differ in the MRSSM from the MSSM and NMSSM and contain the effects from the Λ/λ couplings.Several of the figures shown in the following sections contain plots of both M W and M h as function of the parameters of interest.This is of interest as the Higgs boson mass in the MRSSM is very sensitive to those parameters, and as shown in figure 1 the variation of h has an impact on M W via the SM-type contributions.In order to disentangle this contribution from the genuine MRSSM effects it is convenient to also show the dependence of M h on the relevant parameters.
The fixed parameters are set either as before, when m SUSY is varied, or we use updated values for BMP1 of ref. [7] giving rise to a better agreement with the latest experimental value for M W given in (1.3).The latter parameters are (5.2)

Influence of the triplet vev
As the triplet vev affects the W boson mass already at the tree level by breaking custodial symmetry, even a small value (compared to M W ) affects the prediction at the same order as the size of the experimental uncertainty.
In figure 3 we show the interplay of v T and M W when the SUSY mass scale m SUSY is varied as in figure 1 and all λ d,u /Λ d,u are set equal to zero.One can see that in this case the v T tree level contribution is numerically large for v T > ∼ 1 GeV.The potentially large impact of v T can be clearly seen by the quadratic dependency exhibited in the figure which is in accordance with eq.(2.9).For |v T | > ∼ 3 GeV the prediction for M W grows above the experimentally allowed region.Therefore, for phenomenological reasons the parameter  region with |v T | < ∼ 3 GeV is preferred.For |v T | ≈ 3 GeV, using the parameters of eq. ( 5.2) and adjusting m T accordingly, the associated one-loop contribution (which is proportional to v 2 T ) to ∆r from eq. (3.1) is of similar size as the SM three-and four-loop contributions leading to a shift of δM It should be noted that the higher-order contributions also significantly depend on the SUSY mass spectrum.
For our numerical analysis in the following we choose the parameters of eq.(5.2) as basis.This yields as an input for our M W calculation.This setting leads to a a tree-level (one-loop) shift of δM = −0.17MeV), respectively, where again it should be noted that the higher-order contributions are significantly affected by the parameters of the SUSY mass spectrum.

Influence of the Λ couplings
The dependence of M W on the superpotential parameters Λ d and Λ u is shown in figure 4. The effects are stronger for Λ u than for Λ d because of tan β > 1.In the extreme case of Λ u = 2 a shift of more than δM = −5 MeV, while the prediction for M h is lowered by about 1 GeV.The behaviour of M W with regard to the two parameters Λ d and Λ u can be understood from their influence on the electroweak precision parameters S, T and U which contribute to M W .For this, we follow the lines of refs.[6,77].There, several limits of the contributions to S, T and U were studied The parameter has been identified as the one with the biggest impact on M W , where the contributions from the neutralino and chargino sector dominate.Up to a prefactor the definition of the T parameter corresponds to the one of ∆ρ.In general, the ∆ρ parameter depends on the fourth power of Λ leading to significant effects for magnitudes close to or above unity, as it is visible in figure 4.
It is of interest to understand the interplay of Λ d and Λ u concerning the M W prediction.In the previous works of refs.[6,77], all analytical expressions in the study of several model limits have been derived setting v d = 0, turning off all Λ d contributions.As we want to investigate these contributions we discuss a different model limit in the following.We take the gaugeless limit (g 1 = g 2 = 0) and set µ d = µ u = M D W and λ u = λ d = 0.Then, we find contributions from the electroweakino sector to the ∆ρ parameter as The relative sign between the two couplings and the fact that tan β > 1 for the scenario considered is the reason why an increase of Λ 2 d actually decreases the prediction for M W when Λ d and Λ u are of similar magnitude.The Λ u contribution dominates for most of the parameter space, and the Λ 2 d term leads to a reduction of the contribution in this case.The situation is reversed for tan β < 1.
In figure 5 we show on the left the quantity where as above M MRSSM h is the SM-like Higgs boson mass of the MRSSM.On the right the prediction for v T is depicted.We compare the scenario studied above where the magnitudes of Λ d,u are of order unity with a scenario where Λ d and Λ u are both fixed to zero.Note that it is necessary to fix the values of µ d and µ u to the ones of the benchmark point of eq.(5.2), while all other dimensionful SUSY parameter are scaled with m SUSY as specified in eq.(5.1).The parameters λ d and λ u are also set as in eq.(5.2).This setting limits the size of v T for m SUSY below 1 TeV.In both scenarios the difference in the prediction for M W between the MRSSM and the SM decreases from more than 50 MeV at m SUSY ≈ 1 TeV to below 5 MeV for m SUSY values in the multi-TeV range.Both lines show a very similar shape while the main contributions to δM W are different in the two scenarios.
In the scenario with Λ d,u of about −1 the magnitude of the triplet vev drops to below 1 GeV for m SUSY > 1 TeV as there is a partial cancellation in the numerator of eq. with a smaller rate as the cancellation in the numerator of eq.(3.15) is not perfect.As v T is small above m SUSY = 1 TeV, its tree-level contribution does not substantially impact the prediction for M W in this parameter region.Then, loop corrections from Λ d,u like eq. (5.4) are the most relevant ones.
In the scenario where Λ d,u are fixed to zero their loop contributions vanish.On the other hand, there is no significant cancellation in the numerator of eq.(3.15) for tan β 1.Then, v T drops below 1 GeV only above m SUSY = 3.5 TeV, and its tree-level contribution to M W is relevant for a larger mass range.

Higgs sector contributions
In the following, we investigate the influence of the extended Higgs sector of the MRSSM on the W boson mass.The contributions from the Higgs sector include the ones from the two MSSM-like Higgs doublets, the singlet and triplet states, which all mix with each other, as well as the two R-Higgs doublets.We vary all the relevant soft breaking masses   other hand increases the Higgs boson mass by about 14 GeV while M W drops by about 20 MeV.For both plots decoupling-like behaviour of the relevant SUSY contributions to M W can be seen which is similar to the one in figure 1.The residual slope for high SUSY masses originates purely from the Higgs mass dependence of the SM-like contributions to ∆r.
It has been noted before [6] that O(1) λ/Λ parameters have effects comparable to the ones of the top Yukawa coupling as both, the Yukawa and λ/Λ couplings, originate from similar terms of the superpotential.The squark contributions to M W stem mainly from top-Yukawa effects with a suppression factor originating from the squark masses.The Higgs sector effects on the other hand are driven by the λ/Λ parameters being of order one and are suppressed by the soft-breaking Higgs mass terms.Therefore, the similar behaviour arising from both sectors for M W and M h as shown in figure 6 is expected.The effect of the Higgs sector is quantitatively larger when varying the involved common mass parameters in a similar range as more degrees of freedom contribute in the Higgs sector even taking into account the colour factor for the squark contributions.A rising m T leads to a suppression of the triplet vev and its contribution to M W via the tadpole relation (3.15).

Neutralino contributions
Contributions of charginos and neutralinos to M W are very relevant in the MRSSM as the Λ superpotential parameters affect their mixing and lead to novel contributions.Additionally, the dimensionful parameters influence these corrections directly and indirectly, which is discussed in the following.
Figure 7 (left) shows that the effect of the mass parameter M D W is similar to the ones of the scalar soft breaking masses discussed before, i.e. the predicted value for M W decreases for rising M D W .As already noted in the discussion of figure 1   = 16 MeV for µ u .The downward shifts are mainly driven by contributions from ∆ρ Λ 0 , see eq. (5.4).For the mass range above about 600 GeV the prediction for the mass of the SM-like Higgs boson decreases for both parameters, as described above.In this parameter region the decrease in the Higgs boson mass leads to additional contributions shifting M W upwards.Those contributions from the SM-like Higgs boson partially cancel the SUSY corrections, with a net effect in the M W prediction of a less steep decrease with rising M D W and of an increase with rising µ u .

Scan over MRSSM parameters
In figure 8   mass.We have arrived at this band by scanning over several combinations, where the prediction for the mass of the SM-like Higgs boson has been required to agree with the measured value within the theoretical uncertainties.As condition for M h the mass range 122 GeV < M h < 128 GeV has been adopted.The SM prediction where the measured Higgs boson mass within the experimental uncertainties has been used as input is shown in red.The blue ellipses mark the measurements of the top quark and the W boson mass including their two-dimensional 1 σ and 2 σ experimental uncertainty regions.
It should be noted that the systematic uncertainty in relating the measured value of the OS/DR before SARAH-4.12.3 OS/DR after SARAH-4.12.3 OS result Experimental value Figure 9.Comparison of the M W prediction as a function of m SUSY (left) and Λ u (right) calculated in this work using the on-shell scheme (black line) with the result from SARAH/SPheno using the original contributions (blue dashed line) and using corrected contributions (purple dash-dotted line).As in the figures above, the red dotted line and the shaded area show the experimental central value for M W and its 1 σ uncertainty band according to eq. (1.3).All other model parameters are chosen as for BMP1 of ref. [7].For details see the discussion in the text.top quark mass to the top quark pole mass (see the discussion above) is not accounted for in figure 8.A proper inclusion of this uncertainty would widen the displayed ellipses along the m t axis.
The comparison of the MRSSM and SM predictions for M W with the experimental results for M W and m t in figure 8 shows on the one hand that MRSSM parameter regions giving rise to a large upward shift in M W as compared to the SM case are disfavoured by the measured value of M W , in accordance with the results of figures 1-7.On the other hand, figure 8 indicates a slight preference for a non-zero SUSY contribution to M W , see also the discussion for the MSSM and the NMSSM in refs.[47,48].The band of the SM prediction barely intersects with the 2 σ ellipse of the experimental results in figure 8, and a non-zero SUSY contribution giving rise to a moderate upward shift in M W is required in order to reach compatibility with the experimental result at the 1 σ level.

Comparison to other calculation methods
After the discussion of the various features of our numerical results, we now turn to a comparison of our results with predictions for M W in the MRSSM that have been obtained with other approaches.As discussed above, the calculation of M W in refs.[6][7][8] was done using the implemented mixed OS/DR calculation of SARAH/SPheno.In ref. [60] and the update of the program FlexibleSUSY, it was recently shown that SM higher-order contributions implemented in SARAH/SPheno were not correct with regard to the usage of the OS and DR top quark in the two-loop SM contribution.the implementation leads to a shift of M W of 50-100 MeV compared to the result of the original calculation for example given in refs.[6][7][8] for the MRSSM.This is not only true for the MRSSM but also for all other versions of SARAH/SPheno and also concerns the original SPheno code.In the following we show how the on-shell calculation presented here compares to the previous and corrected mixed OS/DR scheme predictions obtained with SARAH/SPheno.
In figure 9 we show the predictions for M W arising from the different calculations as function of the common SUSY mass in section 5.1 and of the superpotential parameter u of the MRSSM (right).The on-shell result obtained in this work is given as solid black line, the previous OS/DR result as dashed blue line and the corrected OS/DR result as dash-dotted purple line.The experimental result for M W is shown as red dotted line with a shaded region for the experimental 1 σ uncertainty.
It can be seen in the left plot of figure 9 that only the on-shell result presented in this work shows a proper decoupling behaviour where for large m SUSY the MRSSM prediction approaches the SM prediction in which the Higgs boson mass of the SM is identified with the mass of the SM-like Higgs boson of the MRSSM, see also figure 1.Both the previous and corrected mixed OS/DR scheme predictions obtained with SARAH/SPheno show a slope for large m SUSY such that the deviation between the MRSSM prediction and the SM prediction grows for increasing m SUSY .The correction of the contributions for the OS/DR calculation yields a large upward shift of about 100 MeV in M W that is roughly constant for the displayed range of m SUSY .As a consequence, the prediction for M W arising from the calculation in the mixed OS/DR scheme including the correction shows a large deviation from the measured value of M W for all values of m SUSY .The same feature also holds for the plot as function of Λ u shown on the right-hand side of figure 9. Also in this case the correction that was implemented in the calculation based on the mixed OS/DR scheme yields a roughly constant upward shift in M W that brings the MRSSM prediction far away from the experimental result for M W .Both the previous and corrected SARAH/SPheno predictions agree with the corresponding results from FlexibleSUSY generator shown on the right of Fig. 10 in ref. [60].Thus, the large deviation observed in the results for the MSSM and the MRSSM based on the mixed OS/DR scheme appears to be a general feature of this scheme.
In view of these findings the relatively good agreement between our on-shell result and the previous mixed OS/DR scheme prediction obtained with SARAH/SPheno before the correction (dashed blue line) for m SUSY below 2 TeV (left plot) and for the whole Λ u range (right plot) appears to be a numerical accident.This accidental agreement implies that the parameter regions that were identified in refs.[6][7][8] for predicting M W values that are compatible with the experimental result are roughly in agreement with the ones obtained from our new on-shell prediction within the estimated uncertainties.We have verified this accidental feature for the benchmark points of the MRSSM proposed in refs.[6][7][8].Further investigations to clarify the observed features of scheme prediction, which has been first proposed for the MSSM in ref. [51] and most generally been implemented in the tools SARAH/SPheno and FlexibleSUSY, would clearly be desirable.

Conclusions
We have presented the currently most accurate prediction for the mass of the W boson in the MRSSM.The result is based on the on-shell scheme, using the muon decay constant, the fine-structure constant and the Z boson pole mass as precisely measured experimental inputs.The appearance of a triplet scalar vacuum expectation value v T at lowest order in the electroweak symmetry breaking condition for the W boson mass but not in the corresponding relation for the mass of the Z boson leads to custodial symmetry breaking effects in the prediction for M W already at tree-level, while the other BSM parameters of the MRSSM enter via higher-order corrections.As described in detail, the prediction for the W boson mass needs to properly take into account the relation between the weak mixing angle and the gauge boson masses that is modified in the MRSSM in comparison to the SM and extensions of it involving only Higgs doublets and singlets.
Our prediction for the W boson mass is based on the full one-loop contributions in the MRSSM that we have supplemented by all available SM-type corrections of higher order.The implementation is based on a SPheno-4.0.3 mass spectrum generator that has been obtained by SARAH-4.12 for the MRSSM.The calculation of M W in the on-shell scheme has been carried out making use of the available analytical one-loop expressions that have been consistently combined with the high-order corrections of SM-type.For the latter a fit formula has been implemented, which accounts for the full electroweak two-loop corrections of SM-type involving numerical integrations of two-loop integrals with nonvanishing external momenta, as well as analytical results for leading QCD, electroweak and mixed corrections up to the four-loop level.For the renormalisation of the triplet scalar vacuum expectation value v T entering the prediction for M W at lowest order a DRtype prescription has been chosen, where the numerical value is determined via a two-step procedure ensuring numerical stability.
We have investigated the numerical result for the W boson mass in view of the characteristics of the parameter space of the MRSSM.We have verified in this context that in the decoupling limit where the SUSY particles are heavy the SM prediction is recovered, i.e. in this limit the MRSSM result approaches the SM prediction in which the Higgs boson mass of the SM is identified with the mass of the SM-like Higgs boson of the MRSSM.The upward shift in M W for a small SUSY mass scale tends to be more pronounced in the MRSSM than it is the case in the MSSM and the NMSSM, while the decoupling to the SM result occurs at higher values of the SUSY mass scale than in those models.
The most relevant SUSY parameters of the MRSSM influencing the prediction for M W are the triplet vacuum expectation value and the Λ superpotential couplings.The triplet vacuum expectation value is related to all other model parameters through its contribution to the electroweak symmetry breaking conditions and gives rise to a lowest-order shift in the ρ parameter.Since the Λ parameters are trilinear couplings of the superpotential, they enter in a similar way as the couplings, see also the discussion [6].We have identified leading contributions to the prediction for M W that enter with the fourth power of Λ u and Λ d .Additionally, the Λ couplings have an important impact via the contributions of the neutralino and chargino sector to M W .The contributions to M W of the extended Higgs sector of the MRSSM with a common Higgs sector mass show a qualitatively similar behaviour as the ones of the squark sector with a common squark mass.Confronting the results of a parameter scan in the MRSSM as well as the SM prediction for M W as a function of m t with the experimental results for the W boson mass and the top quark mass, we have demonstrated a slight preference for a non-zero SUSY contribution to M W .While this preference is similar to the results that were found in the MSSM and the NMSSM, it should be noted that there is no direct limit from the MRSSM to the MSSM.This is caused in particular by the fact that the Λ couplings are a specific feature of the MRSSM and by the pure Dirac nature of gauginos and Higgsinos in the MRSSM.While certain contributions are similar in the two models, in particular the MSSM-like contributions from stops and sbottoms which are driven by the top Yukawa coupling, the absence of trilinear A-terms in the MRSSM also gives rise to differences in the squark sector.
We have compared our results for M W to the ones that were obtained in the MRSSM from the mixed OS/DR implementation of SARAH/SPheno before [6][7][8] and after the correction that was pointed out in ref. [60] was carried out.While as described above our result shows a proper decoupling behaviour where for large values of a common SUSY mass scale in the MRSSM the SM prediction is recovered, this is not the case for either of the previous results.Those predictions show a deviation from the SM result that actually grows with increasing m SUSY .While the result of the mixed OS/DR implementation of SARAH/SPheno before the correction was applied agrees relatively well with our result in some parts of the parameter space, a feature that is apparently caused by a numerical coincidence, the mixed OS/DR implementation of SARAH/SPheno including the correction shows a large upward shift in M W of about 100 MeV compared to the previous result that gives rise to a large deviation from the measured value of M W .Because of the described accidental numerical agreement our analysis roughly confirms the preferred MRSSM parameter regions that were identified from the investigation of the M W prediction in refs.[6,7].As we have demonstrated, the large deviations of the result of the mixed OS/DR implementation of SARAH/SPheno including the correction both with respect to our result and with respect to the experimental value of M W should motivate further work in this direction.

Figure 1 .
Figure 1.Comparison of the M W (M h ) prediction as blue full line on the left (right) depending on a common SUSY mass scale m SUSY (definition given in the text).The green dashed line on the left shows the prediction of the SM calculation for M W if M SM

h
(m SUSY ) still amounts to about 10 MeV for m SUSY values of about 3 TeV in figure1, and the difference reduces to values below 1 MeV only for m SUSY > ∼ 5 TeV.The different behaviour in the MRSSM as compared to the MSSM and the NMSSM[46,47] is m SUSY[GeV]

Figure 3 .
Figure 3. Dependence of M W on v T obtained from varying the common SUSY mass scale as in figure 1.

Figure 4 .
Figure 4. Dependence of M W and M h on Λ d and Λ u .The value for v T is fixed according to eq. (5.3), and the other model parameters are chosen as in eq.(5.2).The red bands mark the experimental (theoretical) uncertainty region for M W (M SM-like h is possible compared to the minimal value at Λ u = −0.5.In the phenomenologically interesting region where the MRSSM Higgs boson mass prediction is around the experimental observation of about 125 GeV with Λ u = −1.1 the shift in M W compared to Λ u = 0 is δM (Λu) W ≈ 10 MeV.The actual effect from the Λ u variation on M W for large |Λ u | is even stronger than the variation displayed in figure 4 since large |Λ u | also drives the SM Higgs mass prediction to values far above the experimental observation, as shown in the lower left plot of figure 4, which gives rise to a downward shift from the SM-type part of the contributions to M W .As shown on the right-hand side of figure 4, an enhancement of the magnitude of Λ d from zero to unity leads to a reduction of δM (Λ d ) W

Figure 5 .
Figure 5.The plot on the left depicts the shift in the prediction of M W with respect to the SM prediction according to eq. (5.5).On the right the corresponding value of v T is plotted.Two different scenarios are considered where the parameters Λ d,u are fixed to either the values Λ d = −1, Λ u = −1.03or to zero, while µ d = µ u = 500 GeV, and the values of all other mass parameters are given in eq.(5.1).
d as well as the MSSM-like CP-odd Higgs mass parameter m 2 A = 2B µ / sin 2β simultaneously to show the dependence of the W boson mass on them.On the left side of figure 6 the dependences of M W and M h on these parameters are shown.As a comparison we show the dependence on the squark masses on the right, here all the soft-breaking squark mass parameters are varied simultaneously.Altogether, varying the common Higgs sector mass from 500 GeV to 4 TeV leads to an increase of the Higgs boson mass by almost 30 GeV and a simultaneous decrease of M W by about 30 MeV.The variation of the common squark mass from 500 GeV to 4 TeV on the

Figure 6 .
Figure 6.Dependence of M W and M h on a common Higgs sector mass (left) and a common squark mass (right).The other parameters are chosen as in figure 4.

Figure 7 . 13 =
Figure 7. Dependence of M W and M h on M D W (left) and µ u (right).The other parameters are chosen as in figure 4.

Figure 8 .
Figure 8. Prediction for the W boson mass in the MRSSM and the SM versus the input value of the top quark pole mass in comparison with the experimental results for M W , see eq. (1.3), and m t , see eq. (1.5).The green band of MRSSM arises from the scan over MRSSM parameters specified in eq.(5.6),where the condition 122 GeV < M h < 128 GeV has been applied for the prediction of the SM-like Higgs mass.The narrow red band, which is shown on top of the green band, the SM prediction where the experimental measurement is used as input for the Higgs boson mass.For the experimental measurements of M W and m t the two-dimensional allowed at the 1 σ and the 2 σ level are indicated.
and figure2, the parameter µ u we show the predictions for M W in the MRSSM resulting from a scan over MRSSM parameters as a green band in relation to the input value for the top quark pole