AbstractThe $$\mu \nu \mathrm {SSM}$$
μ
ν
SSM
is a highly predictive alternative model to the MSSM. In particular, the electroweak sector of the model can explain the longstanding discrepancy between the experimental result for the anomalous magnetic moment of the muon, $$(g-2)_\mu $$
(
g
-
2
)
μ
, and its Standard Model prediction, while being in agreement with all other theoretical and experimental constraints. The recently published MUON G-2 result is within $${0.8}\,\sigma $$
0.8
σ
in agreement with the older BNL result on $$(g-2)_\mu $$
(
g
-
2
)
μ
. The combined result was announced as $$a_\mu ^{\mathrm{exp}} = (11 659 {206.1}\pm {4.1}) \times 10^{-10}$$
a
μ
exp
=
(
11659
206.1
±
4.1
)
×
10
-
10
, yielding a new deviation from the Standard Model prediction of $$\Delta a_\mu = ({25.1}\pm {5.9}) \times 10^{-10}$$
Δ
a
μ
=
(
25.1
±
5.9
)
×
10
-
10
, corresponding to $${4.2}\,\sigma $$
4.2
σ
. Using this improved bound we update the analysis in the $$\mu \nu \mathrm {SSM}$$
μ
ν
SSM
as presented in Kpatcha et al. (Eur Phys J C 81(2):154. arXiv:1912.04163 [hep-ph], 2021) and set new limits on the allowed parameters space of the electroweak sector of the model. We conclude that significant regions of the model can explain the new $$(g-2)_\mu $$
(
g
-
2
)
μ
data.
The standard model prediction of the muon anomalous magnetic moment
