We investigate a method for determining the CP nature of a neutral Higgs boson or spin-zero resonance Φ at a future linear e + e − collider (ILC) in its Φ → τ − τ + decay channel. Our procedure is applicable if the production vertex of the Higgs boson can be measured. This will be the case, for example, for the Higgs-strahlung process e + e − → Z + Φ. We show that the method is feasible for both the leptonic and the hadronic 1-prong tau decay modes, τ Recently, the ATLAS and CMS experiments reported the discovery of a neutral boson of mass ∼ 126 GeV at the LHC [1,2]. The experimental findings disfavor the option of a spin J = 1 resonance. The experimental results [1,2] are compatible with the hypothesis of identifying this resonance with the Standard Model (SM) Higgs boson; however, much more detailed investigations will be necessary to establish this conjecture. The investigations of the properties of this resonance will probably be possible at the LHC to a large extent. A high-energy linear e + e − collider would be an ideal machine to investigate the properties of this resonance, i.e., its couplings, decay modes, spin, and CP parity, in great detail (and, of course, also of other, not too heavy resonances of similar type if they exist). As it is likely that the ATLAS and CMS resonance is a spin-zero (Higgs) boson, one may revert, for assessing the prospects of exploring this particle at a future linear collider, to the many existing phenomenological investigations, within the SM and many of its extensions, of Higgs-boson production and decay in e + e − collisions. As to the prospects of exploring the spin and CP properties of a Higgs boson, there have been a number of proposals and studies, including that are relevant for Higgs-boson production and decay at a linear collider. In this workshop contribution we apply a method [26,27] for the determination of the CP properties of a neutral spin-zero (Higgs) boson Φ in its τ + τ − decays to the production of Φ at a future e + e − linear collider (ILC). For definiteness, we consider e + e − → ZΦ, but the analysis outlined below is applicable to any other Φ production mode. In our analysis all major 1-prong τ decays are taken into account. We demonstrate that the CP properties of Φ can be determined with our method in an unambiguous way.
