Altermagnets (AMs) represent a new class of magnetic materials that exhibit properties common to both antiferromagnets (AFMs) and ferromagnets (FMs). Like AFMs, AMs have zero net magnetization, while also displaying spin band splitting, a characteristic of FMs. However, unlike the global spin band splitting in FMs, AMs exhibit momentum-dependent splitting along specific crystalline directions. This unique combination of traits enables AMs to offer superior performance compared to FMs in various applications. A prominent example of an AM candidate is metallic RuO2, where the spin band splitting arises from the 90-rotated crystal fields between neighboring Ru atoms in the rutile structure. Experimental evidence supporting this includes spin-torque ferromagnetic resonance, laserinduced THz emission, and earlier neutron scattering data. However, more recent neutron and muon experiments suggest that Ru atoms do not carry a magnetic moment. In this presentation, we confirm that RuO₂ is not an altermagnet based on our latest experimental findings from laser-induced THz emission, magneto-Kerr rotation, and neutron scattering experiments.