We carried out one-dimensional hybrid simulations of resonant scattering of protons and He2+ ions by ion cyclotron waves in an initially homogeneous, collisionless and magnetized plasma. The initial ion cyclotron waves have a power spectrum and propagate both outward and inward. Due to the resonant interaction with the protons and He2+ ions, the wave power will be depleted in the resonance region. Both the protons and He2+ ions can be resonantly heated in the direction perpendicular to the ambient magnetic field and leading to anisotropic velocity distributions, with the anisotropy higher for the He2+ ions than for the protons. At the same time, the anisotropies of the protons and He2+ ions are inversely correlated with the plasma β||p= 8πnpkBT||p/b02, consistent with the prediction of the quasilinear theory (QLT). We carried out one-dimensional hybrid simulations of resonant scattering of protons and He2 + ions by ion cyclotron waves in an initially homogeneous, collisionless and magnetized plasma. The initial ion cyclotron waves have a power spectrum and propagate both outward and inward. Due to the resonant interaction with the protons and He2 + ions, the wave power will be depleted in the resonance region. Both the protons and He2 + ions can be resonantly heated in the direction perpendicular to the ambient magnetic field and leading to anisotropic velocity distributions, with the anisotropy higher for the He2 + ions than for the protons. At the same time, the anisotropies of the protons and He2 + ions are inversely correlated with the plasma β || p = 8πnpkBT || p / b02, consistent with the prediction of the quasilinear theory (QLT) .