In this paper, holmium-doped zinc oxide (Ho:ZnO) thin films are grown by pulsed-laser deposition on c-oriented sapphire substrates with Ho concentration ranging from 0 to 10 atomic percent. During deposition, the oxygen partial pressure is 3×10-1 mbar, the substrate temperature is 525 °C, the laser wavelength and energy fluence are 266 nm and 2.0 J/cm2, respectively. The structural, luminescent, magnetic, and magneto-optical properties as well as electrical resistivity were investigated. X-ray diffraction and Raman scattering spectra show Ho incorporation into ZnO without any secondary phase. The c lattice constant and grain size becomes smaller as Ho dopant concentration increases, which is attributed to defect formation during growth. Moreover, luminescence of Ho 4f 5S2→5I8 and 5F4→5I8 transition are also observed for thin films of 5 and 8 at. % of Ho doping in Raman scattering spectra. In Photoluminescence (PL) spectra, ZnO shows strong near-band-edge (NBE) emission at both T = 5 K and T = 300 K. As Ho content increases, NBE peaks becomes weaker which defect emission peaks becomes stronger. Oxygen vacancy, zinc vacancy and zinc interstitial are identified from PL spectra of Ho-doped thin films. Magnetization loops measured by superconducting quantum interference device at T = 5 and 300 K reveal only paramagnetism from all Ho:ZnO thin films. Other than strong oxygen desorption characteristic between 40 and 60 K, temperature dependence of magnetization of Ho:ZnO thin films also not show any magnetic ordering. Magneto-optical Faraday effect at room temperature exhibit paramagnetic behavior for all Ho:ZnO thin films for wavelength between 380 and 700 nm. Verdet constant of Ho:ZnO thin films decrease with increasing wavelength. III Current-voltage curves show that all electrode on Ho:ZnO thin films are ohmic contact. The resistivity does not change with current, but increases after Ho cncoporation. This increase in resistivity is attributed to defects in Ho:ZnO thin films.