We propose ZnO as an attractive interfacial layer (IL) option for n-type metal-IL-semiconductor (MIS) contacts because of (i) good conduction band alignment between ZnO and Si/Ge/SiC, (ii) high n-type doping possible in ZnO, and, (iii) low Fermi-level pinning factor for metal/ZnO contacts. Device simulations suggest better scalability for MIS contacts versus silicides/germanides for future FinFET technologies. Contact diode measurements on Ti/n<sup>+</sup>-ZnO/n-Ge and Ti/n<sup>+</sup>-ZnO/n-Si devices show nearly 1000X increase in current densities due to the presence of an n<sup>+</sup>-ZnO IL. In comparison to alternate IL options such as Al<sub>2</sub>O<sub>3</sub> and TiO<sub>2</sub>, n<sup>+</sup>-ZnO gives significantly higher current densities on n-Ge as demonstrated through device simulations and experimental data. Specific contact resistivity of (0.8-1.5) × 10<sup>-6</sup> Ω cm<sup>2</sup> is demonstrated through four-probe measurements on circular TLM devices fabricated on n<sup>+</sup>-Ge (1 × 10<sup>19</sup> cm<sup>-3</sup>) epi layers using n<sup>+</sup>-ZnO IL.