This study utilizes atomic layer deposition (ALD) to develop Hf:ZnO films for use as transparent conductive electrodes of flexible electronics. The conductivity of the ALD Hf:ZnO film was found to be limited by the layer-by-layer nature of the HfO2 and ZnO constituents, which prevented some HfO2 molecules in the HfO2 layers from applying their full doping effects, resulting in redundant HfO2 molecules that contributed little carriers while hindering conduction of carriers across the ZnO layers. To overcome this issue, we developed a novel ALD process to change the layer-by-layer HfO2/ZnO structure to a more homogeneous mixture, and as a result we improved the resistivity of the ALD Hf:ZnO film from 2.0 E-03 to 8.5 E-04 Ω-cm. Using the novel ALD process, which involved exposing the substrate consecutively with the two organometallic precursors within the same ALD cycle, high doping concentration could be obtained with low HfO2 content; meanwhile, with low HfO2 content, the carrier mobility of ZnO could be better preserved in the Hf:ZnO film. The homogeneity of the Hf:ZnO film deposited with the novel process was confirmed with TEM and energy-dispersive X-ray spectroscopy (EDX). In terms of optical transparency, the ALD Hf:ZnO film showed >85% transmittance throughout the visible wavelengths, exceeding that of the widely used indium tin oxide (ITO). With its low deposition temperature (150 ºC), the novel ALD process was applicable to polymer substrates, and the resulted Hf:ZnO films largely retained the conductivity of those deposited on glass substrates. Additionally, the ALD Hf:ZnO film was found to be effective gas-diffusion barriers for the polymer substrates： Its helium transmission rate was lower than sputtered films by more than 1 orders of magnitude. With its high conductivity, high optical transparency, low deposition temperature, and low gas permeability, the ALD Hf:ZnO film developed in this study will offer many advantages for flexible electronics applications.