The development of p-type transparent semiconductors with large optical bandgaps and high electrical conductivity is needed for a wide range of applications in optoelectronics and solar cell technologies. The experimental techniques currently used are limited to complex procedures and time consuming processing. In this work, we propose a versatile, simple and reproducible method of rapid reactive dip-coating using a mesoporous network of highly aligned γ-alumina nanofibers for synthesis of delafossite CuAlO2 by a time-effective process of 2 h duration. The rhombohedral CuAlO2 was densified with the help of spark plasma sintering in vacuum. Electrical conductivity improves with increase in annealing temperature while its room temperature value for a sample annealed at 1100 °C was 0.07 S m−1 measured with four-probe method. Direct optical bandgap of 3.79 eV was estimated with the help of diffuse reflection data for the sample sintered at optimal temperature. Both Seebeck coefficient and Hall measurements confirmed the p-type conductivity of the material. Novelty: The major number of CuAlO2 synthesis approaches require complex instrumentation, templating, and long processing time. Therefore, scalable and cost-effective production of CuAlO2 remains a challenge. Herein, we report a rapid synthesis of CuAlO2, in a straightforward and scalable approach, which reduces the processing cost and overal energy consumption of the process.