The electrification of remote locations that lack grid-connectivity is a global challenge. In Australia, off-grid communities and mining sites that are not connected to the electrical grid meet their electricity demand primarily through diesel generator systems. The economic and environmental ramifications associated with diesel generators can be minimised using hybrid renewable energy technologies. This study aims to identify the optimal combination of technologies in a hybrid system consisting of concentrating solar thermal (CST), solar photovoltaic (PV), battery storage and diesel generators. Optimisation is carried out through an economic analysis based on minimisation of the levelised cost of energy (LCOE). The CST system considered here utilises a supercritical CO2 power cycle, which presents increased suitability for small scales (<10 MW). The efficiencies and costs of the CST system are closely related to the turbine inlet temperature. In this work, three temperatures are explored to identify the optimal case. The results indicate that the optimal system consists of CST (650 degrees C) as the primary source of baseload power, with PV and diesel generation serving as supplementary sources. These systems present significant reductions in LCOE and emissions compared to the diesel base case, and therefore offer a promising solution for remote electricity. (C) 2019 Elsevier Ltd. All rights reserved.