The world energy demand is growing steadily as is the emission of greenhouse gases. The efforts to enhance energy consumption can escalate greenhouse pollution yet the technologies used to implement zero-emission processes have been inefficient. It has long been considered that the solution for both might be one and the same. The scope of this paper is to discuss an integrated power cycle that employs two power sources, namely solar power and the s-CO₂ oxy-combustion cycle. This integrated power conversion system provides zero CO₂ emissions, using renewable energy in the form of concentrated solar power at one end and oxy-combustion of natural gas with carbon capture technology at the other end. The power cycle is different from conventional power cycles in the respect that it uses both renewable and non-renewable energy sources to lessen the latter’s consumption. Consequently, this enables the integrated system to avoid CO₂ emissions into the environment while responding to energy depletions at the same time. The analysis will include the efficiency of the integrated system and the resulting reduction in fuel consumption based on their thermodynamic analysis. The results will be analyzed to determine whether the proposed power cycle integrating solar power is compatible from the thermodynamic point of view.