Abstract Carbon dioxide capture and storage (CCS) is gaining widespread interest as a potential method to control greenhouse gas emissions from combustion processes of fossil fuels, especially in electric power plants. Retrofitting existing power plants with post-combustion CO 2 capture technologies, the most mature options today, has been suggested as a possible mean to reduce CO 2 emissions. After adding a carbon capture unit, both electricity and steam are required by the capture system, essentially forcing the power plant to operate in cogeneration. Instead of derating the base plant for post-combustion capture energy needs, steam could be generated in an external auxiliary unit designed specifically for the capture island. Since this auxiliary plant would be a new build, the plant could be designed for the particular heat load of the capture section in order to minimize efficiency losses and increase the energy saving. This paper examines the energy behavior of combined cycle power plants with CO 2 post-combustion capture, assuming that the reboiler duty is satisfied by steam extracted upstream the low pressure turbine or by an auxiliary biomass boiler. These options are also compared in terms of cost of electricity (COE) and capture cost per tonne of CO 2 avoided. The platform used to simulate the power plant is the commercially available software GateCycle; the CO 2 capture process is simulated using ChemCad software and assuming 90% CO 2 capture ratio with monoethanolamine (MEA 30 wt%) as absorbent.