•Heat mining form deep hot dry rock beneath the current oilfield at bongor basin, chad.•Utilizing carbon dioxide from diesel power plants into deep geothermal reservoirs for heat mining and CO2 sequestration.•Utilizing oilfield geothermal water from high water-cut oil wells into geothermal wells for heat mining.•Using infrastructures and facilities of oilfield reduces the cost of geothermal project implementation. In this paper, the feasibility of power generation from an enhanced geothermal system (EGS) located beneath an oilfield at the Bongor basin in Chad was examined through the analysis of numerical simulation parameters. A 3D geometric model is constructed to represent the proposed EGS and a thermo-hydro-mechanical (THM) coupled mathematical model was used in the simulation process to link all inter-dependent parameters of heat mining. Oilfield warm water is anticipated to be the circulating fluid of the thermal reservoir due to its ready availability from high water-cut oil wells. Chad depends heavily on a diesel power plant, thus this work further proposes the utilization of carbon dioxide (CO2) from the power plants to be used as heat mining fluid and likely CO2 sequestration into deep granite formation. The results indicate that the implementation of EGS beneath the current oilfield would have significant advantages both technically, environmentally, and economically. Oilfield produced water at warm temperatures improved heat mining efficiency and utilization of oilfield water in geothermal wells will reduce costs involved in water treatment and disposal. The geothermal gradient is sufficient to produce water at a higher temperature that can be utilized commercially by different binary power plants. Utilizing CO2 as heat extraction fluid showed significant heat extraction, higher than using oilfield produced water. Furthermore, substantial amount of CO2 can be deposited into the formation, thus reducing emission of greenhouse gasses to the atmosphere.