This study evaluated the CO2 corrosion layer formation on the surface of two different steels, the API 5L X80 used for oil and gas transportation and the API 5CT used in oil production (case tubing). Techniques such as weight loss and electrochemical techniques as linear polarization resistance (LPR), Tafel curves, electrochemical impedance spectroscopy (EIS) were employed to determine the corrosion rate. Tests were conducted under static conditions in a brine 3 percent wt solution of of NaCl under CO2 partial pressure of 55 bar and total of 75 bar, immersion times of 7, 15, 21 and 30 days and temperatures of 25 Celcius, 50 Celcius and 75 Celcius. Analysis of the scale morphology was carried out by Scanning Electron Microscopy (SEM), and X-ray Diffraction. (XRD) and Energy Dispersive Spectroscopy (EDS) were used to determine the chemical composition. The layers formed were evaluated as a function of its thickness, morphology and chemical composition. It was found out that at 25 Celcius only after 30 days of immersion there was iron carbonate layer formation for both steels and at 50 Celcius and 75 Celcius there was the growth of two layers for all immersion times, being the chemical composition of these layers identifyed as iron carbonate FeCO3 as the main corrosion product for the two steels. The lowest corrosion rate and most protective layer of iron carbonate FeCO3 was for the condition at 75 Celcius and 30 days of immersion. The results obtained of LPR and EIS were similar to those obtained by mass loss showing the same tendency, reducing with time and temperature.