Class G oil well cement is frequently used a in oil well cementing operation, which is subjected to various forms of deterioration, affecting its durability. Two of these forms of deterioration is due to cyclic loading and elevated temperatures. In the present study, cylindrical specimens were subjected to cyclic loading of 30, 50 and 70 per cents of the materials ultimate strength and to temperatures of 100 Celsius degrees, 200 Celsius degrees, 450 Celsius degrees and 650 Celsius degrees for one hour. Microcomputed tomography (microCT) was used to generate threedimensional images to visualize the internal structure of the material before and after the tests, and to quantitatively assess the evolution of pore structures and cracking by a computational routine developed. First, the FIJI software was used to reduce noises of images, then the images generated before and after the tests was aligned using the DataViewer software. In the Dragonfly software the voids (pores and fissures) of the images are segmented and quantified, showing the volume and sphericity of the voids of interest.The results of the cyclic load test showed that when the specimen was submitted to 30 per cent of its ultimate strength almost no influence in the internal structure was observed.When the cyclic load was increased to 50 per cent and 70 per cent significant damage to the specimens was noticed. The results of the qualitative and quantitative analysis of the specimen submitted to 100 Celsius degrees and 200 Celsius degrees showed the appearance of small cracks, however, the pore structures did not change. In the specimen subjected to 450 Celsius degrees the appearance of several cracks was visualized. For the sample submitted to 650 Celsius degrees specimen was imposed to the material, making it impossible to visualize in the microCT. As a conclusion, the Class G Oil Well Cement Paste may be used for operations with cyclic loading up to 30 per cent of the ultimate strength with service temperatures up to 200 Celsius degrees. Finally, the dehydroxylation of Ca(OH)2 and degradation of CaCO3 led to high deterioration in this cement paste.