The Oil and Gas Industry is implementing fiber optic sensors, in order to optimize their production by monitoring oilfield in various applications. However, there is a challenge in the implementation of fiber optic sensors in places with presence of compounds such as hydrogen sulphide (H2S). Such a substance in contact with moisture can cause chemical reactions that result in the formation of hydrogen (H2), whicht spread in to optical fibers, may affect the transmission capacity of the optical signal due to interaction of this compound with the atomic structure of silica. In order to understand such effects, this dissertation studied the impacts of hydrogen diffusion in four fiber optics. This study was conducted using two experimental methods: An evaluation of performance of distributed temperature sensors (DTS) and analysis of the profiles of attenuation of the optical signal in the infrared when the optical fibers were subjected to different conditions of temperature and hydrogen pressure. Among the studied optical fibers, the single mode special optical fiber in metal tube (FIMT) stands out because it s showed no significant attenuation and changes in its structural composition when exposed to different hydrogen pressures and various temperatures.