The development of high-performance gas sensors is crucial for environmental monitoring, industrial safety, and medical diagnostics. Single-walled carbon nanotubes (SWCNTs) are a promising material for gas sensing due to their high surface-area-to-volume ratio, exceptional electrical properties, and sensitivity to charge transfer. While conventional SWCNT gas sensors rely on measuring changes in electrical resistance, Raman spectroscopy offers a powerful and non-destructive optical method for detecting and characterizing gas molecules. Raman spectroscopy provides unique vibrational fingerprints of materials. The characteristic Raman bands of SWCNTs, such as the radial breathing mode (RBM), D-band, and G-band, are highly sensitive to their local environment. The adsorption of gas molecules onto the SWCNT surface leads to a charge transfer interaction, which perturbs the electronic and vibrational properties of the nanotubes. This interaction results in observable changes in the Raman spectrum, including shifts in the peak positions, alterations in intensity, and the appearance of new peaks. This work investigates the changes in the Raman spectrum of SWCNT films upon exposure to various gases, such as Carbon Dioxide (CO2​). Our findings demonstrate that Raman spectroscopy, particularly when utilizing resonant excitation, offers a highly sensitive and selective method for gas detection. This approach could lead to the development of robust, real-time optical gas sensors that complement or surpass traditional electrical-based sensors, providing a new pathway for advanced gas sensing technologies.