The dynamic surface behavior of surfactant in polymer solution is essential information to understand the formation and stability of Colloidal Gas Aphrons (CGAs). Measurements of dynamic surface tension, volume and half-life time of CGAs as well as size distribution of bubbles have been performed in this work. Three different surfactants of anionic sodium dodecyl sulfate (SDS), nonionic Triton X-100 (4-(1,1,3,3-tetramethylbutyl)phenyl-polyethylene glycol) and zwitterionic cocamidopropyl betaine (CAPB) were used for producing the CGAs in presence of the polymer Xanthan Gum (XG) as stabilizer. In addition, the influence of stirring time and speed as well as polymer and surfactant concentrations were investigated with respect to CGA volume and half-life time. The results showed an approximately linear relationship between half-life time and volume of CGAs for different stirring times and speeds. This reveals that at fixed polymer and surfactant concentrations, the half-life time mostly depends on the CGA volume. The XG concentration has also a strong influence on CGAs formation and stability. The increase in XG concentration reduces the CGA volume but significantly increases the half-life time. The dynamic surface tension of the applied surfactant has a major influence on CGA formation as only surfactants of a certain type and at a respective concentration provides the conditions for proper CGA formation. However, the stability of CGAs is rather complex and can be affected by the electrostatic nature of the surfactant and possible interactions with other compounds. Ionic SDS and CAPB surfactants allow producing CGAs of significant stabilities in contrast to the poor stability of CGAs made by the nonionic Triton X-100. The increase of the surfactant concentration increases the CGA volume as well as the half-life time, even at concentrations above the CMC. However, for the determination of optimum surfactant concentrations, economic issues should also be considered.