The morphologies, stabilities, and viscosities of high-pressure carbon dioxide-in-water (C/W) foams (emulsions) formed with branched nonionic hydrocarbons surfactants were investigated by in situ optical microscopy and capillary rheology. Over two dozen hydrocarbon surfactants were shown to stabilize C/W foams with Sauter mean bubble diameters as low as 1 to 2 mu m. Coalescence of the C/W foam bubbles was rare for bubbles larger than about 0.5 mu m over a 60 h time frame, and Oswald ripening became very slow. By better blocking of the CO, and water phases with branched and double-tailed surfactants. the in tension decreases, the surface pressure increases, and the C/W foams become very stable. For branched surfactants with propylene oxide middle groups. the stabilities were markedly lower for foams and decane water emulsions. The greater stability of the C/W foams to coalescence may be attributed to a smaller capillary pressure, lower drainage rates, and a sufficient surface pressure and thus limiting surface elasticity, plus small film sizes, to hinder spatial and surface density fluctuations that lead to coalescence. Unexpectedly, the foams were stable even when the surfactant favored the CO2 phase over the water phase, in violation of Baneroft's rule. This unusual behavior is influenced by the low drainage rate, which makes Marangoni stabilization of less consequence and the strong tendency of emerging holes in the lamella to close as a result of surfactant tail flocculation in CO2. The high distribution coefficient toward CO2 versus water is of significant practical interest for mobility control in CO2 sequestration and enhanced oil recovery by foam formation.