The conversion of carbon dioxide to long-chain hydrocarbons is potentially crucial to the production of renewable fuels. Now, two separate research groups in China have developed multifunctional catalysts that can convert CO 2 and hydrogen to gasoline, which comprises hydrocarbons with chain lengths between five and 11 carbon atoms.

Various processes can convert CO 2 to hydrocarbons, but they usually produce volatile single-carbon hydrocarbons such as methane and methanol. Building carbon–carbon bonds to produce longer chain, liquid hydrocarbons is a significant challenge. Recently, however, researchers have shown that zeolites can catalyse the conversion of methanol to gasoline at high temperatures.

One group at Shanghai Advanced Research Institute in China produced a bifunctional catalyst combining pellets of partially-reduced indium oxide, which converts CO 2 and hydrogen to methanol, in a mixed bed with pellets of H-form Zeolite Socony Mobil-5 (HZSM-5) to convert the methanol to long-chain hydrocarbons.1 The catalyst currently favoured in industry for methanol production from CO 2 and hydrogen is a mixture of copper and zinc oxides supported on alumina, and the researchers tried combining this and other catalysts with the zeolite. However, the other catalysts caused the production of large quantities of carbon monoxide via the reverse water-gas shift reaction; this competed with methanol production and, at the high temperatures necessary for the zeolite to convert methanol to gasoline, the selectivity for carbon monoxide reached 97%. Indium oxide, however, catalyses the reverse water-gas shift reaction less effectively, resulting in more methanol, which can then be converted to long-chain hydrocarbons by the zeolite.

In contrast, researchers at Dalian Institute for Chemical Physics combined HZSM-5 zeolite with partially-reduced magnetite, which strongly promotes the reverse water-gas shift, producing more carbon monoxide. When the magnetite is exposed to the reaction atmosphere, some of the Fe 3 O 4 sites are converted to Fe 5 C 2 sites, which catalyse the Fischer-Tropsch synthesis – converting the carbon monoxide to α-olefins. Like methanol, these react to form long-chain hydrocarbons in the presence of HZSM-5 zeolite.2

The Shanghai researchers achieved conversion of 13% of CO 2 to hydrocarbons, whereas the Dalian group achieved 22% conversion. Both groups found that around 78% of the hydrocarbons produced contained at least five carbon atoms. The reactions presented here are exothermic: the energy needed to reduce the CO 2 comes from the hydrogen. ‘One way to do this,’ explains Shenggang Li of the Shanghai team, ‘would be to use, for example, solar energy to obtain electricity, and then to use the electricity to obtain hydrogen.’