Direct synthesis of iso-olefins from carbon dioxide hydrogenation via tandem catalysis

The direct production of iso-olefins using carbon dioxide and hydrogen is a promising alternative to traditional petrochemical routes, but it has not been fully achieved due to the lack of suitable catalysts and processes for the conversion. Herein, we report a tandem process for the direct synthesis of C4 -C7 iso-olefins from carbon dioxide and hydrogen. The process proceeds by hydrogenation of carbon dioxide to C4 -C7 n -olefins over a potassium -doped ferroferric oxide and subsequent selective isomerization to C4 -C7 iso-olefins over a silica -alumina xerogel. A high C4 -C7 iso-olefin selectivity of 35.2% with 37.8% CO2 conversion is obtained. Experiments reveal that the presence of high -density weak Lewis acid sites and the absence of Bronsted acid sites in the silica -aluminum xerogel can inhibit the cracking and hydrogenation of olefin intermediates during isomerization reaction under a hydrogen -rich atmosphere, resulting in the selective formation of C4 -C7 iso-olefins with a 6.9 iso-/n-olefin ratio.