Valorization of CO2 into light olefins by thermal-catalytic hydrogenation

Doktorsavhandling, 2024

Ending the dependence on fossil resources and reducing greenhouse gas emissions are the main trends in energy technology development. In recent years, with the large-scale application of renewable resources and the popularization of water electrolysis technologies for green hydrogen production, the catalytic valorization of CO2 and green H2 into high-value-added light olefins (ethylene, propene, and butene) is ushering in major opportunities. CO2 will no longer be treated as a waste but will be an important carbon resource for producing chemicals and fuels in the future. In this thesis, two main catalytic technologies for hydrogenation of CO2 to light olefins were studied: (i) Methanol intermediate pathway using the tandem catalysts containing CO2 to methanol (CTM) and methanol to olefins (MTO) catalyst components. (ii) CO intermediate pathway using iron-based Fischer-Tropsch synthesis (FTS) catalysts. These studies are intended to lay a technical and theoretical foundation for the future development of stable industrial catalysts.

One major goal was to develop a tandem catalyst with high stability and minimal CO selectivity. Firstly, two series of single In2O3 and binary In2O3-ZrO2 catalysts were synthesized by combustion, urea hydrolysis, and precipitation methods with different precipitants. The physicochemical properties were characterized and correlated with CTM reaction performance. The results indicated that the synthesis methods significantly influence the catalysts’ specific surface area, crystal structure, and catalytic performance. Moreover, the In2O3-ZrO2 catalysts exhibited superior performance compared to the In2O3 counterparts. Secondly, two types of SSZ-13 zeolites with similar bulk composition, but different framework Al distribution (isolated and paired Al in framework) were synthesized as MTO components in tandem catalysts. Their performance was investigated at a low temperature of CO2 hydrogenation, and the main acid properties (acid density and distribution) influencing selectivity for olefins and coke formation were explored. The results revealed that the Brønsted acid density of zeolites is the primary factor affecting product selectivity and coke formation. Thirdly, over an optimized tandem catalyst with a low acidity SSZ-13 zeolite component and a stable In2O3 component, a transient experiment with varying reaction conditions was carried out to investigate the formation and degradation of trapped coke during CO2 hydrogenation. A dynamic balance mechanism between the formation and degradation of coke was identified, and a pre-coking method was proposed to enhance catalyst selectivity and stability. This mechanism was validated through a 100-hour stability test, confirming that pre-coking improved the performance of SSZ-13 within the In2O3/SSZ-13 tandem catalyst.

To develop a stable iron-based catalyst that can effectively convert CO and CO2 into light olefins, nano-Fe5C2 and nano-Fe3O4 materials, with and without sodium additives, were first synthesized as model catalysts. Their catalytic activities were tested, and the iron phase transitions which closely influence product selectivity and stability were studied under both reaction and regeneration conditions. The results showed that the interface between Na2CO3 and Fe5C2 was the active center for olefins production. However, the Fe5C2 component was prone to oxidation to Fe3O4, especially when mixed with Na2CO3, which reduced selectivity for methane and increased CO selectivity in CO2 hydrogenation. Reducing the gas hourly space velocity (GHSV) lowered CO selectivity and maintained high olefin selectivity, however it also accelerated the oxidation of the Na2CO3-modified nano-Fe5C2 catalyst. Additionally, a series of pure Fe, Fe-Zn, Fe-Mn, and Fe-Zn-Mn spinel-derived catalysts were prepared using a solvothermal method. Their activity and stability were investigated through accelerated deactivation experiments. The results revealed that strong interactions between Fe and Zn or Mn in the lattice changed the reduction, carburization, and oxidation rates of iron species, leading to the formation of dynamic active centers with prolonged catalytic stability during CO2 hydrogenation.