Environmental CO2 concentration has reached a very high level of 414.83 ppm recently (1) due to human activities like burning of fossil fuels, deforestation, and large-scale industrial manufacturing. Methanol is a key synthetic chemical and a viable source for renewable energy storage at a large scale. (2) Synthesis of methanol using syngas (CO/H2) and heterogeneous catalysts is a well-developed process; (3) however, direct conversion of CO2 to methanol, another viable alternative to reduce greenhouse gas emissions, has gained significant attention lately.

Although different types of catalysts (4,5) and reactors have been reported in the literature for CO2 hydrogenation, such as slurry reactors, (6) fluidized bed reactors (7) and membrane reactors, (8) Cu/ZnO/Al2O3 pellet-based catalysts are the most widely used commercial catalyst in a packed bed reactor for direct CO2 hydrogenation into methanol. (9) Typical reactors have three types of resistances, namely, kinetic resistance, external mass transfer resistance, and internal mass transfer resistance. (10−12) Nevertheless, overcoming internal and external mass transfer resistances has always been a challenge in packed bed reactors. Gas channeling, boundary layer formation, and internal diffusion are a few of the many factors that affect reactor performance and are driven by these resistances. (13) To improve the reactor performance, an effective reactor design is needed that minimizes these resistances to help maximize the reactant conversion, product yield, and selectivity.

Monolith catalytic reactors have been widely used in various applications such as vehicular and stationary engine exhaust aftertreatment, chemical and fuel processing, and catalytic oxidation of volatile organic compounds. (14) Monolithic reactors offer uniform catalyst coating and efficient material usage and can accommodate lower particle size without incurring high pressure drops, unlike pellet-based packed bed reactors. Fan and Tahir (15) and Liang et al. (16) have discussed the benefits of using monolithic catalysts and reactors. Du et al. (17) have specifically showed the use of a ZnO nanorod array grown on cordierite monoliths as a support for Cu–ZnO–Al2O3-based CO2 hydrogenation catalyst. Meanwhile, Durán Martínez et al. (18) as well as Lu et al. (12) have used modeling and simulation-based approaches to show the mass transfer benefits of monolithic reactors. As of late, effective use of monolithic reactors has recently drawn attention for CO2 hydrogenation processes, (16,17) but in-depth studies are rather limited pertaining to mass transfer resistances on the process and reaction kinetics, to say the least.

Herein, a three-dimensional (3D) monolithic reactor model was demonstrated for direct CO2 hydrogenation. Parametric fitting models were successfully developed to fit experimental data to the kinetic models...

Figure 1. Schematics of (A) a monolithic channel reactor, (B) external diffusion through the individual channel, and (C) internal diffusion in the catalyst layer on the channel surface.

Figure 2. Block flow diagram depicting the steps involved in the parametric optimization in this article, from catalyst preparation and testing to obtaining the required optimized reactor design variables.

Figure 6. (A) Square channel depicting Sherwood number profile at multiple planes along the length of the channel; Sherwood number profiles for channel midpoint planes at 300 °C: (B) square, (C) triangle, (D) pentagon, (E) hexagon, (F) circular [Sherwood number scale: 0–9].

Figure 8. (A) Effect of space velocity on methanol concentration for constant reactor volume case at 300 °C. (B) Single channel cross sections depicting the change in methanol concentration profiles between reactor inlet and outlet over the length of the channel [1 cm] at volumetric flow rates ranging from 10 to 120 sccm for constant reactor volume case. (C) Effect of flow rate on methanol concentration for variable and constant space velocity [SV = 25000 h–1] at 300 °C.