Abstract
In many porous catalyst supports, the accessibility of interior catalytic sites to reactant species could be restricted due to limitations of reactant transport through pores comparable to reactant dimensions. The interplay between reaction and diffusion in porous catalysts is defined through the Thiele modulus and the effectiveness factor, with diffusional restrictions leading to high Thiele moduli, reduced effectivess factors, and a reduction in the observed reaction rate. We demonstrate a method to integrate ceramic nanostraws into the interior of ordered mesoporous silica MCM-41 to mitigate diffusional restrictions. The nanostraws are the natural aluminosilicate tubular clay minerals known as halloysite. Such halloysite nanotubes (HNTs) have a lumen diameter of 15–30 nm, which is significantly larger than the 2–4 nm pores of MCM-41, thus facilitating entry and egress of larger molecules to the interior of the pellet. The method of integrating HNT nanostraws into MCM-41 is through a ship-in-a-bottle approach of synthesizing MCM-41 in the confined volume of an aerosol droplet that contains HNT nanotubes. The concept is applied to a system in which microcrystallites of Ni@ZSM-5 are incorporated into MCM-41. Using the liquid phase reduction of nitrophenol as a model reaction catalyzed by Ni@ZSM-5, we show that the insertion of HNT nanostraws into this composite leads to a 50% increase in the effectiveness factor. The process of integrating nanostraws into MCM-41 through the aerosol-assisted approach is a one-step facile method that complements traditional catalyst preparation techniques. The facile and scalable synthesis technique toward the mitigation of diffusional restrictions has implications to catalysis and separation technologies.
Highlights
The interplay between reaction and diffusion in porous catalyst particles is a fundamental and foundational concept that impacts the observed reaction rates and selectivities of a host of industrially relevant reactions
Using the liquid phase reduction of nitrophenol as a model reaction catalyzed by Ni@ZSM-5, we show that the insertion of halloysite nanotubes (HNTs) nanostraws into this composite leads to a 50% increase in the effectiveness factor
To confirm the accessibility of reactants to encapsulated Ni@ZSM-5 through pores of MCM-41 and the effect of HNTs acting as straws for improved diffusion, we tested the catalytic performance of the composite samples for the reduction of 4-nitrophenol (4-NP) to 4aminophenol (4-AP) as a model reaction.[25,27]
Summary
The interplay between reaction and diffusion in porous catalyst particles is a fundamental and foundational concept that impacts the observed reaction rates and selectivities of a host of industrially relevant reactions. There are many ways to reduce the impact of low catalyst effectiveness factors including modifying catalyst morphologies by placing the active sites near the external surface (the eggshell model), reducing the particle size, and increasing the pore size of the pellet. These approaches could be cumbersome in practice and could lead to the loss of structural integrity, increased pressure drops in packed beds, etc.
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