Abstract
Bioethanol is one of the most promising renewable resources for the production of important monomers. To date, there have been various processes proposed for bioethanol conversion to renewable monomers. In this review, the catalytic bioethanol upgrading to various types of monomers using hierarchical zeolites as catalysts is illustrated, including the recent design and preparation of hierarchical zeolites for these catalytic processes. The characterizations of catalysts including textural properties, pore architectures, acidic properties, and active species are also exemplified. Moreover, the catalytic studies with various processes of monomer production from bioethanol including bioethanol dehydration, bioethanol to hydrocarbons, and bioethanol to butadiene are revealed in terms of catalytic activities and mechanistic studies. In addition, the future perspectives of these catalytic circumstances are proposed in both economic and sustainable development contexts.
Highlights
Monomers are important raw materials in polymer industries as they can react together to build polymers via polymerization processes [1]
The TPOAC and the cetyltrimethylammonium bromide (CTAB) act as mesoporogens so that the structure-directing agent (SDA) of each zeolite framework is required in the synthetic procedure, such as TPABr and tetrapropylammonium hydroxide (TPAOH) for the ZSM-5 zeolite and Tetraethylammonium hydroxide (TEAOH) for the BEA zeolite
There have been various hierarchical zeolite catalysts applied in the bioethanol upgrading to renewable monomers
Summary
Monomers are important raw materials in polymer industries as they can react together to build polymers via polymerization processes [1]. The ethylene production from bioethanol dehydration is an alternative process using the renewable resource instead of fossil resources, which can reduce greenhouse gas emission and create a more environmentally friendly process, and it has been already available in the commercial scale in some locations, for example, Brazil [16]. The conventional zeolites frequently suffer from the mass transfer limitation, leading to fast catalyst deactivation because of micropore blocking by coke species [20]. To overcome this drawback, hierarchical zeolites have been proposed. The catalytic behaviors of hierarchical zeolites in bioethanol conversion to monomers are divided into the catalytic activities and mechanistic studies in the bioethanol dehydration, bioethanol to hydrocarbons, and bioethanol to butadiene reactions
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