Shunxiang Xia scite author profile

Oil produced by the pyrolysis of biomass and co-pyrolysis of biomass with waste synthetic polymers has significant potential as a substitute for fossil fuels. However, the relatively poor properties found in pyrolysis oil—such as high oxygen content, low caloric value, and physicochemical instability—hampers its practical utilization as a commercial petroleum fuel replacement or additive. This review focuses on pyrolysis catalyst design, impact of using real waste feedstocks, catalyst deactivation and regeneration, and optimization of product distributions to support the production of high value-added products. Co-pyrolysis of two or more feedstock materials is shown to increase oil yield, caloric value, and aromatic hydrocarbon content. In addition, the co-pyrolysis of biomass and polymer waste can contribute to a reduction in production costs, expand waste disposal options, and reduce environmental impacts. Several promising options for catalytic pyrolysis to become industrially viable are also discussed.

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Application of Polysaccharide Biopolymer in Petroleum Recovery

Xia

Zhang²,

Davletshin

et al. 2020

Polymers

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Polysaccharide biopolymers are biomacromolecules derived from renewable resources with versatile functions including thickening, crosslinking, adsorption, etc. Possessing high efficiency and low cost, they have brought wide applications in all phases of petroleum recovery, from well drilling to wastewater treatment. The biopolymers are generally utilized as additives of fluids or plugging agents, to correct the fluid properties that affect the performance and cost of petroleum recovery. This review focuses on both the characteristics of biopolymers and their utilization in the petroleum recovery process. Research on the synthesis and characterization of polymers, as well as controlling their structures through modification, aims to develop novel recipes of biopolymer treatment with new application realms. The influences of biopolymer in many petroleum recovery cases were also evaluated to permit establishing the correlations between their physicochemical properties and performances. As their performance is heavily affected by the local environment, screening and testing polymers under controlled conditions is the necessary step to guarantee the efficiency and safety of biopolymer treatments.

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Stabilized glycerol dehydrogenase for the conversion of glycerol to dihydroxyacetone

Kumar

Wee

Lee

et al. 2015

Chemical Engineering Journal

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Electro-deposition for asphaltene removal during heavy oil upgrading

2019

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Shunxiang Xia

Catalytic Pyrolysis of Biomass and Polymer Wastes

Application of Polysaccharide Biopolymer in Petroleum Recovery

Stabilized glycerol dehydrogenase for the conversion of glycerol to dihydroxyacetone

Electro-deposition for asphaltene removal during heavy oil upgrading

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