A comprehensive review on the pyrolysis of lignocellulosic biomass

Bioenergy derived from biomass provides a promising energy alternative and can reduce the greenhouse gas (GHG) emissions generated from fossil fuels. Biomass-based thermochemical conversion technologies have been acknowledged as apt options to convert bioresources into bioenergy; this bioenergy includes electricity, heat, and fuels/chemicals in solid, liquid, and gaseous phases. In this review, the techno-economic and life cycle assessment of these technologies (combustion, gasification, pyrolysis, liquefaction, carbonization, and co-firing) are summarized. Specific indicators (production costs in a techno-economic analysis, functional units and environmental impacts in a life cycle analysis) for different technologies were compared. Finally, gaps in research and future trends in biomass thermochemical conversion were identified. This review could be used to guide future research related to economic and environmental benefits of bioenergy.

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Techno-economic and life cycle assessment on lignocellulosic biomass thermochemical conversion technologies: a review.

Progress in biomass torrefaction: Principles, applications and challenges

Pretreatment of lignocellulose has received considerable research globally due to its influence on the technical, economic and environmental sustainability of cellulosic ethanol production. Some of the most promising pretreatment methods require the application of chemicals such as acids, alkali, salts, oxidants, and solvents. Thus, advances in research have enabled the development and integration of chemical-based pretreatment into proprietary ethanol production technologies in several pilot and demonstration plants globally, with potential to scale-up to commercial levels. This paper reviews known and emerging chemical pretreatment methods, highlighting recent findings and process innovations developed to offset inherent challenges via a range of interventions, notably, the combination of chemical pretreatment with other methods to improve carbohydrate preservation, reduce formation of degradation products, achieve high sugar yields at mild reaction conditions, reduce solvent loads and enzyme dose, reduce waste generation, and improve recovery of biomass components in pure forms. The use of chemicals such as ionic liquids, NMMO, and sulphite are promising once challenges in solvent recovery are overcome. For developing countries, alkali-based methods are relatively easy to deploy in decentralized, low-tech systems owing to advantages such as the requirement of simple reactors and the ease of operation.

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Chemical Pretreatment Methods for the Production of Cellulosic Ethanol: Technologies and Innovations

http://spiral.imperial.ac.uk/bitstream/10044/1/65770/2/Manuscript.pdf

The multi-scale challenges of biomass fast pyrolysis and bio-oil upgrading: Review of the state of art and future research directions

Life cycle assessment of electricity generation using fast pyrolysis bio-oil

Effect of biomass type, heating rate, and sample size on microwave-enhanced fast pyrolysis product yields and qualities

Discrete element modeling of deformable pinewood chips in cyclic loading test

Biomass is a renewable and sustainable energy resource. Current design of biomass handling and feeding equipment leverage both experiments and numerical modeling. This paper reviews the state-of-th...

Jordan Klinger

Papers

Life cycle assessment of electricity generation using fast pyrolysis bio-oil

Effect of biomass type, heating rate, and sample size on microwave-enhanced fast pyrolysis product yields and qualities

Discrete element modeling of deformable pinewood chips in cyclic loading test

A Review of Computational Models for the Flow of Milled Biomass Part I: Discrete-Particle Models

Kinetic study of aspen during torrefaction