The global market for Biorefinery technologies will grow from $466.6 billion in 2016 to $714.6 billion by 2021, with a compound annual growth rate (CAGR) of 8.9% for the period of 2016-2021.
This report provides:
A complete techno-economic and environmental analysis of industrial biorefineries, which have been identified as the most promising route to the creation of a domestic bio-based industry
Analyses of global market trends, with data from 2014 to 2016, and projections of compound annual growth rates (CAGRs) through 2021.
Coverage of all biomass fractionation and conversion technologies
Forecasts for biomass conversion processes and equipment to produce fuels, power, and chemicals from biomass
Identification of feedstocks, chemical products, and transportation fuels
Evaluations of the prospects for biorefineries built on different "platforms," such as the "sugar platform," based on fermentation of sugars extracted from biomass feedstocks, versus the "syngas platform," based on thermochemical conversion processes
Detailed patent analysis and a research-and-development update
Company profiles of major players in the industry.
SCOPE OF THE REPORT
The report starts with an overview that provides the background of the industry and reports on market trends. It also indicates the importance of the industry and the ways in which biorefinery technologies fit into the global economy. It also quantifies staffing and salary, professions, carriers, occupations, new product development and market penetration. It then presents the relative percentage contribution of each of the identified platforms with forecasts to 2021.
Chapter Four quantifies the demand for the physicochemical technology platform, including processes (e.g., pressing, pretreatment, milling, separation, distillation) that do not change the chemical structure of the biomass components, but perform a size reduction or a separation of feedstock components and chemical processes (e.g., hydrolysis, transesterification, hydrogenation, oxidation, pulping) in which a chemical change in the substrate occurs.
Chapter Five quantifies the demand for the biological technology platform, including industrial microbiological processes such as anaerobic digestion, anaerobic fermentation, enzymatic conversion that occur under mild operating conditions (e.g., lower temperature and pressure) using microorganisms or enzymes.
Chapter Six quantifies the demand for the thermochemical technology platform, including pyrolysis; gasification, hydrothermal upgrading and combustion, including processes in which feedstock undergoes extreme conditions (e.g., high temperature and/or pressure, with or without a catalytic means).
Chapter Seven identifies and quantifies the demand for the hybrid technology platform including biological transformation (fermentation) of biomass gasification-derived syngas to alcohols, thermochemical catalytic transformation of biochemical platform-produced sugars (and perhaps other solubilized carbon species) to hydrocarbon biofuels and thermochemical catalytic transformation of biochemical platform produced alcohols such as ethanol or butanol into hydrocarbon biofuels
Chapter Eight presents the development of advanced biorefinery technologies and process developments and includes an evaluation of major patents and company shares.
Chapter Nine describes the biorefinery technology industry structure. It considers a number of influencing factors, including macro factors that affect the global economy and the agricultural economy in particular, and industry-specific factors such as the public acceptance of biorefinery products. Consideration has also been given to the development of the industry over the period since 2013 and the forces that have led to its ongoing restructuring. It also assesses the rise of bio-based companies; outsourcing; adding value through improved formulations, drop-ins and additives; and the streamlining of product portfolios
Chapter Ten discusses the macroeconomic aspects and energy perspective and geographical diversification of the major international trends.
Chapter Eleven analyzes the future of the regulation and legislation of the biorefinery industry.
The report concludes with a chapter that contains comprehensive profiles of the relevant companies involved in biorefinery technologies, including biorefinery technology integrators that currently have assets that can be deployed to transform biomass feedstocks.
Edward Gobina is a Full U.K. Professor of Chemical and Processing Engineering with 32 years of research and teaching experience in environmental engineering, petrochemical reaction engineering and catalytic membrane-reactor technology. His scientific achievements are archived in more than 300 scientific articles and are found in more than 25 granted patents, 30 patent applications and 100 invited and guest speaker presentations, as well as contributed presentations and prestigious refereed scientific journals, newsletters, proceedings and reviews. He has been a project analyst for BCC Research since 1998 and has authored more than 26 BCC Research reports. His reports have provided the critical links in the entire chemical and energy infrastructure chain occasioned from hydrogen to advanced oil and gas exploitation, sensors and monitoring, and LNG infrastructure. Professor Gobina is a member of the European Membrane Society (EMS), the North American Membrane Society (NAMS) and the New York Academy of Sciences (NYAS). He is the current director of the Centre for Process Integration and Membrane Technology (CPIMT) within the School of Engineering at the Robert Gordon University in the U.K.