Biomass Modification, Characterization and Process Monitoring Analytics to Support Biofuel and Biomaterial Production

The conversion of lignocellulosic biomass into renewable fuels and other commodities has provided an appealing alternative towards supplanting global dependence on fossil fuels. The suitability of multitudes of plants for deconstruction to useful precursor molecules and products is currently being e...

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Main Authors: Blake Simmons, Jason Lupoi, Robert Henry
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語言:英语
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author Blake Simmons
Jason Lupoi
Robert Henry
author_browse Blake Simmons
Jason Lupoi
Robert Henry
author_facet Blake Simmons
Jason Lupoi
Robert Henry
author_sort Blake Simmons
collection Directory of Open Access Books
description The conversion of lignocellulosic biomass into renewable fuels and other commodities has provided an appealing alternative towards supplanting global dependence on fossil fuels. The suitability of multitudes of plants for deconstruction to useful precursor molecules and products is currently being evaluated. These studies have probed a variety of phenotypic traits, including cellulose, non-cellulosic polysaccharide, lignin, and lignin monomer composition, glucose and xylose production following enzymatic hydrolysis, and an assessment of lignin-carbohydrate and lignin-lignin linkages, to name a few. These quintessential traits can provide an assessment of biomass recalcitrance, enabling researchers to devise appropriate deconstruction strategies. Plants with high polysaccharide and lower lignin contents have been shown to breakdown to monomeric sugars more readily. Not all plants contain ideal proportions of the various cell wall constituents, however. The capabilities of biotechnology can alleviate this conundrum by tailoring the chemical composition of plants to be more favorable for conversion to sugars, fuels, etc. Increases in the total biomass yield, cellulose content, or conversion efficiency through, for example, a reduction in lignin content, are pathways being evaluated to genetically improve plants for use in manufacturing biofuels and bio-based chemicals. Although plants have been previously domesticated for food and fiber production, the collection of phenotypic traits prerequisite for biofuel production may necessitate new genetic breeding schemes. Given the plethora of potential plants available for exploration, rapid analytical methods are needed to more efficiently screen through the bulk of samples to hone in on which feedstocks contain the desired chemistry for subsequent conversion to valuable, renewable commodities. The standard methods for analyzing biomass and related intermediates and finished products are laborious, potentially toxic, and/or destructive. They may also necessitate a complex data analysis, significantly increasing the experimental time and add unwanted delays in process monitoring, where delays can incur in significant costs. Advances in thermochemical and spectroscopic techniques have enabled the screening of thousands of plants for different phenotypes, such as cell-wall cellulose, non-cellulosic polysaccharide, and lignin composition, lignin monomer composition, or monomeric sugar release. Some instrumental methods have been coupled with multivariate analysis, providing elegant chemometric predictive models enabling the accelerated identification of potential feedstocks. In addition to the use of high-throughput analytical methods for the characterization of feedstocks based on phenotypic metrics, rapid instrumental techniques have been developed for the real-time monitoring of diverse processes, such as the efficacy of a specific pretreatment strategy, or the formation of end products, such as biofuels and biomaterials. Real-time process monitoring techniques are needed for all stages of the feedstocks-to-biofuels conversion process in order to maximize efficiency and lower costs by monitoring and optimizing performance. These approaches allow researchers to adjust experimental conditions during, rather than at the conclusion, of a process, thereby decreasing overhead expenses. This Frontiers Research Topic explores options for the modification of biomass composition and the conversion of these feedstocks into to biofuels or biomaterials and the related innovations in methods for the analysis of the composition of plant biomass, and advances in assessing up- and downstream processes in real-time. Finally, a review of the computational models available for techno-economic modeling and lifecycle analysis will be presented.
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spelling doab-20.500.12854ir-422542024-04-11T15:10:49Z Biomass Modification, Characterization and Process Monitoring Analytics to Support Biofuel and Biomaterial Production Blake Simmons Jason Lupoi Robert Henry TP248.13-248.65 TA1-2040 biomass NIMS pretreatment high-throughput Proteomics transgenic Raman spectroscopy Biofuels Agave sugarcane thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TC Biochemical engineering::TCB Biotechnology The conversion of lignocellulosic biomass into renewable fuels and other commodities has provided an appealing alternative towards supplanting global dependence on fossil fuels. The suitability of multitudes of plants for deconstruction to useful precursor molecules and products is currently being evaluated. These studies have probed a variety of phenotypic traits, including cellulose, non-cellulosic polysaccharide, lignin, and lignin monomer composition, glucose and xylose production following enzymatic hydrolysis, and an assessment of lignin-carbohydrate and lignin-lignin linkages, to name a few. These quintessential traits can provide an assessment of biomass recalcitrance, enabling researchers to devise appropriate deconstruction strategies. Plants with high polysaccharide and lower lignin contents have been shown to breakdown to monomeric sugars more readily. Not all plants contain ideal proportions of the various cell wall constituents, however. The capabilities of biotechnology can alleviate this conundrum by tailoring the chemical composition of plants to be more favorable for conversion to sugars, fuels, etc. Increases in the total biomass yield, cellulose content, or conversion efficiency through, for example, a reduction in lignin content, are pathways being evaluated to genetically improve plants for use in manufacturing biofuels and bio-based chemicals. Although plants have been previously domesticated for food and fiber production, the collection of phenotypic traits prerequisite for biofuel production may necessitate new genetic breeding schemes. Given the plethora of potential plants available for exploration, rapid analytical methods are needed to more efficiently screen through the bulk of samples to hone in on which feedstocks contain the desired chemistry for subsequent conversion to valuable, renewable commodities. The standard methods for analyzing biomass and related intermediates and finished products are laborious, potentially toxic, and/or destructive. They may also necessitate a complex data analysis, significantly increasing the experimental time and add unwanted delays in process monitoring, where delays can incur in significant costs. Advances in thermochemical and spectroscopic techniques have enabled the screening of thousands of plants for different phenotypes, such as cell-wall cellulose, non-cellulosic polysaccharide, and lignin composition, lignin monomer composition, or monomeric sugar release. Some instrumental methods have been coupled with multivariate analysis, providing elegant chemometric predictive models enabling the accelerated identification of potential feedstocks. In addition to the use of high-throughput analytical methods for the characterization of feedstocks based on phenotypic metrics, rapid instrumental techniques have been developed for the real-time monitoring of diverse processes, such as the efficacy of a specific pretreatment strategy, or the formation of end products, such as biofuels and biomaterials. Real-time process monitoring techniques are needed for all stages of the feedstocks-to-biofuels conversion process in order to maximize efficiency and lower costs by monitoring and optimizing performance. These approaches allow researchers to adjust experimental conditions during, rather than at the conclusion, of a process, thereby decreasing overhead expenses. This Frontiers Research Topic explores options for the modification of biomass composition and the conversion of these feedstocks into to biofuels or biomaterials and the related innovations in methods for the analysis of the composition of plant biomass, and advances in assessing up- and downstream processes in real-time. Finally, a review of the computational models available for techno-economic modeling and lifecycle analysis will be presented. 2021-02-11T09:09:59Z 2021-02-11T09:09:59Z 2016-01-19 14:05:46 2016 book 18254 16648714 9782889198672 https://directory.doabooks.org/handle/20.500.12854/42254 eng Frontiers Research Topics image/jpeg Attribution 4.0 International http://www.frontiersin.org/books/Biomass_Modification_Characterization_and_Process_Monitoring_Analytics_to_Support_Biofuel_and_Bioma/894 http://journal.frontiersin.org/researchtopic/3591/biomass-modification-characterization-and-process-monitoring-analytics-to-support-biofuel-and-biomat Frontiers Media SA 10.3389/978-2-88919-867-2 10.3389/978-2-88919-867-2 bf5ce210-e72e-4860-ba9b-c305640ff3ae 9782889198672 156 open access
spellingShingle TP248.13-248.65
TA1-2040
biomass
NIMS
pretreatment
high-throughput
Proteomics
transgenic
Raman spectroscopy
Biofuels
Agave
sugarcane
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TC Biochemical engineering::TCB Biotechnology
Blake Simmons
Jason Lupoi
Robert Henry
Biomass Modification, Characterization and Process Monitoring Analytics to Support Biofuel and Biomaterial Production
title Biomass Modification, Characterization and Process Monitoring Analytics to Support Biofuel and Biomaterial Production
title_full Biomass Modification, Characterization and Process Monitoring Analytics to Support Biofuel and Biomaterial Production
title_fullStr Biomass Modification, Characterization and Process Monitoring Analytics to Support Biofuel and Biomaterial Production
title_full_unstemmed Biomass Modification, Characterization and Process Monitoring Analytics to Support Biofuel and Biomaterial Production
title_short Biomass Modification, Characterization and Process Monitoring Analytics to Support Biofuel and Biomaterial Production
title_sort biomass modification characterization and process monitoring analytics to support biofuel and biomaterial production
topic TP248.13-248.65
TA1-2040
biomass
NIMS
pretreatment
high-throughput
Proteomics
transgenic
Raman spectroscopy
Biofuels
Agave
sugarcane
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TC Biochemical engineering::TCB Biotechnology
topic_facet TP248.13-248.65
TA1-2040
biomass
NIMS
pretreatment
high-throughput
Proteomics
transgenic
Raman spectroscopy
Biofuels
Agave
sugarcane
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TC Biochemical engineering::TCB Biotechnology
url 18254
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AT jasonlupoi biomassmodificationcharacterizationandprocessmonitoringanalyticstosupportbiofuelandbiomaterialproduction
AT roberthenry biomassmodificationcharacterizationandprocessmonitoringanalyticstosupportbiofuelandbiomaterialproduction