Mass Transport Limitations and Kinetic Consequences of Corn Stover Deacetylation

Thornburg, Nicholas E.; Ness, Ryan; Crowley, Meagan F.; Bu, Lintao; Pecha, M. Brennan; Usseglio-Viretta, François; Bharadwaj, Vivek S.; Li, Yudong; Chen, Xiaowen; Sievers, David A.; Wolfrum, Edward J.; Resch, Michael G.; Ciesielski, Peter N.

doi:10.3389/fenrg.2022.841169

Cited by 6 publications

(3 citation statements)

References 50 publications

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“…Beyond direct application to separation processes, the binding free energies of lignocellulosic interactions in different organic solvents (∆G binding ) and solvent diffusion constants, calculated using all-atom molecular dynamics, are essential inputs into future continuum scale finite element models (FEM) to investigate reaction-diffusion mass transport properties of plant biomass [44,101]. Experimentally validated continuum based models can effectively quantify structural and transport properties of woody biomass, before and after pyrolysis, and critical towards engineering and optimizing the conversion processes for plant biomass based chemical production [102].…”

Section: Discussionmentioning

confidence: 99%

Atomistic origins of biomass recalcitrance in organosolv pretreatment

Sarkar

Santiago

Vermaas

2023

Chemical Engineering Science

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Section: Discussionmentioning

confidence: 99%

Atomistic origins of biomass recalcitrance in organosolv pretreatment

Sarkar

Santiago

Vermaas

2023

Chemical Engineering Science

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“…This information guides engineers’ selection of acceptable process conditions and materials of construction. The comparatively wide breadth of biomass and waste carbon feedstock sources and often high variability in properties even within one “feedstock” (e.g., corn stover) have both (i) prevented the same systematic tabulation of biomass and waste feedstock properties and (ii) heightened the uncertainties around estimated properties, dramatically increasing the risk of process failure due to poor understanding of material attributes. One particularly common failure mode stemming from this gap is buildup of initially undetected trace contaminants unique to biomass in process equipment over time. Relative complexity of biomass processing compared to petroleum .…”

Section: Sources Of Failure In Scale-up Of Biomass and Waste Carbon C...mentioning

confidence: 99%

Risk Minimization in Scale-Up of Biomass and Waste Carbon Upgrading Processes

Miller,

Nimlos,

et al. 2023

ACS Sustainable Chem. Eng.

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Improving the odds and pace of successful biomass and waste carbon utilization technology scale-up is crucial to decarbonizing key industries such as aviation and materials within timelines required to meet global climate goals. In this perspective, we review deficiencies commonly encountered during scale-up to show that many nascent technology developers place too much focus on simply demonstrating that technologies work in progressively larger units ("profit") without expending enough up-front research effort to identify and derisk roadblocks to commercialization (collecting "information") to inform the design of these units. We combine this conclusion with economic and timeline data collected from technology scale-up and piloting operations at the National Renewable Energy Laboratory (NREL) to motivate a more scientific, risk-minimized approach to biomass and waste carbon upgrading scale-up. Our proposed approach emphasizes maximizing information collection in the smallest, most agile, and least expensive experimental setups possible, emulating the mentality embraced by R&D across the petrochemical industry. Key points are supported by examples of successful and unsuccessful scale-up efforts undertaken at NREL and elsewhere. We close by showing that the U.S. national laboratory system is uniquely well equipped to serve as a hub to facilitate effective scale-up of promising biomass and waste carbon upgrading technologies.

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“…The internal mass transfer has been considered in a vast number of heterogeneous catalysis studies in different applications ranging from bio-applications 1,2 and biomass upgrading 3 to thermal catalysis [4][5][6][7][8] and energy materials [9][10][11][12] . The internal transport effect in porous catalytic materials is studied in a reaction-diffusion phenomenon where it is coupled with the intrinsic kinetics of the catalysts 13 .…”

Section: Introductionmentioning

confidence: 99%

Strategy to enhance selectivity in a two-step reaction using the R1-R2-D reactions-diffusion phenomena

Najimu

Adamu

Kareem

et al. 2023

Preprint

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An analytically derived criterion for R1-R2 phenomenon is combined with the Weisz criterion for R1-D phenomenon to allow the development of assignment criteria for the overall controlling factors in R1-R2-D phenomena. The overall assignment criteria are found to be dependent on the internal effectiveness factors η_1 and η_2, as well as the rate of the individual reactions at the surface of the catalyst particle. Applying the developed criteria to a two-step methanol oxidation reaction suggests that the selectivity of the formaldehyde intermediate species can be enhanced at high reaction temperature when catalysts are specifically designed to enhance the rate of formaldehyde formation. However, CO formation needs to be suppressed to enhance selectivity towards formaldehyde at moderately low temperature. This reaction-diffusion theoretical framework provides guidance for the development of highly selective catalyst for two-reactions-in-series systems and can be extended for higher-number multiple reactions in series and in parallel.

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Mass Transport Limitations and Kinetic Consequences of Corn Stover Deacetylation

Cited by 6 publications

References 50 publications

Atomistic origins of biomass recalcitrance in organosolv pretreatment

Atomistic origins of biomass recalcitrance in organosolv pretreatment

Risk Minimization in Scale-Up of Biomass and Waste Carbon Upgrading Processes

Strategy to enhance selectivity in a two-step reaction using the R1-R2-D reactions-diffusion phenomena

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