Recent Trends in the Production, Combustion and Modeling of Furan-Based Fuels

Eldeeb, Mazen A.; Akih-Kumgeh, Benjamin

doi:10.3390/en11030512

Cited by 54 publications

(24 citation statements)

References 219 publications

(493 reference statements)

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“…Including recent progress in the characterization of its combustion properties, production processes, theoretical kinetic explorations and fundamental combustion properties. The theoretical efforts are focused on the mechanistic pathways for furan decomposition and oxidation, as well as the development of detailed chemical kinetic models 2018 [39] Furthermore, it is well-known that, the field of furan chemistry, both theoretically and in the applied segment is very huge, and no single work can exhaust its many applications that range, from the chemical, to electrical and electronics, pharmacy, biomedical, medicine, the textile, paints and coatings, plastics industry, to name but a few [2,[49][50][51]. Interestingly, according to the density functional theory (DFT) calculations, it has been shown that the heterocyclic furan ring is particularly prone to ring opening, preferably via the C-O bond [52], which can be harnessed for generating tailored and tuneable products, thereby, broadening the application portfolio of furanic systems whether in bio-refineries and/or application materials as has been exemplified in the work of Fan et al [53], when they demonstrated a self-crosslinking elastomeric thermoset via furan ring-opening mechanism.…”

Section: Historical Overviewmentioning

confidence: 99%

Sustainable Chemicals: A Brief Survey of the Furans

et al. 2020

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Whether it is in the textiles, paints and coatings, energy sector, polymers, plastics, woods, sugar chemistry, pharmacy, aerospace and the automotive industries, the multiplicity of applications of furans and their derivatives, have made steady, impressive, and progressive impacts over the last 9 decades. After World War II, due to the shift in focus towards the petroleum-based chemical feedstocks, research, and development studies of these impressive class of lignocellulosic-derived chemicals, slowed down markedly. The trend, however, has reversed remarkably in recent time, due to the pursuit for "green" and sustainable chemical feedstocks, coupled with the increasing concerns over climate change, volatile oil prices and the attendant undesirable environmental issues, associated with fossil hydrocarbons. Chemicals obtained from "green" inedible lignocellulosic biomass, such as: the furans and their derivatives, ranks amongst the most promising, sustainable, and industrially applicable alternatives to various petroleum-derived chemicals; further offering an enormous assortment of unique compounds/materials, and properties analogous to and even exceeding those derived from fossil hydrocarbons. This article reviews selected progresses, so far made, in the field of furans and its derivatives and their application portfolios; while recognising the immense contributions of Peters and Dunlop, who in no small measures, advanced the furan chemical industry during their research efforts at the Oat Hull Research Centre at the Quaker Oats Company, Cedar Rapids, USA.

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Section: Historical Overviewmentioning

confidence: 99%

Sustainable Chemicals: A Brief Survey of the Furans

et al. 2020

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“…The joint optimization of fuel and propulsion systems can exploit the potential of efficient, ultra-low-emission combustion, using renewably made fuels or fuel additives. Chemistry knowledge is needed to tailor their combustion properties and understand the influence of their molecular structure on their reaction mechanisms [13] , [14] , [15] , [16] , [17] , [18] for current and advanced combustion conditions, as well as to determine efficient pathways to make such fuels sustainably and in large scale [17 , 18] .…”

Section: Setting the Stage: Combustion And Chemistry In Contextmentioning

confidence: 99%

“…The relationship between their molecular structure, reaction mechanism, and combustion behavior is an intense area of research, particularly for the development of predictive combustion models. Proposed fuel classes include, among others, cellulosic biofuels such as the furanic family [17 , 18] and synthetic fuels such as oxymethylene ethers (OMEs, CH 3 O(CH 2 O) n CH 3 ). The latter, attractive diesel replacement fuels, offer large pollutant reduction potential owing to their molecular structure featuring only C 1 units [21 , 22] .…”

Section: Setting the Stage: Combustion And Chemistry In Contextmentioning

confidence: 99%

Combustion in the future: The importance of chemistry

Kohse‐Höinghaus

2021

Proceedings of the Combustion Institute

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Combustion involves chemical reactions that are often highly exothermic. Combustion systems utilize the energy of chemical compounds released during this reactive process for transportation, to generate electric power, or to provide heat for various applications. Chemistry and combustion are interlinked in several ways. The outcome of a combustion process in terms of its energy and material balance, regarding the delivery of useful work as well as the generation of harmful emissions, depends sensitively on the molecular nature of the respective fuel. The design of efficient, low-emission combustion processes in compliance with air quality and climate goals suggests a closer inspection of the molecular properties and reactions of conventional, bio-derived, and synthetic fuels. Information about flammability, reaction intensity, and potentially hazardous combustion by-products is important also for safety considerations. Moreover, some of the compounds that serve as fuels can assume important roles in chemical energy storage and conversion. Combustion processes can furthermore be used to synthesize materials with attractive properties. A systematic understanding of the combustion behavior thus demands chemical knowledge. Desirable information includes properties of the thermodynamic states before and after the combustion reactions and relevant details about the dynamic processes that occur during the reactive transformations from the fuel and oxidizer to the products under the given boundary conditions. Combustion systems can be described, tailored, and improved by taking chemical knowledge into account. Combining theory, experiment, model development, simulation, and a systematic analysis of uncertainties enables qualitative or even quantitative predictions for many combustion situations of practical relevance. This article can highlight only a few of the numerous investigations on chemical processes for combustion and combustion-related science and applications, with a main focus on gas-phase reaction systems. It attempts to provide a snapshot of recent progress and a guide to exciting opportunities that drive such research beyond fossil combustion.

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“…42 Furan is a member of a class of bioprivileged molecules, which can be converted into other substances with high added value. 43,44 Furanic compounds can be chemically manipulated or used directly for many purposes. [45][46][47] For example, 5-hydroxymethylfurfural (HMF) is one of the most promising platforms for chemicals formed from hexoses.…”

Section: Introductionmentioning

confidence: 99%