Assessment of the environmental sustainability of solvent-less fatty acid ketonization to bio-based ketones for wax emulsion applications

Boekaerts, Bert; Vandeputte, Margot; Navaré, Kranti; Aelst, Joost Van; Acker, Karel Van; Cocquyt, Jan; Caneyt, Chris Van; Puyvelde, Peter Van; Sels, Bert F.

doi:10.1039/d1gc02430b

Cited by 11 publications

(21 citation statements)

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“…9 Recent life cycle analysis of the pathway studied in this work, VFA upgrading to sustainable aviation fuel (SAF) via sequential ketonization and hydrotreating, found that the process has a carbon emissions intensity below zero (−55 g CO 2eq MJ −1 ) due to avoided methane emissions otherwise generated when wet waste is landfilled. 10 Life-cycle analyses of VFA upgrading to diesel blendstocks 11 and fatty acid upgrading to waxes 12 and surfactants 13 also show that valorization of waste acids for fuels and chemicals results in substantial carbon intensity reductions. Thus, upgrading of wet waste-derived VFAs for use as aviation fuel blendstocks is a promising decarbonization pathway.…”

Section: Introductionmentioning

confidence: 99%

Kinetics and Reactor Design Principles of Volatile Fatty Acid Ketonization for Sustainable Aviation Fuel Production

Miller

Hafenstine

Nguyen

et al. 2022

Ind. Eng. Chem. Res.

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Ketonization of wet waste-derived carboxylic acids (volatile fatty acids, VFAs) constitutes the first step of a process to catalytically upgrade VFAs to an alkane sustainable aviation fuel blendstock. VFA ketonization has been demonstrated at near-theoretical yields at the lab scale, and robust operation of industrial-scale ketonization reactors is essential for the commercialization of VFA upgrading to sustainable aviation fuel. We present a ketonization kinetic study of hexanoic acid, a VFA model compound, over commercial ZrO2 and use the kinetic parameters derived from the study in an adiabatic packed-bed reactor simulation of hexanoic acid ketonization running to near-complete (98%) conversion. A key findings from the kinetic study is that ketonization rate is positive order in acid pressure at low (<10 kPa) pressures and transitions to zero order at higher pressures, conforming to a Langmuir–Hinshelwood surface coupling mechanism. Rates are inhibited by ketonization coproduct water but not by ketones themselves or coproduct CO2. Reactor simulations using these kinetics show that rate inhibition by water controls reactor size and that size requirements can be lessened by employing designs that allow for the removal of water from the partially converted acid stream.

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Section: Introductionmentioning

confidence: 99%

Kinetics and Reactor Design Principles of Volatile Fatty Acid Ketonization for Sustainable Aviation Fuel Production

Miller

Hafenstine

Nguyen

et al. 2022

Ind. Eng. Chem. Res.

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“…However, their molecular composition is suitable for C−C coupling to renewable C 23 −C 35 "wax" ketones. 11 They can be used directly as end products 12 or may serve as intermediates to undergo hydrodeoxygenation and hydroisomerization reactions for the synthesis of bio-based paraffinic waxes and lubricants. 13−16 Ultimately, they can serve as platform molecules for a wide array of functionalized compounds such as amines, alcohols, sulfonates, olefins, etc.…”

Section: ■ Introductionmentioning

confidence: 99%

“…In this context, a combined green chemistry and life cycle assessment (LCA) analysis study on a dedicated liquid-phase fatty acid ketonization process with anatase TiO 2 demonstrated that its use significantly contributes to the overall environmental burden of wax ketone production. 12 More specifically, for the production of 1 kg of ketone bio-wax product, 0.03 kg of TiO 2 catalyst was required, of which the latter showed substantial contributions to multiple LCA impact categories, viz., 2.2% climate change impact, 3.7% freshwater consumption, 43% freshwater eutrophication, 16% human toxicity, 16% terrestrial acidification, and 10% terrestrial ecotoxicity. These impacts are a result of the environmental footprint of the anatase TiO 2 fabrication process and moderate ketonization activity.…”

Section: ■ Introductionmentioning

confidence: 99%

“…However, their molecular composition is suitable for C–C coupling to renewable C 23 –C 35 “wax” ketones . They can be used directly as end products or may serve as intermediates to undergo hydrodeoxygenation and hydroisomerization reactions for the synthesis of bio-based paraffinic waxes and lubricants. − Ultimately, they can serve as platform molecules for a wide array of functionalized compounds such as amines, alcohols, sulfonates, olefins, etc. Since its discovery, metals, metal salts, zeolites, and metal oxides have been used as ketonization catalysts. Of the latter, amphoteric TiO 2 , CeO 2 , and ZrO 2 materials have shown the desired combination of high activity, selectivity, and (often) stability. , Their surface active sites consist of coordinatively unsaturated M n+ –O 2– Lewis acid–base pairs that can interact with the carboxylic acid substrates in multiple adsorption modes.…”

Section: Introductionmentioning

confidence: 99%

“…Given the higher sensitivity to product deactivation of rutile, especially in a solvent-less reaction system where anatase achieved higher overall fatty acid conversion and ketone product yields on a mass basis, anatase can be considered the preferred catalyst. In this context, a combined green chemistry and life cycle assessment (LCA) analysis study on a dedicated liquid-phase fatty acid ketonization process with anatase TiO 2 demonstrated that its use significantly contributes to the overall environmental burden of wax ketone production . More specifically, for the production of 1 kg of ketone bio-wax product, 0.03 kg of TiO 2 catalyst was required, of which the latter showed substantial contributions to multiple LCA impact categories, viz., 2.2% climate change impact, 3.7% freshwater consumption, 43% freshwater eutrophication, 16% human toxicity, 16% terrestrial acidification, and 10% terrestrial ecotoxicity.…”

Section: Introductionmentioning

confidence: 99%

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Metal-Free Reduction Creates Highly Active TiO₂ Surfaces for Fatty Acid Ketonization

Boekaerts

Sels

2022

ACS Sustainable Chem. Eng.

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TiO2 is one of the most promising catalysts for liquid-phase ketonization of carboxylic acids. As recently reported, its use significantly contributes to the overall environmental impact of the fatty acid ketonization process. Therefore, postsynthetic modifications such as metal addition and thermal treatment under inert and reducing atmospheres were studied to enhance the catalytic activity of anatase TiO2 for the ketonization of lauric acid. Although more active surfaces can be generated by the additional metal through hydrogen spillover effects, its presence led to substantial decarboxylation rather than ketonization. Interestingly, metal-free anatase TiO2 is also substantially activated after thermal treatment in nitrogen or hydrogen gas, while maintaining its full ketonization selectivity. Ascertained by X-ray analysis, this was not related to polymorphism but due to a higher content of Lewis acid sites, of which the hydrogen-treated catalysts possessed the largest density. A quadratic relationship appears between the ketonization rate and surface acid site density, a defining characteristic of rate-determining bimolecular C–C coupling in the ketonization mechanism. In contrast to studies on short-chain carboxylic acids, this liquid-phase study renders hydrogenated TiO2 as the most promising catalyst, while metal addition is less suitable for selectivity reasons. Although less essential for bio-oil upgrading, high selectivity is of utmost importance for on-purpose fatty acid ketonization.

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The Underlying Catalytic Role of Oxygen Vacancies in Fatty Acid Methyl Esters Ketonization over TiO_x Catalysts

Yazdanpanah,

Fereidooni,

Márquez

et al. 2023

ChemSusChem

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Recently, interest in converting bio‐derived fatty acid methyl esters (FAMEs) into added‐value products has significantly increased. The selectivity of ketonization reaction in the conversion of the FAMEs has significantly hampered the efficiency of this process. Herein, we prepared catalysts with different levels of oxygen vacancies while the crystal phase remained unchanged. The catalyst with the highest level of oxygen vacancy exhibited the maximum selectivity. The density functional theory (DFT) simulation showed an increase in interatomic distances leading to the formation of frustrated Lewis pairs (FLPs) upon the creation of oxygen vacancies. The surface measurements, type and density of acid sites of the catalysts, showed that the Lewis acid sites enhanced the selectivity for ketone production; while Bronsted acid sites increased the formation of by‐products. Moreover, the ketone formation rate was directly proportional to acid density. The findings of this research provide a different approach for catalyst design, based on defects engineering and their effect on the surface activity, which could be used for enhancing the catalytic performance of novel metal oxides.

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Assessment of the environmental sustainability of solvent-less fatty acid ketonization to bio-based ketones for wax emulsion applications

Abstract: The environmental and economic challenges currently faced by the wax market may be addressed by the use of sustainable bio-based alternatives. Hereto, ketonization of vegetable oils and animal fats is...

Cited by 11 publications

References 73 publications

Kinetics and Reactor Design Principles of Volatile Fatty Acid Ketonization for Sustainable Aviation Fuel Production

Kinetics and Reactor Design Principles of Volatile Fatty Acid Ketonization for Sustainable Aviation Fuel Production

Metal-Free Reduction Creates Highly Active TiO₂ Surfaces for Fatty Acid Ketonization

The Underlying Catalytic Role of Oxygen Vacancies in Fatty Acid Methyl Esters Ketonization over TiO_x Catalysts

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Assessment of the environmental sustainability of solvent-less fatty acid ketonization to bio-based ketones for wax emulsion applications

Abstract: The environmental and economic challenges currently faced by the wax market may be addressed by the use of sustainable bio-based alternatives. Hereto, ketonization of vegetable oils and animal fats is...

Cited by 11 publications

References 73 publications

Kinetics and Reactor Design Principles of Volatile Fatty Acid Ketonization for Sustainable Aviation Fuel Production

Kinetics and Reactor Design Principles of Volatile Fatty Acid Ketonization for Sustainable Aviation Fuel Production

Metal-Free Reduction Creates Highly Active TiO2 Surfaces for Fatty Acid Ketonization

The Underlying Catalytic Role of Oxygen Vacancies in Fatty Acid Methyl Esters Ketonization over TiOx Catalysts

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Product

Resources

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Metal-Free Reduction Creates Highly Active TiO₂ Surfaces for Fatty Acid Ketonization

The Underlying Catalytic Role of Oxygen Vacancies in Fatty Acid Methyl Esters Ketonization over TiO_x Catalysts