Your search keyword '"Panos D. Kouris"' showing total 10 results

1. Renewable thiol-yne ‘click’ networks based on propargylated lignin for adhesive resin applications

Author

Monika A. Jedrzejczyk, Panos D. Kouris, Michael D. Boot, Emiel J.M. Hensen, Katrien V. Bernaerts, AMIBM, RS: FSE AMIBM, Inorganic Materials & Catalysis, Energy Technology, and EIRES Chem. for Sustainable Energy Systems

Subjects

thermosets, Polymers and Plastics, Process Chemistry and Technology, FRACTIONATION, Organic Chemistry, fungi, technology, industry, and agriculture, food and beverages, lignin, macromolecular substances, complex mixtures, TECHNICAL LIGNINS, CHEMISTRY, wood adhesives, DEPOLYMERIZATION, "click" chemistry, SDG 7 - Affordable and Clean Energy, propargylated lignin, thiol-yne, SDG 7 – Betaalbare en schone energie

Abstract

In this study, the development of lignin-based resins for wood adhesion applications was demonstrated. We investigated two lignin fractions: commercial Protobind 1000 lignin and methanol-soluble Protobind 1000 lignin fraction after mild solvolysis. Although lignin has previously been incorporated into various cross-linked systems, this is the first report on lignin-based thermosets obtained via thiol–yne “click” chemistry. In this approach, lignin was functionalized with terminal alkyne groups followed by cross-linking with a multifunctional thiol, resulting in polymeric network formation. The influence of the curing conditions on the resin characteristics and performance was studied, by varying the amount of reactive monomeric diluents. Additionally, a post-curing strategy utilizing the Claisen rearrangement was investigated. These resins were tested as a wood adhesive and were proven to possess a desirable performance, comparable to the state-of-art phenol-formaldehyde resins. Lignin-based thiol–yne resins turn out to be an alternative to phenol-formaldehyde resins, currently used as adhesives and coatings. Although it is possible to use lignin in phenol-formaldehyde resins, lignin addition is compromising the resin’s performance. The main benefits over the phenol-formaldehyde approach are that higher lignin loadings are possible to achieve, and no volatiles are emitted during the resin processing and use.

Published

2022

2. Investigation of the combustion and emissions of lignin derived aromatic oxygenates in a marine diesel engine

Author

Georgios D Kouris, Panos D. Kouris, Emiel J. M. Hensen, Dawei Wu, Michael Boot, Zhichao Zhang, Inorganic Materials & Catalysis, Energy Technology, and EIRES Chem. for Sustainable Energy Systems

Subjects

Waste management, Renewable Energy, Sustainability and the Environment, H300, lignin, Bioengineering, Marine engine, Diesel engine, Combustion, SDG 14 – Leven onder water, chemistry.chemical_compound, chemistry, Biofuel, Lignin, biofuel, SDG 14 - Life Below Water, SDG 7 - Affordable and Clean Energy, marine engine, Oxygenate, SDG 7 – Betaalbare en schone energie, drop-in fuel

Abstract

As a hard-to-decarbonize sector, the shipping industry is experiencing demands to accelerate the transition from fossil fuels to alternative low-carbon fuels, to significantly reduce the negative impacts on the environment. Biofuels are regarded as one of the solutions for decarbonization in the marine sector. This paper introduces a lignin-derived drop-in biofuel, 2-methoxy-4-propylphenol (2M4PP), from non-edible feedstocks and investigates engine performance using its 10% (by volume) blend with standard diesel fuel (DF) at variable engine speeds and loads. Results show insignificant difference between the in-cylinder pressures of the proposed blend and DF. The diesel-2M4PP blend emits less carbon monoxide (CO) and nitric oxide (NO x) than DF at all speeds by up to 39.6% and 10.7% respectively, although its brake-specific fuel consumption (BSFC) is higher. A Ricardo wave model, which is validated with engine experimental data at 2400 rpm speed and full load, is investigated by adjusting injection pressure, injection timing, injection duration and nozzle diameter. The optimal parameters, i.e., 214 bar injection pressure, 6° injection timing, 41.4° injection duration, and 0.37 mm injector orifice, lead to the best engine performance with improved brake power, reduced NO x emissions, and limited influence on BSFC and hydrocarbon emissions compared to DF.

Published

2021

3. Lignin-Based Additives for Improved Thermo-Oxidative Stability of Biolubricants

Author

Panos D. Kouris, Michael Boot, Monika Jedrzejczyk, Bert F. Sels, Guido R.M.M. Haenen, Mohamed Moalin, Korneel Van Aelst, Bert Lagrain, Katrien V. Bernaerts, Emiel J. M. Hensen, Joost Van Aelst, Sander Van den Bosch, Inorganic Materials & Catalysis, Energy Technology, EIRES Chem. for Sustainable Energy Systems, RS: FSE Biobased Materials, AMIBM, RS: Carim - H03 ECM and Wnt signaling, RS: NUTRIM - R3 - Respiratory & Age-related Health, Farmacologie en Toxicologie, and RS: FSE AMIBM

Subjects

DPPH assay, Technology, Engineering, Chemical, OIL-BASED LUBRICANTS, Tribology, General Chemical Engineering, Chemistry, Multidisciplinary, Biolubricants, Esterified lignin, Oxidative phosphorylation, Lignin, Antioxidants, Thermo-oxidative stability, TECHNICAL LIGNINS, BIODIESEL, chemistry.chemical_compound, Engineering, Rheology, CHEMISTRY, Environmental Chemistry, SIDE, SDG 7 - Affordable and Clean Energy, Green & Sustainable Science & Technology, Science & Technology, Renewable Energy, Sustainability and the Environment, ANTIOXIDANT PROPERTIES, General Chemistry, LIGNOCELLULOSE FRACTIONATION, SOFTWOOD KRAFT LIGNIN, Biorefinery, GEL-LIKE DISPERSIONS, chemistry, Chemical engineering, DEPOLYMERIZATION, Physical Sciences, Science & Technology - Other Topics, SDG 7 – Betaalbare en schone energie

Abstract

There is an environmental concern regarding the use of petroleum-based lubricants, which are generally toxic and nonbiodegradable. Biobased lubricants, such as vegetable oils, are the alternative: they show excellent lubricity, are readily biodegradable and nontoxic. However, a major disadvantage of using vegetable oils in lubricant applications is their lack of thermo-oxidative stability, which can be improved by antioxidant additives. Here, we propose the use of lignin-based additives in biolubricant formulations to improve this feature, based on lignin’s known antioxidant properties. To ensure a stable dispersion in vegetable oil, lignin was partially esterified. Antioxidant properties of lignin before and after palmitoylation were demonstrated in a 2,2-diphenyl-1-picrylhydrazyl (DPPH) assay. Four different lignin-based fractions, commercial Protobind P1000 soda lignin from straw, solvolytically fractionated Protobind P1000 lignin and two lignin fractions from reductively catalyzed fractionation (RCF) of native birch wood, were tested in biolubricant formulations with castor oil as base oil. Those lignin fractions exhibited excellent performance compared to butylated hydroxytoluene (BHT), a commonly used petroleum-based antioxidant. Formulations of modified lignin in castor oil possess improved thermo-oxidative stability, as illustrated by their increased oxidation induction time. Additionally, rheological and tribological tests demonstrate similar, or in some cases improved, lubricating properties compared to castor oil. This study showcases the successful incorporation of lignin-based antioxidants in biolubricant formulations, tackling the major disadvantage of vegetable oils as environment-friendly lubricants.

Published

2021

4. Mild thermolytic solvolysis of technical lignins in polar organic solvents to a crude lignin oil

Author

Dannie J. G. P. van Osch, Panos D. Kouris, Emiel J. M. Hensen, Geert J. W. Cremers, Michael Boot, Inorganic Materials & Catalysis, Energy Technology, and EIRES Chem. for Sustainable Energy Systems

Subjects

Ethanol, Renewable Energy, Sustainability and the Environment, fungi, technology, industry, and agriculture, food and beverages, Energy Engineering and Power Technology, Alcohol, macromolecular substances, Condensation reaction, complex mixtures, Solvent, Gel permeation chromatography, chemistry.chemical_compound, Fuel Technology, chemistry, Lignin, Methanol, Solvolysis, SDG 7 - Affordable and Clean Energy, SDG 7 – Betaalbare en schone energie, Nuclear chemistry

Abstract

A mild thermal solvolysis process using alcohols for the valorization of technical Protobind soda lignin into crude lignin oil (CLO) is presented. The solubilization process results in lower molecular weight lignin fragments (1250–1550 g mol−1cf. 2500 g mol−1 of parent lignin), while rejecting heavy compounds and other solid impurities. The influence of the reaction temperature (100–350 °C), residence time (0.5–4 h), lignin : solvent ratio (1 : 15–1 : 2 w/v) and alcohol solvent (methanol, ethanol, 1-propanol, 1-butanol, and 1-octanol) on the amount and type of products is investigated. At a high lignin loading (ratio < 1 : 5 w/v) and under optimum conditions for lignin solubilization (T = 200 °C, t = 0.5 h), the condensation reactions and solvent consumption are minimized. Methanol exhibits the highest solvolytic efficacy resulting in an overall lignin solubilization degree of 61 wt%, which includes some heavier lignin fractions originating from condensation reactions. The other alcohols resulted in a lignin solubilization degree of 57 wt% for ethanol, 53 wt% for 1-propanol, 51 wt% for 1-butanol and 38 wt% for 1-octanol. The solvent losses based on GC-MS analysis of the obtained CLOs were 1.1 wt% for methanol, 1.4 wt% for ethanol and 2.2 wt% for 1-butanol. Hansen solubility parameters are employed to discuss the effect of solvent on the solubilization process. Gel permeation chromatography and heteronuclear single quantum coherence NMR of solubilized fractions revealed cleavage of β-O-4 bonds during thermal solvolysis, explaining the molecular weight reduction. Methanol is the most favourable solvent and is utilized in solubilization of 5 different biorefinery lignins. In all cases, this led to CLO with a lower molecular weight of the lignin fragments, a lower polydispersity and an increased hydroxyl group content.

Published

2020

5. Molecular weight-based fractionation of lignin oils by membrane separation technology

Author

Griet Jacobs, Panos D. Kouris, Pieter Vandezande, Ana M. Panaite, Emiel J. M. Hensen, Karolien Vanbroekhoven, Viviana Polizzi, Kelly Servaes, Michael Boot, Inorganic Materials & Catalysis, Energy Technology, and EIRES Chem. for Sustainable Energy Systems

Subjects

bio-aromatics, lignin, macromolecular substances, Fractionation, 010402 general chemistry, complex mixtures, 01 natural sciences, Membrane technology, Biomaterials, chemistry.chemical_compound, renewable resource, lignin depolymerization, Lignin, Organic chemistry, SDG 7 - Affordable and Clean Energy, 010405 organic chemistry, Chemistry, membrane separation, technology, industry, and agriculture, food and beverages, renewable resources, 0104 chemical sciences, Diafiltration, Membrane, Ceramic membrane, nanofiltration, Soda pulping, Nanofiltration, SDG 7 – Betaalbare en schone energie

Abstract

Lignin is a renewable and abundant source for production of bio-based chemicals and is a valuable alternative to crude oil to obtain aromatic building blocks. It is built from aromatic units with strong chemical linkages, which need to be cleaved to enable the use of the aromatic compounds in industrial applications. In addition to depolymerizing lignin, efficient fractionation and conversion of the resulting complex mixtures is an essential step in the valorization of lignin derivatives for different applications. In this work, we studied the separation of a lignin oil obtained by catalytic cleavage in supercritical ethanol (scEtOH) of technical lignin produced by means of soda pulping of wheat straw. The use of six commercial polymeric nanofiltration (NF) membranes and one in-house developed Grignard-functionalized ceramic membrane was investigated for the fractionation of a mixture of lignin derivatives. Separation by molecular weight (MW) was observed with the polymeric NP030 membrane but not with the other membranes tested. The development of a protocol using this membrane in the diafiltration mode for fractionation of crude lignin oils (CLOs) is discussed.

Published

2020

6. The Impact of Biomass and Acid Loading on Methanolysis during Two-Step Lignin-First Processing of Birchwood

Author

Emiel J. M. Hensen, Geert J. W. Cremers, Xianhong Ouyang, Panos D. Kouris, Xiaoming Huang, Dannie J. G. P. van Osch, Michael Boot, Inorganic Materials & Catalysis, Physical Chemistry, Energy Technology, and EIRES Chem. for Sustainable Energy Systems

Subjects

Biomass, Ether, 02 engineering and technology, TP1-1185, 01 natural sciences, complex mixtures, Catalysis, chemistry.chemical_compound, Lignin, depolymerization, lignin first, Physical and Theoretical Chemistry, QD1-999, lignin oil, biomass, 010405 organic chemistry, Depolymerization, Chemical technology, food and beverages, Sulfuric acid, 021001 nanoscience & nanotechnology, β-O-4 content, 0104 chemical sciences, Solvent, Chemistry, chemistry, Methanol, Solvolysis, 0210 nano-technology, optimization, Nuclear chemistry

Abstract

We optimized the solvolysis step in methanol for two-step lignin-first upgrading of woody biomass. Birchwood was first converted via sulfuric acid methanolysis to cellulose pulp and a lignin oil intermediate, which comprises a mixture of lignin oligomers and C5 sugars in the methanol solvent. The impact of reaction temperature (140–200 °C), acid loading (0.24–0.81 wt%, dry biomass), methanol/biomass ratio (2.3/1–15.8/1 w/w) and reaction time (2 h and 0.5 h) was investigated. At high biomass loadings (ratio &lt, 6.3/1 w/w), operation at elevated pressure facilitates delignification by keeping methanol in the liquid phase. A high degree of delignification goes together to a large extent with C5 sugar release, mostly in the form of methyl xylosides. Gel permeation chromatography and heteronuclear single quantum coherence NMR of lignin fractions obtained at high acid (0.81 wt%) and low biomass (15.8/1 w/w) loading revealed extensive cleavage of β-O-4′ bonds during acidolysis at 180 °C for 2 h. At an optimized methanol/biomass ratio of 2.3/1 w/w and acid loading (0.24 wt%), more β-O-4′ bonds could be preserved, i.e., about 33% after 2 h and 47% after 0.5 h. The high reactivity of the extracted lignin fragments was confirmed by a second hydrogenolysis step. Reductive treatment with Pd/C under mild conditions led to disappearance of ether linkages and molecular weight reduction in the hydrotreated lignin oil.

Published

2021

7. A novel semi-batch autoclave reactor to overcome thermal dwell time in solvent liquefaction experiments

Author

Jessica L. Brown, Emiel J. M. Hensen, Michael Boot, Sean A. Rollag, Panos D. Kouris, Ryan G. Smith, Robert C. Brown, Arpa Ghosh, Preston Gable, Jake K. Lindstrom, Chad A. Peterson, Inorganic Materials & Catalysis, Energy Technology, and EIRES Chem. for Sustainable Energy Systems

Subjects

Process development, Materials science, General Chemical Engineering, 02 engineering and technology, 010402 general chemistry, Lignin, 01 natural sciences, Industrial and Manufacturing Engineering, Autoclave, Reaction rate, Heat transfer, Environmental Chemistry, Process engineering, business.industry, Continuous reactor, Liquefaction, General Chemistry, 021001 nanoscience & nanotechnology, Biorefinery, Solvent liquefaction, 0104 chemical sciences, Solvent, Dwell time, Isobaric process, 0210 nano-technology, business

Abstract

The thermal profile of solvent liquefaction experiments must be well-controlled to generate data suitable for process scaling and technoeconomic analysis. Acknowledging the differences in small-scale batch systems compared to continuous commercial processes is important. In particular, many experiments have long heating and cooling periods, which influence rates of reaction in ways that would not occur in commercial continuous reactors. To overcome this problem, a novel semi-batch autoclave (SBA) system was built to rapidly heat reactants and cool products while maintaining constant pressure during solvent liquefaction experiments. In this study, the performance of the SBA reactor was compared to an isobaric conventional batch autoclave (ICBA) reactor in the solvent liquefaction of lignin in n-butanol. Heat transfer affected both the apparent reaction rate and measured product yields. Solvent liquefaction limited by slow heating gave the misperception that reaction rates were faster than was actually the case and promoted the formation of char-like solids. Experiments constrained by slow heat transfer are of limited use in process modeling and reactor design, which would otherwise result in undersized reactors for desired processing rates. The SBA system facilitates the design and scale-up of commercial SL plants as it approximates the thermal profile of a continuous system.

Published

2021

8. Industrial lignin from 2G biorefineries – Assessment of availability and pricing strategies

Author

Panos D. Kouris, David Smeulders, Svetlana V. Obydenkova, Michael Boot, Emiel J. M. Hensen, Yvonne van der Meer, Energy Technology, Inorganic Materials & Catalysis, EAISI High Tech Systems, AMIBM, RS: FSE AMIBM, Biobased Materials, RS: FSE Biobased Materials, Sciences, and RS: FSE Sciences

Subjects

0106 biological sciences, Environmental Engineering, Lignin availability, Energy balance, Bioengineering, Lignin/chemistry, 010501 environmental sciences, Lignin, 01 natural sciences, Hydrolysate, Lignin price, chemistry.chemical_compound, Electricity, 010608 biotechnology, Market price, Industry, SDG 7 - Affordable and Clean Energy, Multi-product biorefinery, Waste Management and Disposal, 0105 earth and related environmental sciences, Mathematics, Zero-energy building, Ethanol, Ethanol/chemistry, Renewable Energy, Sustainability and the Environment, business.industry, General Medicine, Pulp and paper industry, Biorefinery, Industrial lignin, Pricing strategies, chemistry, Costs and Cost Analysis, Pricing strategy, business, SDG 7 – Betaalbare en schone energie

Abstract

With a view to boost practical implementation of lignin conversion technologies, this paper assesses the availability of industrial lignin and evaluates pricing strategies applicable to multi-product biorefineries. The biorefineries, producing either denatured ethanol or sugar hydrolysate as a main product, can yield 43% and 61% of lignin residue (LR) comprising 33% and 23% of lignin by mass, respectively, without sacrificing the output of the main product and before electricity import has become indispensable. Analysis of the pricing strategies reveals that LR must be treated as a low-value by-product, and its minimum selling price (MSP) is driven mainly by the prevailing electricity price. Under the biorefinery net zero energy balance, and taking into account the LR market price adequacy, as well as the main probabilistic conditions, the upper range for the MSP is calculated at $43–70 and $18–37 per ton for biorefineries producing ethanol and hydrolysate, respectively.

Published

2019

9. Scaling-up catalytic depolymerisation of lignin: performance criteria for industrial operation

Author

Emiel J. M. Hensen, Panos D. Kouris, Michael Boot, Xiaoming Huang, Inorganic Materials & Catalysis, and Energy Technology

Subjects

Scaling up, Fouling, 010405 organic chemistry, Depolymerization, Biomass, Supercritical ethanol, General Chemistry, 010402 general chemistry, Pulp and paper industry, 01 natural sciences, Lignin, Catalysis, Supercritical fluid, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Yield (chemistry), Scientific method, Industrial operation, Environmental science

Abstract

Much scientific research has been carried to convert lignin into valuable biobased chemicals or fuels. Most of these studies had the objective to develop active and selective catalysts for effective lignin depolymerization; this with little regard for the parameters that are necessary for later commercialization of these technologies. In this work, we have chosen as a case study a process that has been extensively studied and reported on earlier by our group. This process converts (technical) lignin into mainly aromatic compounds, using supercritical ethanol and a Cu–Mg–Al mixed oxide catalyst. Here, we investigate the impact of scaling up this process from lab to bench scale. More specifically, we study the influence of higher lignin loadings than previously reported on, amongst other parameters, monomer yield, solvent losses and catalyst fouling; all of which being critical performance parameters for industrial operation. After we examined the technical feasibility of our process at 4 L scale, we further looked into the economic viability of this technology, by introducing two performance criteria, both of which being a function of lignin monomer yield. The ratios (g/g) of yield over total feed, and yield over ethanol losses are presented as qualitative indicators for capital expenditure (CAPEX) and operational expenditure (OPEX), respectively. This exercise sheds some much needed light on the trade-off between yield optimization and cost minimization.

Published

2018

10. Environmental economics of lignin derived transport fuels

Author

Panos D. Kouris, Emiel J. M. Hensen, Svetlana V. Obydenkova, Hero J. Heeres, Michael Boot, Chemical Technology, Inorganic Materials & Catalysis, and Power & Flow

Subjects

Greenhouse Effect, Environmental Engineering, DUTY DIESEL-ENGINE, 020209 energy, Renewable Fuel Standard, BIOFUELS, Bioengineering, 02 engineering and technology, BIO-OIL, Environment, Natural Gas, Fuels, Lignin, FAST PYROLYSIS, CHEMICALS, Life cycle assessment, 0202 electrical engineering, electronic engineering, information engineering, Biomass, SDG 7 - Affordable and Clean Energy, SDG 14 - Life Below Water, Waste Management and Disposal, Life-cycle assessment, EMISSIONS, Waste management, Ethanol, Renewable Energy, Sustainability and the Environment, business.industry, Chemistry, Fossil fuel, COST, General Medicine, Renewable fuels, PERFORMANCE, SDG 14 – Leven onder water, LOGISTICS, SDG 12 – Verantwoordelijke consumptie en productie, Biofuel, Cellulosic ethanol, Greenhouse gas, Alternative energy, 2G ethanol plants, business, SDG 12 - Responsible Consumption and Production, CELLULOSIC ETHANOL, SDG 7 – Betaalbare en schone energie

Abstract

This paper explores the environmental and economic aspects of fast pyrolytic conversion of lignin, obtained from 2G ethanol plants, to transport fuels for both the marine and automotive markets. Various scenarios are explored, pertaining to aggregation of lignin from several sites, alternative energy carries to replace lignin, transport modalities, and allocation methodology. The results highlight two critical factors that ultimately determine the economic and/or environmental fuel viability. The first factor, the logistics scheme, exhibited the disadvantage of the centralized approach, owing to prohibitively expensive transportation costs of the low energy-dense lignin. Life cycle analysis (LCA) displayed the second critical factor related to alternative energy carrier selection. Natural gas (NG) chosen over additional biomass boosts well-to-wheel greenhouse gas emissions (WTW GHG) to a level incompatible with the reduction targets set by the U.S. renewable fuel standard (RFS). Adversely, the process' economics revealed higher profits vs. fossil energy carrier. (C) 2017 The Author(s). Published by Elsevier Ltd.

Published

2017