Your search keyword '"Brandt, Agnieszka"' showing total 13 results

1. Atomic charges of sulfur in ionic liquids: experiments and calculations.

Author

Fogarty, Richard M., Rowe, Rebecca, Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Smith, Emily F., Bourne, Richard A., Chamberlain, Thomas W., Thompson, Paul B. J., Hunt, Patricia A., and Lovelock, Kevin R. J.

Abstract

Experimental near edge X-ray absorption fine structure (NEXAFS) spectra, X-ray photoelectron (XP) spectra and Auger electron spectra are reported for sulfur in ionic liquids (ILs) with a range of chemical structures. These values provide experimental measures of the atomic charge in each IL and enable the evaluation of the suitability of NEXAFS spectroscopy and XPS for probing the relative atomic charge of sulfur. In addition, we use Auger electron spectroscopy to show that when XPS binding energies differ by less than 0.5 eV, conclusions on atomic charge should be treated with caution. Our experimental data provides a benchmark for calculations of the atomic charge of sulfur obtained using different methods. Atomic charges were computed for lone ions and ion pairs, both in the gas phase (GP) and in a solvation model (SMD), with a wide range of ion pair conformers considered. Three methods were used to compute the atomic charges: charges from the electrostatic potential using a grid based method (ChelpG), natural bond orbital (NBO) population analysis and Bader’s atoms in molecules (AIM) approach. By comparing the experimental and calculated measures of the atomic charge of sulfur, we provide an order for the sulfur atoms, ranging from the most negative to the most positive atomic charge. Furthermore, we show that both ChelpG and NBO are reasonable methods for calculating the atomic charge of sulfur in ILs, based on the agreement with both the XPS and NEXAFS spectroscopy results. However, the atomic charges of sulfur derived from ChelpG are found to display significant, non-physical conformational dependence. Only small differences in individual atomic charge of sulfur were observed between lone ion (GP) and ion pair IL(SMD) model systems, indicating that ion–ion interactions do not strongly influence individual atomic charges. [ABSTRACT FROM AUTHOR]

Published

2018

2. Mechanistic insights into lignin depolymerisation in acidic ionic liquids.

Author

De Gregorio, Gilbert F., Weber, Cameron C., Gräsvik, John, Welton, Tom, Brandt, Agnieszka, and Hallett, Jason P.

Subjects

LIGNIN structure, IONIC liquids, ANIONS, POLYMERIZATION, CHEMICAL kinetics, HYDROLYSIS, SULFURIC acid

Abstract

Acidic anions of ionic liquids have been demonstrated as efficient catalysts for the cleavage of the β-O-4 ether linkage prevalent in the lignin superstructure. Through the use of lignin model compounds with varying functionality and by monitoring reaction kinetics, a full mechanistic investigation into the hydrolysis of the β-O-4 linkage in acidic ionic liquid solutions is reported. Hammett acidities are reported for different 1-butyl-3-methylimidazolium hydrogen sulfate [C4C1im][HSO4] ionic liquid systems with varying acid and water concentrations and were correlated to substrate reactivity. Results show that the rate of ether cleavage increases with an increase in acidity and the initial dehydration of the model compound is the rate-determining step of the reaction. The Eyring activation parameters of the reaction in hydrogen sulfate ionic liquids with a variety of cations are reported, indicating a consistent E1 dehydration mechanism. Hydrogen bonding in protic ionic liquids was shown to significantly influence anion–cation interactions, consequently altering the solvation of the protonated starting material and therefore the overall rate of reaction. Comparison of reaction rates in these ionic liquids with results within aqueous or aqueous/organic media indicate that the ionic liquids facilitate more rapid cleavage of the β-O-4 ether linkage even under less acidic conditions. All the reported results give a complete overview of both the mechanistic and solvation effects of acidic ionic liquids on lignin model compounds and provide scope for the appropriate selection and design of ionic liquids for lignin processing. [ABSTRACT FROM AUTHOR]

Published

2016

3. Structural changes in lignins isolated using an acidic ionic liquid water mixture.

Author

Brandt, Agnieszka, Chen, Long, van Dongen, Bart E., Welton, Tom, and Hallett, Jason P.

Subjects

*SULFURIC acid, *LIGNINS, *IONIC liquids, *ANIONS, *LIGNOCELLULOSE

Abstract

Recently, acidic ionic liquid water mixtures based on the hydrogen sulfate anion have been shown to effectively extract lignin from lignocellulosic biomass. This study analyses Miscanthus giganteus lignin isolated after extraction with the protic ionic liquid 1-butylimidazolium hydrogen sulfate ([HC4im][HSO4]) followed by precipitation with the antisolvent water. Several analytical techniques were employed, such as quantitative 13C-NMR, 1H–13C HSQC NMR, 31P-NMR, Py-GC-MS, GPC and elemental analysis. The analysis shows that the ionic liquid pretreatment breaks lignin-hemicellulose linkages and depolymerizes the lignin through the cleavage of glycosidic, ester and β-O-4 ether bonds. This is accompanied by solubilization of the newly generated lignin fragments. At longer pretreatment times, repolymerization of lignin fragments through condensation reactions occurs. The isolated lignins were carbohydrate-free, had low sulfur contents, low molecular weights. Early stage lignins were structurally similar to ball-milled lignin, while more treated lignins were enriched in p-hydroxyphenyl and guaiacyl units and had a high phenolic hydroxyl group content. We conclude that, depending on the treatment conditions, lignins with a variety of characteristics can be isolated using this type of ionic liquid solution. [ABSTRACT FROM AUTHOR]

Published

2015

4. Design of low-cost ionic liquids for lignocellulosic biomass pretreatment.

Author

George, Anthe, Brandt, Agnieszka, Tran, Kim, Zahari, Shahrul M. S. Nizan S., Klein-Marcuschamer, Daniel, Sun, Ning, Sathitsuksanoh, Noppadon, Shi, Jian, Stavila, Vitalie, Parthasarathi, Ramakrishnan, Singh, Seema, Holmes, Bradley M., Welton, Tom, Simmons, Blake A., and Hallett, Jason P.

Subjects

*IONIC liquids, *LIGNOCELLULOSE, *BIOMASS conversion, *FEEDSTOCK, *COST effectiveness, *ECONOMICS

Abstract

The cost of ionic liquids (ILs) is one of the main impediments to IL utilization in the cellulosic biorefinery, especially in the pretreatment step. In this study, a number of ionic liquids were synthesized with the goal of optimizing solvent cost and stability whilst demonstrating promising processing potential. To achieve this, inexpensive feedstocks such as sulfuric acid and simple amines were combined into a range of protic ionic liquids containing the hydrogen sulfate [HSO4]− anion. The performance of these ionic liquids was compared to a benchmark system containing the IL 1-ethyl-3-methylimidazolium acetate [C2C1im][OAc]. The highest saccharification yields were observed for the triethylammonium hydrogen sulfate IL, which was 75% as effective as the benchmark system. Techno-economic modeling revealed that this promising and yet to be optimized yield was achieved at a fraction of the processing cost. This study demonstrates that some ILs can compete with the cheapest pretreatment chemicals, such as ammonia, in terms of effectiveness and process cost, removing IL cost as a barrier to the economic viability of IL-based biorefineries. [ABSTRACT FROM AUTHOR]

Published

2015

5. Fractionation of lignocellulosic biomass with the ionic liquid 1-butylimidazolium hydrogen sulfate.

Author

Verdía, Pedro, Brandt, Agnieszka, Hallett, Jason P., Ray, Michael J., and Welton, Tom

Subjects

*IONIC liquids, *SULFURIC acid, *LIGNOCELLULOSE, *FIELD-flow fractionation, *LIQUID chromatography

Abstract

The application of the protic ionic liquid 1-butylimidazolium hydrogen sulfate in the deconstruction (aka pretreatment) and fractionation of lignocellulosic biomass has been investigated. A cellulose rich pulp and a lignin fraction were produced. The pulp was subjected to enzymatic saccharification which allowed recovery of up to 90% of the glucan as fermentable glucose. The influence of the solution acidity on the deconstruction of Miscanthus giganteus was examined by varying the 1-butylimidazole to sulfuric acid ratio. Increased acidity led to shorter pretreatment times and resulted in reduced hemicellulose content in the pulp. Addition of water to the ionic liquid resulted in enhanced saccharification yields. The ability to tune acidity through the use of protic ionic liquids offers a significant advantage in flexibility over dialkylimidazolium analogues. [ABSTRACT FROM AUTHOR]

Published

2014

6. A step towards the a priori design of ionic liquids.

Author

Niedermeyer, Heiko, Ashworth, Claire, Brandt, Agnieszka, Welton, Tom, and Hunt, Patricia A.

Abstract

A range of methods for the computational prediction of experimentally derived α and β Kamlet–Taft parameters, indicators of hydrogen bond (H-bond) acidity and basicity for ionic liquids (ILs) have been explored. Most usefully, a good correlation has been established between several simple and easily computed quantities which allow for a “quick bench-top” evaluation. More accurate, but also more sophisticated methods employing TD-DFT calculations involving the Kamlet–Taft dyes have been examined and evaluated. Importantly, these techniques open up the opportunity for pre-screening and a priori prediction of properties for ILs not yet synthesised. A key fundamental insight into IL H-bonds has been the determination of an estimate for the energy associated with replacing both neutral molecules in a H-bond with ionic molecules, thus forming the “doubly ionic” H-bond found in ILs. [ABSTRACT FROM AUTHOR]

Published

2013

7. Deconstruction of lignocellulosic biomass with ionic liquids.

Author

Brandt, Agnieszka, Gräsvik, John, Hallett, Jason P., and Welton, Tom

Subjects

*LIGNOCELLULOSE, *BIOMASS, *POLYMER fractionation, *IONIC liquids, *BIOPOLYMERS, *SOLVENTS

Abstract

This paper reviews the application of ionic liquids to the deconstruction and fractionation of lignocellulosic biomass, in a process step that is commonly called pretreatment. It is divided into four parts: the first gives background information on lignocellulosic biomass and ionic liquids; the second focuses on the solubility of lignocellulosic biomass (and the individual biopolymers within it) in ionic liquids; the third emphasises the deconstruction effects brought about by the use of ionic liquids as a solvent; the fourth part deals with practical considerations regarding the design of ionic liquid based deconstruction processes. [ABSTRACT FROM AUTHOR]

Published

2013

8. Soaking of pine wood chips with ionic liquids for reduced energy input during grinding.

Author

Brandt, Agnieszka, Erickson, James K., Hallett, Jason P., Murphy, Richard J., Potthast, Antje, Ray, Michael J., Rosenau, Thomas, Schrems, Michael, and Welton, Tom

Subjects

*IONIC liquids, *GRINDING & polishing, *SOLVENTS, *CATALYSTS, *LIGNOCELLULOSE, *HYDROLYSIS

Abstract

Ionic liquids are of great interest as potential solvents/catalysts for the production of fuels and chemicals from lignocellulosic biomass. Attention has focused particularly on the pretreatment of lignocellulose to make the cellulose more accessible to enzymatic hydrolysis. Any biomass processing requires a reduction in the size of the harvested biomass by chipping and/or grinding to make it more amenable to chemical and biological treatments. This paper demonstrates that significant energy savings can be achieved in the grinding of pine wood chips when the ionic liquid is added before the grinding operation. We show that this is due to the lubricating properties of the ionic liquids and not to physico-chemical modifications of the biomass. A brief impregnation of the chipped biomass results in higher savings than a longer treatment. [ABSTRACT FROM AUTHOR]

Published

2012

9. Ionic liquid pretreatment of lignocellulosic biomass with ionic liquid–water mixtures.

Author

Brandt, Agnieszka, Ray, Michael J., To, Trang Q., Leak, David J., Murphy, Richard J., and Welton, Tom

Subjects

*IONIC liquids, *LIGNOCELLULOSE, *BIOMASS, *HYDROLYSIS, *MONOMERS, *HEMICELLULOSE

Abstract

Ground lignocellulosic biomass (Miscanthus giganteus, pine (Pinus sylvestris) and willow (Salix viminalis)) was pretreated with ionic liquid–water mixtures of 1-butyl-3-methylimidazolium methyl sulfate and 1-butyl-3-methylimidazolium hydrogen sulfate. A solid fraction enriched in cellulose was recovered, which was subjected to enzymatic hydrolysis. Up to 90% of the glucose and 25% of the hemicellulose contained in the original biomass were released by the combined ionic liquid pretreatment and the enzymatic hydrolysis. After the pretreatment, the ionic liquid liquor contained the majority of the lignin and the hemicellulose. The lignin portion was partially precipitated from the liquor upon dilution with water. The amount of hemicellulose monomers in the ionic liquid liquor and their conversion into furfurals was also examined. The performance of ionic liquid–water mixtures containing 1,3-dialkylimidazolium ionic liquids with acetate, methanesulfonate, trifluoromethanesulfonate and chloride anions was investigated. The applicability of the ionic liquid 1-butylimidazolium hydrogensulfate for lignocellulose pretreatment was also examined. It was found that ionic liquid liquors containing methyl sulfate, hydrogen sulfate and methanesulfonate anions were most effective in terms of lignin/cellulose fractionation and enhancement of cellulose digestibility. [ABSTRACT FROM AUTHOR]

Published

2011

10. NEXAFS spectroscopy of ionic liquids: experiments versus calculations

Author

Fogarty, Richard M., Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Bourne, Richard A., Chamberlain, Thomas W., Vander Hoogerstraete, Tom, Thompson, Paul B.J., Hunt, Patricia A., Besley, Nicholas A., Lovelock, Kevin R.J., Fogarty, Richard M., Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Bourne, Richard A., Chamberlain, Thomas W., Vander Hoogerstraete, Tom, Thompson, Paul B.J., Hunt, Patricia A., Besley, Nicholas A., and Lovelock, Kevin R.J.

Abstract

Experimental near edge X–ray absorption fine structure (NEXAFS) spectra are reported for 12 ionic liquids (ILs) encompassing a range of chemical structures for both the sulfur 1s and nitrogen 1s edges and compared with time–dependent density functional theory (TD–DFT) calculations. The energy scales for the experimental data were carefully calibrated against literature data. Gas phase calculations were performed on lone ions, ion pairs and ion pair dimers, with a wide range of ion pair conformers considered. For the first time, it is demonstrated that TD–DFT is a suitable method for simulating NEXAFS spectra of ILs, although the number of ions included in the calculations and their conformations are important considerations. For most of the ILs studied, calculations on lone ions in the gas phase were sufficient to successfully reproduce the experimental NEXAFS spectra. However, for certain ILs – for example, those containing a protic ammonium cation –calculations on ion pairs were required to obtain a good agreement with experimental spectra. Furthermore, significant conformational dependence was observed for the protic ammonium ILs, providing insight into the predominant liquid phase cation–anion interactions. Among the 12 investigated ILs, we find that four have an excited state that is delocalised across both the cation and the anion, which has implications for any process that depends upon the excited state, for example, radiolysis. Considering the collective experimental and theoretical data, we recommend that ion pairs should be the minimum number of ions used for the calculations of NEXAFS spectra of ILs.

11. NEXAFS spectroscopy of ionic liquids: experiments versus calculations

Author

Fogarty, Richard M., Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Bourne, Richard A., Chamberlain, Thomas W., Vander Hoogerstraete, Tom, Thompson, Paul B.J., Hunt, Patricia A., Besley, Nicholas A., Lovelock, Kevin R.J., Fogarty, Richard M., Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Bourne, Richard A., Chamberlain, Thomas W., Vander Hoogerstraete, Tom, Thompson, Paul B.J., Hunt, Patricia A., Besley, Nicholas A., and Lovelock, Kevin R.J.

Abstract

Experimental near edge X–ray absorption fine structure (NEXAFS) spectra are reported for 12 ionic liquids (ILs) encompassing a range of chemical structures for both the sulfur 1s and nitrogen 1s edges and compared with time–dependent density functional theory (TD–DFT) calculations. The energy scales for the experimental data were carefully calibrated against literature data. Gas phase calculations were performed on lone ions, ion pairs and ion pair dimers, with a wide range of ion pair conformers considered. For the first time, it is demonstrated that TD–DFT is a suitable method for simulating NEXAFS spectra of ILs, although the number of ions included in the calculations and their conformations are important considerations. For most of the ILs studied, calculations on lone ions in the gas phase were sufficient to successfully reproduce the experimental NEXAFS spectra. However, for certain ILs – for example, those containing a protic ammonium cation –calculations on ion pairs were required to obtain a good agreement with experimental spectra. Furthermore, significant conformational dependence was observed for the protic ammonium ILs, providing insight into the predominant liquid phase cation–anion interactions. Among the 12 investigated ILs, we find that four have an excited state that is delocalised across both the cation and the anion, which has implications for any process that depends upon the excited state, for example, radiolysis. Considering the collective experimental and theoretical data, we recommend that ion pairs should be the minimum number of ions used for the calculations of NEXAFS spectra of ILs.

12. NEXAFS spectroscopy of ionic liquids: experiments versus calculations

Author

Fogarty, Richard M., Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Bourne, Richard A., Chamberlain, Thomas W., Vander Hoogerstraete, Tom, Thompson, Paul B.J., Hunt, Patricia A., Besley, Nicholas A., Lovelock, Kevin R.J., Fogarty, Richard M., Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Bourne, Richard A., Chamberlain, Thomas W., Vander Hoogerstraete, Tom, Thompson, Paul B.J., Hunt, Patricia A., Besley, Nicholas A., and Lovelock, Kevin R.J.

Abstract

Experimental near edge X–ray absorption fine structure (NEXAFS) spectra are reported for 12 ionic liquids (ILs) encompassing a range of chemical structures for both the sulfur 1s and nitrogen 1s edges and compared with time–dependent density functional theory (TD–DFT) calculations. The energy scales for the experimental data were carefully calibrated against literature data. Gas phase calculations were performed on lone ions, ion pairs and ion pair dimers, with a wide range of ion pair conformers considered. For the first time, it is demonstrated that TD–DFT is a suitable method for simulating NEXAFS spectra of ILs, although the number of ions included in the calculations and their conformations are important considerations. For most of the ILs studied, calculations on lone ions in the gas phase were sufficient to successfully reproduce the experimental NEXAFS spectra. However, for certain ILs – for example, those containing a protic ammonium cation –calculations on ion pairs were required to obtain a good agreement with experimental spectra. Furthermore, significant conformational dependence was observed for the protic ammonium ILs, providing insight into the predominant liquid phase cation–anion interactions. Among the 12 investigated ILs, we find that four have an excited state that is delocalised across both the cation and the anion, which has implications for any process that depends upon the excited state, for example, radiolysis. Considering the collective experimental and theoretical data, we recommend that ion pairs should be the minimum number of ions used for the calculations of NEXAFS spectra of ILs.

13. NEXAFS spectroscopy of ionic liquids: experiments versus calculations

Author

Fogarty, Richard M., Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Bourne, Richard A., Chamberlain, Thomas W., Vander Hoogerstraete, Tom, Thompson, Paul B.J., Hunt, Patricia A., Besley, Nicholas A., Lovelock, Kevin R.J., Fogarty, Richard M., Matthews, Richard P., Clough, Matthew T., Ashworth, Claire R., Brandt, Agnieszka, Corbett, Paul J., Palgrave, Robert G., Bourne, Richard A., Chamberlain, Thomas W., Vander Hoogerstraete, Tom, Thompson, Paul B.J., Hunt, Patricia A., Besley, Nicholas A., and Lovelock, Kevin R.J.

Abstract

Experimental near edge X–ray absorption fine structure (NEXAFS) spectra are reported for 12 ionic liquids (ILs) encompassing a range of chemical structures for both the sulfur 1s and nitrogen 1s edges and compared with time–dependent density functional theory (TD–DFT) calculations. The energy scales for the experimental data were carefully calibrated against literature data. Gas phase calculations were performed on lone ions, ion pairs and ion pair dimers, with a wide range of ion pair conformers considered. For the first time, it is demonstrated that TD–DFT is a suitable method for simulating NEXAFS spectra of ILs, although the number of ions included in the calculations and their conformations are important considerations. For most of the ILs studied, calculations on lone ions in the gas phase were sufficient to successfully reproduce the experimental NEXAFS spectra. However, for certain ILs – for example, those containing a protic ammonium cation –calculations on ion pairs were required to obtain a good agreement with experimental spectra. Furthermore, significant conformational dependence was observed for the protic ammonium ILs, providing insight into the predominant liquid phase cation–anion interactions. Among the 12 investigated ILs, we find that four have an excited state that is delocalised across both the cation and the anion, which has implications for any process that depends upon the excited state, for example, radiolysis. Considering the collective experimental and theoretical data, we recommend that ion pairs should be the minimum number of ions used for the calculations of NEXAFS spectra of ILs.