Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by Impregnation

Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by Impregnation

In the present study, the use of Sn-Beta zeolite to facilitate the conversion of lignocellulosic biomass-derived glucose and xylose into lactic and levulinic acid was explored. The reactions were carried out in a batch reactor using water as the solvent. Water is the preferred solvent over methanol...

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Main Authors: Andrew Kohler, Wayne Seames, Ian Foerster, Clancy Kadrmas
Format: Article
Language:English
Published: MDPI AG 2020-10-01
Series:Catalysts
Subjects:
Sn-Beta
calcium sulfate
corn stover
forage sorghum
glucose
xylose
Online Access:https://www.mdpi.com/2073-4344/10/10/1219
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spelling doaj-07908df072c34e3f87135708891fbcd82020-11-25T03:38:45ZengMDPI AGCatalysts2073-43442020-10-01101219121910.3390/catal10101219Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by ImpregnationAndrew Kohler0Wayne Seames1Ian Foerster2Clancy Kadrmas3Department of Chemical Engineering, University of North Dakota, Grand Forks, ND 58202, USADepartment of Chemical Engineering, University of North Dakota, Grand Forks, ND 58202, USADepartment of Chemical Engineering, University of North Dakota, Grand Forks, ND 58202, USADepartment of Chemical Engineering, University of North Dakota, Grand Forks, ND 58202, USAIn the present study, the use of Sn-Beta zeolite to facilitate the conversion of lignocellulosic biomass-derived glucose and xylose into lactic and levulinic acid was explored. The reactions were carried out in a batch reactor using water as the solvent. Water is the preferred solvent over methanol as it reduces downstream product acid recovery and purification complexity. Optimization experiments were performed for reaction temperature and residence time. Under optimized reaction conditions, the Sn-Beta facilitated reaction of a pure sugar solution resulted in lactic acid yields of 13 and 19 wt% of inlet carbon of glucose and xylose, respectively, plus levulinic acid yields of 18 and 0.8 wt%, respectively. When actual biomass-derived sugar solutions were tested, the yields of lactic acid were significantly higher than those from the optimized model solution experiments with lactic acid yields of 34 wt%. These biomass-derived sugar solutions contained residual levels of CaSO<sub>4</sub> from the neutralization step of the hydrolysis process. Further experiments were performed to examine the potential effects from CaSO<sub>4</sub> contributing to this increase. It was found that the sulfate ions increased the Brønsted basicity and the calcium increased the Lewis acidity of the reaction solution, and that the combination of both effects increased the conversion of the original sugars into lactic acid. These effects were verified by testing other organic bases to isolate the Brønsted acid neutralization effect and the Lewis acid enhancement effect. The addition of CaSO<sub>4</sub> resulted in attractive lactic acid yields, 68 wt% and 50 wt% of inlet carbon from pure glucose and xylose solutions, respectively. Increasing the actual corn stover and forage sorghum derived sugars concentration (in water) allowed lactic acids yields of greater than 60 wt% to be achieved. When the optimized Sn-Beta reaction system was applied to corn stover and forage sorghum mixtures, it was found that the ratio of lactic-to-levulinic acid generated was inversely dependent upon the glucose-to-xylose ratio in the recovered sugar mixture.https://www.mdpi.com/2073-4344/10/10/1219Sn-Betacalcium sulfatecorn stoverforage sorghumglucosexylose
collection DOAJ
language English
format Article
sources DOAJ
author Andrew Kohler
Wayne Seames
Ian Foerster
Clancy Kadrmas
spellingShingle Andrew Kohler
Wayne Seames
Ian Foerster
Clancy Kadrmas
Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by Impregnation
Catalysts
Sn-Beta
calcium sulfate
corn stover
forage sorghum
glucose
xylose
author_facet Andrew Kohler
Wayne Seames
Ian Foerster
Clancy Kadrmas
author_sort Andrew Kohler
title Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by Impregnation
title_short Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by Impregnation
title_full Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by Impregnation
title_fullStr Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by Impregnation
title_full_unstemmed Catalytic Formation of Lactic and Levulinic Acids from Biomass Derived Monosaccarides through Sn-Beta Formed by Impregnation
title_sort catalytic formation of lactic and levulinic acids from biomass derived monosaccarides through sn-beta formed by impregnation
publisher MDPI AG
series Catalysts
issn 2073-4344
publishDate 2020-10-01
description In the present study, the use of Sn-Beta zeolite to facilitate the conversion of lignocellulosic biomass-derived glucose and xylose into lactic and levulinic acid was explored. The reactions were carried out in a batch reactor using water as the solvent. Water is the preferred solvent over methanol as it reduces downstream product acid recovery and purification complexity. Optimization experiments were performed for reaction temperature and residence time. Under optimized reaction conditions, the Sn-Beta facilitated reaction of a pure sugar solution resulted in lactic acid yields of 13 and 19 wt% of inlet carbon of glucose and xylose, respectively, plus levulinic acid yields of 18 and 0.8 wt%, respectively. When actual biomass-derived sugar solutions were tested, the yields of lactic acid were significantly higher than those from the optimized model solution experiments with lactic acid yields of 34 wt%. These biomass-derived sugar solutions contained residual levels of CaSO<sub>4</sub> from the neutralization step of the hydrolysis process. Further experiments were performed to examine the potential effects from CaSO<sub>4</sub> contributing to this increase. It was found that the sulfate ions increased the Brønsted basicity and the calcium increased the Lewis acidity of the reaction solution, and that the combination of both effects increased the conversion of the original sugars into lactic acid. These effects were verified by testing other organic bases to isolate the Brønsted acid neutralization effect and the Lewis acid enhancement effect. The addition of CaSO<sub>4</sub> resulted in attractive lactic acid yields, 68 wt% and 50 wt% of inlet carbon from pure glucose and xylose solutions, respectively. Increasing the actual corn stover and forage sorghum derived sugars concentration (in water) allowed lactic acids yields of greater than 60 wt% to be achieved. When the optimized Sn-Beta reaction system was applied to corn stover and forage sorghum mixtures, it was found that the ratio of lactic-to-levulinic acid generated was inversely dependent upon the glucose-to-xylose ratio in the recovered sugar mixture.
topic Sn-Beta
calcium sulfate
corn stover
forage sorghum
glucose
xylose
url https://www.mdpi.com/2073-4344/10/10/1219
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