Valorization of polysaccharides using alternative solvents
Autor(a) principal: | |
---|---|
Data de Publicação: | 2022 |
Idioma: | eng |
Título da fonte: | Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) |
Texto Completo: | http://hdl.handle.net/10773/34081 |
Resumo: | Sustainable development is one of the major concerns of society and of the scientific community presently. These concerns have led to new legislation by the European Union and United Nations focusing on the development of sustainable processes, mostly using greener solvents and renewable feedstocks as well as the implementation of a circular economy. In this sense, it is predicted that the share of bio-based chemicals will exponentially increase in the coming years through the valorization of biomass resources. Moreover, waste management is also a crucial point to achieve Circular Economy. Biomass represents thus a promising source for chemicals and materials. Nonetheless, the use of this feedstock must be carefully planned to be sustainable. To achieve a sustainable exploitation of biomass the use of biorefineries is key. Biorefineries are integrated systems of sustainable technologies for the comprehensive utilization and exploitation of biological raw materials. From the various types of available biomass, lignocellulosic feedstocks present the highest abundance with large quantities of the feedstock being wasted in pulp and paper manufacture and agro-based processes. This feedstock is however very complex, being composed of three main fractions: cellulose, hemicelluloses and lignin. The first two fractions are polysaccharides which can be used to produce new and innovative materials, chemicals and biofuels. Even so, there is a need for more efficient and sustainable use of these biomass fractions. Having these issues in mind, the main aim of this thesis is to explore the valorization of polysaccharides using alternative solvents, such as deep eutectic solvents (DES). The major fraction of the work was focused on the valorization of xylans which compose the majority of hemicelluloses fraction in lignocellulosic biomass. The initial work focused on the dissolution and extraction of these polysaccharides. In this study, the DES [Ch]Cl:Urea was able to solubilize a maximum of 328.23 g/L of xylans using 66.7 wt.% DES in water at 80°C. Moreover, xylans could be recovered easily from the DES by precipitation with yields above 90% while maintaining their main structural features intact. This DES also demonstrated the capability to selectively extract xylans from E. globulus wood which is key for a possible application in a biorefinery context. The next studies focused on the production of chemicals directly from this xylan, namely xylitol and furfural. Xylitol production was achieved through the simultaneous saccharification and fermentation of the xylans dissolved in the previous developed DES system, taking advantage of the mild extraction conditions to achieve a one step process. In this study, 66.04% of xylitol yield was attained using an aqueous solution of 20 wt.% of [Ch]Cl:Urea in the molar ratio of 1:1. Furfural production was explored focusing also on a one-step process. This was achieved through the design of a dual function DES, having the role of both solvent and catalyst. Through the use of the [Ch]Cl:Malic Acid (1:3) with 5 wt.% of water a novel and faster process was developed for furfural production. Moreover, the use of the bio-based solvent γ-valerolactone (GVL) allowed for a maximum furfural yield of 75% with 2.5 min of reaction time using microwave-assisted reactions, at 150 °C, at a S/L ratio of 0.050, and GVL at a weight ratio of 1:2 with the DES system. Furfural was also recovered after production through the use of the bio-based solvent 2-methyltetrahydrofuran (2-MeTHF) and the DES was re-used achieving a fully developed process. Then, the use of alkali metal salts was evaluated in the previous DES system composed of [Ch]Cl:Malic acid (1:3), and it was found that the use of these salts could highly influence the furfural yields attained. The use of LiBr allowed for a sharp increase in furfural yields without the need of GVL. A maximum furfural yield of 89.46% was achieved using 8.19% of LiBr in [Ch]Cl:Mal, 1:3; 5 wt.% water, at 157.3 °C and 1.74 min of reaction time. The final study regarding furfural production focused on the use of acidic-based aqueous biphasic systems (AcABS) for the simultaneous furfural production and separation. The aqueous biphasis system used was composed of the ionic liquid (IL) tributyltetradecylphosphonium chloride ([P444(14)]Cl) and hydrochloric acid (HCl), the latter acting both as a catalyst and phase-forming agent. Though the optimization of this process using microwave-assisted reactions, a maximum furfural yield of 78.8% and an extraction efficiency to the IL-rich phase of 85.5% were attained in 1 min in the microwave reactor, at 140 °C and 0.05 S/L ratio, with the ABS formed by 30 wt.% IL and 6.5 wt.% HCl. The use of this ABS also allowed for an easy re-use of the IL and recovery of furfural. The next study approached in this project had the goal of evaluating the feasibility of DES systems proposed in literature for biorefinery purposes, such as biomass delignification. When proposing these types of systems, to be used in whole biomass, it is crucial to understand the effect of the solvent and process on all the biomass fractions. Therefore, a comprehensive analysis was made to the DES system composed of [Ch]Cl:Lactic acid (1:10) proposed in literature for biomass delignification and its effect on the carbohydrate fractions. This study showed that esterification of cellulose occurs and that xylans are hydrolyzed into xylose and dehydrated into furfural, especially for higher treatment times. The last process approached in this thesis was focused on the production of 5-hyroxymethilfurfural (5-HMF), a valuable platform chemical. Herein, and similarly to the production of furfural in a one-step process, the acidic DES [Ch]Cl:Citric acid was used in the molar ratio of 1:1 to produce 5-HMF from fructose. The best 5-HMF yield attained after optimization was 82.4 % and was achieved at 130°C, in 4 min of reaction time with microwave, and with the addition of 10 wt.% of GVL. The recycling of the solvent and product recovery was carried out in a similar fashion revealing the versatility of the developed recovery process for a large array of furan compounds. In sum, this thesis demonstrates the potential of alternative solvents in the valorization of polysaccharide feeds. The different developed processes present a sustainable and more efficient alternative to the conventional processes in place, thus representing an important step in the paradigm shift to a circular economy and a more sustainable and holistic exploitation of biomass. |
id |
RCAP_91beee76d238d7a6292192bc5959a664 |
---|---|
oai_identifier_str |
oai:ria.ua.pt:10773/34081 |
network_acronym_str |
RCAP |
network_name_str |
Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) |
repository_id_str |
7160 |
spelling |
Valorization of polysaccharides using alternative solventsPolysaccharidesAlternative solventsXylansFuransAcidic catalysisDissolutionExtractionDeep eutectic solventsIonic liquidsSustainable development is one of the major concerns of society and of the scientific community presently. These concerns have led to new legislation by the European Union and United Nations focusing on the development of sustainable processes, mostly using greener solvents and renewable feedstocks as well as the implementation of a circular economy. In this sense, it is predicted that the share of bio-based chemicals will exponentially increase in the coming years through the valorization of biomass resources. Moreover, waste management is also a crucial point to achieve Circular Economy. Biomass represents thus a promising source for chemicals and materials. Nonetheless, the use of this feedstock must be carefully planned to be sustainable. To achieve a sustainable exploitation of biomass the use of biorefineries is key. Biorefineries are integrated systems of sustainable technologies for the comprehensive utilization and exploitation of biological raw materials. From the various types of available biomass, lignocellulosic feedstocks present the highest abundance with large quantities of the feedstock being wasted in pulp and paper manufacture and agro-based processes. This feedstock is however very complex, being composed of three main fractions: cellulose, hemicelluloses and lignin. The first two fractions are polysaccharides which can be used to produce new and innovative materials, chemicals and biofuels. Even so, there is a need for more efficient and sustainable use of these biomass fractions. Having these issues in mind, the main aim of this thesis is to explore the valorization of polysaccharides using alternative solvents, such as deep eutectic solvents (DES). The major fraction of the work was focused on the valorization of xylans which compose the majority of hemicelluloses fraction in lignocellulosic biomass. The initial work focused on the dissolution and extraction of these polysaccharides. In this study, the DES [Ch]Cl:Urea was able to solubilize a maximum of 328.23 g/L of xylans using 66.7 wt.% DES in water at 80°C. Moreover, xylans could be recovered easily from the DES by precipitation with yields above 90% while maintaining their main structural features intact. This DES also demonstrated the capability to selectively extract xylans from E. globulus wood which is key for a possible application in a biorefinery context. The next studies focused on the production of chemicals directly from this xylan, namely xylitol and furfural. Xylitol production was achieved through the simultaneous saccharification and fermentation of the xylans dissolved in the previous developed DES system, taking advantage of the mild extraction conditions to achieve a one step process. In this study, 66.04% of xylitol yield was attained using an aqueous solution of 20 wt.% of [Ch]Cl:Urea in the molar ratio of 1:1. Furfural production was explored focusing also on a one-step process. This was achieved through the design of a dual function DES, having the role of both solvent and catalyst. Through the use of the [Ch]Cl:Malic Acid (1:3) with 5 wt.% of water a novel and faster process was developed for furfural production. Moreover, the use of the bio-based solvent γ-valerolactone (GVL) allowed for a maximum furfural yield of 75% with 2.5 min of reaction time using microwave-assisted reactions, at 150 °C, at a S/L ratio of 0.050, and GVL at a weight ratio of 1:2 with the DES system. Furfural was also recovered after production through the use of the bio-based solvent 2-methyltetrahydrofuran (2-MeTHF) and the DES was re-used achieving a fully developed process. Then, the use of alkali metal salts was evaluated in the previous DES system composed of [Ch]Cl:Malic acid (1:3), and it was found that the use of these salts could highly influence the furfural yields attained. The use of LiBr allowed for a sharp increase in furfural yields without the need of GVL. A maximum furfural yield of 89.46% was achieved using 8.19% of LiBr in [Ch]Cl:Mal, 1:3; 5 wt.% water, at 157.3 °C and 1.74 min of reaction time. The final study regarding furfural production focused on the use of acidic-based aqueous biphasic systems (AcABS) for the simultaneous furfural production and separation. The aqueous biphasis system used was composed of the ionic liquid (IL) tributyltetradecylphosphonium chloride ([P444(14)]Cl) and hydrochloric acid (HCl), the latter acting both as a catalyst and phase-forming agent. Though the optimization of this process using microwave-assisted reactions, a maximum furfural yield of 78.8% and an extraction efficiency to the IL-rich phase of 85.5% were attained in 1 min in the microwave reactor, at 140 °C and 0.05 S/L ratio, with the ABS formed by 30 wt.% IL and 6.5 wt.% HCl. The use of this ABS also allowed for an easy re-use of the IL and recovery of furfural. The next study approached in this project had the goal of evaluating the feasibility of DES systems proposed in literature for biorefinery purposes, such as biomass delignification. When proposing these types of systems, to be used in whole biomass, it is crucial to understand the effect of the solvent and process on all the biomass fractions. Therefore, a comprehensive analysis was made to the DES system composed of [Ch]Cl:Lactic acid (1:10) proposed in literature for biomass delignification and its effect on the carbohydrate fractions. This study showed that esterification of cellulose occurs and that xylans are hydrolyzed into xylose and dehydrated into furfural, especially for higher treatment times. The last process approached in this thesis was focused on the production of 5-hyroxymethilfurfural (5-HMF), a valuable platform chemical. Herein, and similarly to the production of furfural in a one-step process, the acidic DES [Ch]Cl:Citric acid was used in the molar ratio of 1:1 to produce 5-HMF from fructose. The best 5-HMF yield attained after optimization was 82.4 % and was achieved at 130°C, in 4 min of reaction time with microwave, and with the addition of 10 wt.% of GVL. The recycling of the solvent and product recovery was carried out in a similar fashion revealing the versatility of the developed recovery process for a large array of furan compounds. In sum, this thesis demonstrates the potential of alternative solvents in the valorization of polysaccharide feeds. The different developed processes present a sustainable and more efficient alternative to the conventional processes in place, thus representing an important step in the paradigm shift to a circular economy and a more sustainable and holistic exploitation of biomass.O desenvolvimento sustentável é uma das grandes preocupações da sociedade e da comunidade científica. Este tópico deu origem a nova legislação pela União Europeia e Nações Unidas focando-se no desenvolvimento de processos sustentáveis, maioritariamente através do uso de matérias-primas mais verdes assim como na implementação da Economia Circular. Neste sentido, é previsto que a fração de químicos derivados de fontes biológicas aumente exponencialmente nos próximos anos através da valorização da biomassa. Adicionalmente, a gestão de desperdício é também crucial para alcançar Bioeconomia Circular. A biomassa representa uma fonte promissora de químicos e materiais, no entanto, o uso desta matéria-prima deve ser planeado cuidadosamente para ser sustentável. Neste sentido, a utilização de biorefinarias é essencial. Estas são sistemas sustentáveis integrados que utilizam tecnologias amigas do ambiente para a utilização holística das matérias-primas biológicas. Dos vários tipos de biomassa disponível, a biomassa lenhocelulósica é a mais abundante e que apresenta grandes desperdícios, nomeadamente no fabrico da pasta de papel e em processos agrícolas. Por outro lado, esta matéria-prima tem um elevado grau de complexidade, sendo dividida em três grandes frações: celulose, hemiceluloses e lenhina. As primeiras duas frações mencionadas correspondem a polissacarídeos que podem ser utilizados para produzir novos materiais inovadores, químicos e biocombustíveis. Assim sendo é necessário o desenvolvimento de processes mais eficientes e sustentáveis para a utilização destas frações da biomassa. Tendo em conta as problemáticas apresentadas, o objetivo desta tese é explorar a valorização de polissacarídeos utilizando solventes alternativos como o caso dos solventes eutécticos profundos (DES). A maioria do trabalho desenvolvido focou-se na valorização de xilanas, que compõem a fração de grande parte das hemiceluloses na biomassa lenhocelulósica. Neste sentido, o primeiro trabalho centrou-se na dissolução e extração destes polissacarídeos. Neste estudo, o DES [Ch]Cl:Ureia, na composição 66,7 (m/m)% de DES em água a 80°C solubilizou 328,23 g/L de xilanas. Adicionalmente, as xilanas foram recuperadas facilmente do DES através de precipitação com rendimentos acima dos 90% mantendo as suas características estruturais intactas. Este trabalho demonstrou ainda a capacidade do DES para extrair seletivamente as xilanas da madeira de E. globulus, o que é um aspeto determinante na sua aplicação num contexto de biorefinaria. Os trabalhos seguintes focaram-se na produção de químicos diretamente de xilanas, nomeadamente xilitol e furfural. A produção de xilitol foi conseguida através de fermentação e sacarificação simultânea das xilanas previamente dissolvidas no sistema de DES desenvolvido no primeiro trabalho, tomando assim partido das condições moderadas da extração para obter um processo de um único passo. Assim sendo, neste estudo, foi obtido um rendimento de xilitol de 66,04% utilizando uma solução aquosa contendo 20 (m/m)% de [Ch]Cl:Urea num razão molar de 1:1. A produção de furfural foi também explorada com o objetivo de desenvolver um processo de um único passo. Isto foi possível através da utilização de DES com dupla função, desempenhando assim o papel de solvente e catalisador. Um processos novo e mais rápido foi assim desenvolvido através da utilização de [Ch]Cl:Ácido Málico (1:3) com 5 wt.% de água, para a produção de furfural. Além de mais, a utilização do solvente gamavalerolactona (GVL), derivado de fontes naturais permitiu um aumento do rendimento até 75% em 2,5 min de reação, a 150°C, com um razão S/L de 0,05 e com um razão 1:2 (m:m) GVL:DES. O furfural foi também recuperado após produção através da extração com o solvente 2-metiltetrahidrofurano (2-MeTHF), sendo o DES reutilizado, resultando num processo completamente desenvolvido. Seguidamente, a adição de sais alcalinos metálicos ao sistema desenvolvido anteriormente, composto por [Ch]Cl:Ácido Málico, foi investigado. Neste estudo foi observado que o uso destes sais tem uma grande influência nos rendimentos de furfural obtidos. O uso do sal LiBr resultou num aumento significativo do rendimento sem ser necessário o uso de GVL. Um rendimento máximo de 89,46% foi obtido com 8,19% de LiBr em [Ch]Cl:Mal, 1:3; 5 (m/m)% água, 157,3 °C e1,74 min de tempo de reação. O último estudo relativo à produção de furfural centrou-se na utilização de sistemas aquosos bifásicos baseados em ácidos (AcABS) para a produção e separação simultânea do furfural. O ABS utilizado é constituído pelo liquido iónico (IL) cloreto de tributiltetradecilfosfónio ([P444(14)]Cl) e ácido clorídrico (HCl) tendo este a função de catalisador e agente formador de fase. Através da otimização deste processo, utilizando reações assistidas por microondas, foi possível obter um rendimento de furfural de 78,8% e uma eficiência de extração para a fase rica em IL de 85,5% com as seguintes condições: 1 min de reação, 140 °C e 0,05 de razão S/L, com o ABS formado por 30 (m/m)% de IL e 6,5 (m/m)% de HCl. O uso deste ABS permitiu ainda a fácil reutilização do IL e recuperação do furfural. O estudo seguinte focou-se na avaliação da viabilidade do uso dos sistemas compostos por DES propostos na literatura para processos de biorefinaria, como o caso da deslenhificação da biomassa. Quando estes sistemas são propostos para utilização na biomassa é crucial compreender o efeito dos solventes e do processo em todas as frações. Neste sentido, uma análise compreensiva foi feita ao sistema composto pelo DES [Ch]Cl:Ácido Lático (1:10) proposto na literatura para a deslenhificação da biomassa. Este estudo veio assim demonstrar que reações de esterificação ocorrem na fração de celulose e que as xilanas são hidrolisadas obtendo-se xilose e desidratadas em furfural, especialmente para tempos de tratamento mais longos. O último processo desenvolvido nesta tese focou-se na produção de 5-hidroximetilfurfural (5-HMF), um químico de plataforma valioso. Neste trabalho, e similarmente ao caso do furfural, um DES acídico, [Ch]Cl:Ácido Citrico (1:1) foi usado para produzir 5-HMF a partir da frutose. O melhor rendimento obtido foi de 82,4% a 130°C, com 4,0 min de reação em micro-ondas com a adição de 10 (m/m)% de GVL. A reutilização do solvente e recuperação do produto foram feitas de forma similar aos processos previamente desenvolvidos, revelando a versatilidade do processo de recuperação para vários tipos de furanos. Em suma, esta tese demonstra o potencial dos solventes alternativos na valorização dos polissacarídeos. Os diferentes tipos de processos desenvolvidos são uma alternativa mais sustentável e eficiente aos processos convencionais aplicados, representando assim um passo importante na mudança de paradigma para uma economia circular e para uma exploração mais holística e sustentável da biomassa.2022-06-29T09:57:05Z2022-04-21T00:00:00Z2022-04-21doctoral thesisinfo:eu-repo/semantics/publishedVersionapplication/pdfhttp://hdl.handle.net/10773/34081engMorais, Eduarda Serrainfo:eu-repo/semantics/openAccessreponame:Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos)instname:Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informaçãoinstacron:RCAAP2024-05-06T04:38:07Zoai:ria.ua.pt:10773/34081Portal AgregadorONGhttps://www.rcaap.pt/oai/openairemluisa.alvim@gmail.comopendoar:71602024-05-06T04:38:07Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) - Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informaçãofalse |
dc.title.none.fl_str_mv |
Valorization of polysaccharides using alternative solvents |
title |
Valorization of polysaccharides using alternative solvents |
spellingShingle |
Valorization of polysaccharides using alternative solvents Morais, Eduarda Serra Polysaccharides Alternative solvents Xylans Furans Acidic catalysis Dissolution Extraction Deep eutectic solvents Ionic liquids |
title_short |
Valorization of polysaccharides using alternative solvents |
title_full |
Valorization of polysaccharides using alternative solvents |
title_fullStr |
Valorization of polysaccharides using alternative solvents |
title_full_unstemmed |
Valorization of polysaccharides using alternative solvents |
title_sort |
Valorization of polysaccharides using alternative solvents |
author |
Morais, Eduarda Serra |
author_facet |
Morais, Eduarda Serra |
author_role |
author |
dc.contributor.author.fl_str_mv |
Morais, Eduarda Serra |
dc.subject.por.fl_str_mv |
Polysaccharides Alternative solvents Xylans Furans Acidic catalysis Dissolution Extraction Deep eutectic solvents Ionic liquids |
topic |
Polysaccharides Alternative solvents Xylans Furans Acidic catalysis Dissolution Extraction Deep eutectic solvents Ionic liquids |
description |
Sustainable development is one of the major concerns of society and of the scientific community presently. These concerns have led to new legislation by the European Union and United Nations focusing on the development of sustainable processes, mostly using greener solvents and renewable feedstocks as well as the implementation of a circular economy. In this sense, it is predicted that the share of bio-based chemicals will exponentially increase in the coming years through the valorization of biomass resources. Moreover, waste management is also a crucial point to achieve Circular Economy. Biomass represents thus a promising source for chemicals and materials. Nonetheless, the use of this feedstock must be carefully planned to be sustainable. To achieve a sustainable exploitation of biomass the use of biorefineries is key. Biorefineries are integrated systems of sustainable technologies for the comprehensive utilization and exploitation of biological raw materials. From the various types of available biomass, lignocellulosic feedstocks present the highest abundance with large quantities of the feedstock being wasted in pulp and paper manufacture and agro-based processes. This feedstock is however very complex, being composed of three main fractions: cellulose, hemicelluloses and lignin. The first two fractions are polysaccharides which can be used to produce new and innovative materials, chemicals and biofuels. Even so, there is a need for more efficient and sustainable use of these biomass fractions. Having these issues in mind, the main aim of this thesis is to explore the valorization of polysaccharides using alternative solvents, such as deep eutectic solvents (DES). The major fraction of the work was focused on the valorization of xylans which compose the majority of hemicelluloses fraction in lignocellulosic biomass. The initial work focused on the dissolution and extraction of these polysaccharides. In this study, the DES [Ch]Cl:Urea was able to solubilize a maximum of 328.23 g/L of xylans using 66.7 wt.% DES in water at 80°C. Moreover, xylans could be recovered easily from the DES by precipitation with yields above 90% while maintaining their main structural features intact. This DES also demonstrated the capability to selectively extract xylans from E. globulus wood which is key for a possible application in a biorefinery context. The next studies focused on the production of chemicals directly from this xylan, namely xylitol and furfural. Xylitol production was achieved through the simultaneous saccharification and fermentation of the xylans dissolved in the previous developed DES system, taking advantage of the mild extraction conditions to achieve a one step process. In this study, 66.04% of xylitol yield was attained using an aqueous solution of 20 wt.% of [Ch]Cl:Urea in the molar ratio of 1:1. Furfural production was explored focusing also on a one-step process. This was achieved through the design of a dual function DES, having the role of both solvent and catalyst. Through the use of the [Ch]Cl:Malic Acid (1:3) with 5 wt.% of water a novel and faster process was developed for furfural production. Moreover, the use of the bio-based solvent γ-valerolactone (GVL) allowed for a maximum furfural yield of 75% with 2.5 min of reaction time using microwave-assisted reactions, at 150 °C, at a S/L ratio of 0.050, and GVL at a weight ratio of 1:2 with the DES system. Furfural was also recovered after production through the use of the bio-based solvent 2-methyltetrahydrofuran (2-MeTHF) and the DES was re-used achieving a fully developed process. Then, the use of alkali metal salts was evaluated in the previous DES system composed of [Ch]Cl:Malic acid (1:3), and it was found that the use of these salts could highly influence the furfural yields attained. The use of LiBr allowed for a sharp increase in furfural yields without the need of GVL. A maximum furfural yield of 89.46% was achieved using 8.19% of LiBr in [Ch]Cl:Mal, 1:3; 5 wt.% water, at 157.3 °C and 1.74 min of reaction time. The final study regarding furfural production focused on the use of acidic-based aqueous biphasic systems (AcABS) for the simultaneous furfural production and separation. The aqueous biphasis system used was composed of the ionic liquid (IL) tributyltetradecylphosphonium chloride ([P444(14)]Cl) and hydrochloric acid (HCl), the latter acting both as a catalyst and phase-forming agent. Though the optimization of this process using microwave-assisted reactions, a maximum furfural yield of 78.8% and an extraction efficiency to the IL-rich phase of 85.5% were attained in 1 min in the microwave reactor, at 140 °C and 0.05 S/L ratio, with the ABS formed by 30 wt.% IL and 6.5 wt.% HCl. The use of this ABS also allowed for an easy re-use of the IL and recovery of furfural. The next study approached in this project had the goal of evaluating the feasibility of DES systems proposed in literature for biorefinery purposes, such as biomass delignification. When proposing these types of systems, to be used in whole biomass, it is crucial to understand the effect of the solvent and process on all the biomass fractions. Therefore, a comprehensive analysis was made to the DES system composed of [Ch]Cl:Lactic acid (1:10) proposed in literature for biomass delignification and its effect on the carbohydrate fractions. This study showed that esterification of cellulose occurs and that xylans are hydrolyzed into xylose and dehydrated into furfural, especially for higher treatment times. The last process approached in this thesis was focused on the production of 5-hyroxymethilfurfural (5-HMF), a valuable platform chemical. Herein, and similarly to the production of furfural in a one-step process, the acidic DES [Ch]Cl:Citric acid was used in the molar ratio of 1:1 to produce 5-HMF from fructose. The best 5-HMF yield attained after optimization was 82.4 % and was achieved at 130°C, in 4 min of reaction time with microwave, and with the addition of 10 wt.% of GVL. The recycling of the solvent and product recovery was carried out in a similar fashion revealing the versatility of the developed recovery process for a large array of furan compounds. In sum, this thesis demonstrates the potential of alternative solvents in the valorization of polysaccharide feeds. The different developed processes present a sustainable and more efficient alternative to the conventional processes in place, thus representing an important step in the paradigm shift to a circular economy and a more sustainable and holistic exploitation of biomass. |
publishDate |
2022 |
dc.date.none.fl_str_mv |
2022-06-29T09:57:05Z 2022-04-21T00:00:00Z 2022-04-21 |
dc.type.driver.fl_str_mv |
doctoral thesis |
dc.type.status.fl_str_mv |
info:eu-repo/semantics/publishedVersion |
status_str |
publishedVersion |
dc.identifier.uri.fl_str_mv |
http://hdl.handle.net/10773/34081 |
url |
http://hdl.handle.net/10773/34081 |
dc.language.iso.fl_str_mv |
eng |
language |
eng |
dc.rights.driver.fl_str_mv |
info:eu-repo/semantics/openAccess |
eu_rights_str_mv |
openAccess |
dc.format.none.fl_str_mv |
application/pdf |
dc.source.none.fl_str_mv |
reponame:Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) instname:Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informação instacron:RCAAP |
instname_str |
Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informação |
instacron_str |
RCAAP |
institution |
RCAAP |
reponame_str |
Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) |
collection |
Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) |
repository.name.fl_str_mv |
Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) - Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informação |
repository.mail.fl_str_mv |
mluisa.alvim@gmail.com |
_version_ |
1817543814516047872 |