Effect of Poultry Litter Biochar on Saccharomyces cerevisiae Growth and Ethanol Production from Steam-Exploded Poplar and Corn Stover

Diallo, Oumou

01 May 2014

The use of ethanol produced from lignocellulosic biomass for transportation fuel offers solutions in reducing environmental emission and the use of non-renewable fuels. However, lignocellulosic ethanol production is still hampered by economic and technical obstacles. For instance, the inhibitory effect of toxic compounds produced during biomass pretreatment was reported to inhibit the fermenting microorganisms, hence there was a decrease in ethanol yield and productivity. Thus, there is a need to improve the bioconversion of lignocellulosic biomass to ethanol in order to promote its commercialization. The research reported here investigated the use of poultry litter biochar to improve the ethanol production from steam-exploded poplar and corn stover. The effect of poultry litter biochar was first studied on Saccharomyces cerevisiae ATCC 204508/S288C growth, and second on the enzyme hydrolysis and fermentation of two steam-exploded biomasses: (poplar and corn stover). The third part of the study investigated optimal process parameters (biochar loading, biomass loading, and enzyme loading) on the reducing sugars production, and ethanol yield from steam-exploded corn stover. In this study, it has been shown that poultry litter biochar improved the S. cerevisiae growth and ethanol productivity; therefore poultry litter biochar could potentially be used to improve the ethanol production from steam-exploded lignocellulosic biomass.

Effect of Poultry Litter Biochar

Saccharomyces cerevisiae

Growth and Ethanol Production

Steam-exploded Poplar

Corn Stover

Biological Engineering

Combustion characteristics of steam-exploded biomass pellets

Ponce Valle, Maria Gabriela

January 2011

Currently pelletized woody biomass is widely used as a fuel in thermal applications toaccelerate the global transition to renewable energy. Fuel upgrade is one of the key factorsto improve energy conversion processes. Woody biomass can be fractionated into its mainconstituents by steam explosion. Steam-exploded biomass exhibits enhanced heating valueand improves pellet durability. Moreover, there is a significant deviation in thermochemicalbehavior of steam exploded (steam-treated) biomass with respect to the raw material duringpyrolysis. This thesis work concerned combustion characteristics of steam-exploded salix. The steamtreatedmaterial was pelletized and combusted under 21% of oxygen with varying thereactor temperature from 500 to 900°C to study the influence of both surrounding andpretreatment conditions during combustion process. The impact of different pretreatmentseverity factors (Ro) on burning behavior was evaluated: mild (205°C-6min, Ro=3.87),intermediate (205°C-12min, Ro=4.17) and severe (228°C-12min, Ro=4.84). Heterogeneousand homogenous ignition mechanisms were observed, which were dependent on the reactortemperature. The ignition time and devolatilization duration were observed independent onpretreatment severity near 900°C, and slightly influenced near 500°C. Enhanceddevolatilization rate was detected with the increment of Ro from 3.87 to 4.17, whilst themost severe pretreatment conditions (Ro=4.84) weakened biomass reactivity duringdevolatilization. Finally, char reactivity was lowered as a result of the increment ofpretreatment severity.

biomass combustion

pretreatment

steam-exploded pellets

Other Materials Engineering

Annan materialteknik

Wetlaid Cellulose Fiber-Thermoplastic Hybrid Composites - Effects of Lyocell and Steam Exploded Wood Fiber Blends

Johnson, Richard Kwesi

27 July 2004

Fiber hybridization involves the blending of high and low performance fibers in a common matrix to yield a composite with a balance of properties that cannot be achieved by using either fiber alone. In this study, the random wetlay process was used as a compounding method to investigate the effects of fiber hybridization on the mechanical, viscoelastic, and sorption characteristics of steam-exploded wood (SEW) and lyocell (high performance regenerated cellulose) fiber-reinforced polypropylene (PP) composites. The two fiber types were blended in varying proportions within a fixed total fiber content of 50 wt. % and compared with non-hybrid lyocell- and SEW-PP controls. Using PP matrix as basis, it was observed that moduli of all composites generally increased with increasing lyocell concentration, ranging from a minimum 66 % for SP 50 (SEW/PP control) to a maximum 233 % for LP 50 (lyocell/PP control). Ultimate strengths on the other hand, declined for SP 50 but increased with the inclusion of lyocell fibers. Comparisons of hybrid (having 5 - 20 wt % lyocell) with non-hybrid (having 25 - 50 wt. % lyocell) composites revealed a surprisingly greater strength and modulus-building efficiency (by as much as 2.6 times) in the hybrid composites. This observation indicated possible synergism between lyocell and SEW. Analyses of composite property gains as a function of fiber cost also showed greater cost benefits (highest for tensile modulus) in favor of hybridization. The advantages of fiber hybridization on composite properties were again evident under dynamic mechanical analysis where no significant differences in the storage moduli were found between a hybrid composite with 20 wt. % lyocell and a non-hybrid composite with 50 wt. % lyocell loading. Application of the time-temperature superposition principle (TTSP) made it possible to predict storage moduli over extended frequencies for PP and its composites. Comparison of shift factor versus temperature plots revealed decreasing relaxation times of PP with increasing lyocell concentration, which indicated that PP interacted better with lyocell than with SEW fibers. Finally, it was observed from sorption tests that hybrid composites absorbed less moisture than non-hybrid counterparts of either fiber type. The reasons for this observation were not apparent. It is however possible that moisture transport mechanisms within the composites may have been modified as a result of hybridization. / Master of Science

hybrid composites

viscoelastic properties

steam exploded wood

random wetlay process

sorption

lyocell

mechanical properties

Influence of a Biodegradable Litter Amendment on the Pyrolysis of Poultry Litter

Tarrant, Ryan Carl Allen

02 November 2010

The effects of adding a biodegradable litter amendment (AmmoSoak), developed from steam exploded corncobs, to poultry litter prior to pyrolysis on the product yields and qualities were investigated. Mixtures of litter and AmmoSoak were pyrolyzed in a bench-scale fluidized bed reactor. The objective of the second phase was to start-up a pilot-scale fluidized bed reactor unit. The poultry litter had a lower higher heating value (HHV), higher moisture, ash, nitrogen, sulfur, and chlorine contents than AmmoSoak. Analysis of the poultry litter indicated a mixture of volatiles, hemicelluloses, cellulose, lignin, ash, and proteins. AmmoSoak had a simpler composition than the litter; mainly hemicelluloses, cellulose, and lignin. Bench-scale studies indicated that adding AmmoSoak affected the yields and characteristics of the products. Addition of Ammosoak increased the bio-oil and syngas yields and decreased char yields. Adding AmmoSoak to the feed decreased the pH, water contents, initial viscosity, and the rate at which the viscosity increased with time, while densities and HHVs increased. The addition of Ammosoak to poultry litter also increased the carbon and oxygen contents of the boi-oils while nitrogen, hydrogen, sulfur, chlorine and ash contents decreased. A pilot-scale fluidized bed reactor was designed, constructed, installed and investigated for the pyrolysis of poultry litter. Fluidization and thermal equilibrium of the reactor were successfully demonstrated. The reactor was heated by combustion of propane. To ensure complete combustion, the combustion water was collected and compared to the stoichiometric yield. Complete combustion was achieved. Bio-oil yields on the pilot scale were lower than those obtained on the bench-scale pyrolysis unit. The water soluble fractions of the bio-oils were rich in oxygen. Water insoluble fractions were rich in carbon and ash. / Master of Science

Oil Properties

char

Bio-oil

Fast Pyrolysis

Corncob

Steam Exploded

Litter Amendment

Poultry Litter

13C-nmr spectrometry

FT-IR Spectrophotometry

Estudos genéticos e moleculares da produção de celulases e hemicelulases em Aspergillus nidulans e Aspergillus niger / The genetic and molecular studies of cellulase and hemicellulase production in Aspergillus nidulans and Aspergillus niger.

Gouvêa, Paula Fagundes de

31 July 2013

O mundo se depara atualmente com a perspectiva de um significativo aumento na demanda por etanol combustível. O bagaço de cana está entre os maiores subprodutos agroindustriais no Brasil, sendo uma das alternativas na utilização para a produção do etanol de segunda geração. A degradação do bagaço de cana requer a ação de muitas enzimas diferentes que são reguladas transcripcionalmente. Considerando-se que o custo de celulases e hemicelulases contribuem substancialmente no preço do bioetanol, novos estudos visando o entendimento da eficiência e produtividade de celulases são de grande importância. Para entender como melhorar coquetéis de enzimas que podem hidrolizar o bagaço de cana-de-açúcar pré-tratado, uitlizou-se um experimento de genômica para investigar-se quais genes e vias são transcripcionalmente moduladas durante o crescimento de A. niger em bagaço de cana-de-açúcar explodido. Neste trabalho foram identificados genes que codificam celulases e hemicelulases com aumento da expresão durante o crescimento em bagaço de cana-de-açúcar explodido. Foi também realizada a determinação do acúmulo de mRNA de diversos genes que codificam transportadores para verificar se estes eram induzidos por xilose e por depedência de glicose. Foram identificados 18 genes que corresponde a 58% de celulases preditas em A. niger e 21 genes que correponde a 58% de hemicelulases preditas em A. niger os quias foram altamente expressos durante o crescimento em bagaço de cana-de-açúcar explodido. Foi investigado também o papel central realizado pelas proteínas quinases e fosfatases não essenciais (NPKs e NPPs, respectivamente) quando em presença de celulose como fonte de carbono, no sensoriamento do estado energético e na subsequente via de sinalização no fungo filamentoso modelo Aspergillus nidulans. O estudo com A. nidulans identificou 11 quinases e 7 fosfatases não essências, NPKs e NPPs, respectivamente, envolvidas na produção de celulases e em alguns casos, na produção também de hemicelulases. O envolvimento destas NPKs identificadas na resposta induzida por avicel e na desrepressão foram acessados pela análise do transcriptoma da cepa selvagem e por microscopia de fluorescência através da cepa de fusão CreA::GFP expressa no selvagem e no background dos mutantes de NPKs. A ausência das quinases snfA e schA reduziu dramaticamente a resposta transcricional induzida por celulose incluindo a expressão de enzimas hidrolíticas e transportadores, enquanto que a ausência de snfA resultou em uma quase completa modulação gênica induzida por celulose. O mecanismo pelo qual essas duas quinases controlam a transcrição gênica foi identificado, onde os dois mutantes de quinases foram capazes de desbloquear o CreA mediante a repressão catabólica do carbono (CCR), sob condições de desrepressão, como em baixa presença de carbono ou crescimento em celulose. Desta forma, este trabalho abriu novas possibilidades para o entendimento da sacarificação do bagaço de cana-de-açúcar por hidrolases de A. niger e para a construção de coquetéis de enzimas mais eficientes para a obtenção do etanol de segunda geração. Também possibilitou a identificação de muitas quinases e fosfatases envolvidas no sensoriamento do carbono e do estado energético, as quais demonstraram papéis sobrespostos e distintos de snfA e schA na regulação da desrepressão de CreA e na produção de enzimas hidrolíticas em A. nidulans. / The world today is faced with the prospect of a significant increase in demand for fuel ethanol. Sugarcane bagasse is among the largest agro-industrial by-products in Brazil, one of the alternatives in use for the production of second generation ethanol. Degradation of sugarcane bagasse requires the action of many different enzymes which are transcriptionally regulated. Considering that the costs of cellulases and hemicellulases contribute substantially to the price of bioethanol, new studies aimed at understanding and improving cellulase efficiency and productivity are of paramount importance. To understand how to improve enzymatic cocktails that can hydrolyze pretreated sugarcane bagasse, we used a genomics approach to investigate which genes and pathways are transcriptionally modulated during growth of A. niger on steam-exploded sugarcane bagasse. We also sought to determine whether the mRNA accumulation of several steam-exploded sugarcane bagasseinduced genes encoding putative transporters is induced by xylose and dependent on glucose. We identified 18 genes that corresponds to 58% of A. niger predicted cellulases and 21 genes that correspond to 58% of A. niger predicted hemicellulases, that were highly expressed during growth on sugarcane bagasse. The central role performed by nonessential protein kinases (NPK) and phosphatases (NPP) when grown on cellulose as a sole carbon source, in the sensing energetic status and the subsequent signalling pathways was assessed in the model filamentous fungus Aspergillus nidulans. This study identified multiple kinases and phosphatases (NPKs and NPPs, respectively) involved in the sensing of carbon or energetic status, while demonstrating the overlapping and distinct roles of snfA and schA in the regulation of CreA derepression and hydrolytic enzyme production in A.nidulans. The involvement of the identified NPKs in avicel-induced responses and CreA derepression was assessed by genome-wide transcriptomics and fluorescent microscopy of a CreA::GFP fusion proteinexpressed in the wild-type and NPK-deficient mutant backgrounds. The absence of either the schA or snfA kinase dramatically reduced cellulose-induced transcriptional responses including the expression of hydrolytic enzymes and transporters, while the absence snfA resulted in a near complete loss of wild-typecellulose-induced gene modulation. The mechanism by which these two NPKs controlled gene transcription was identified, as neither of NPK-deficient mutants were able to unlock CreA-mediated carbon catabolite repression, under derepressing conditions, such as carbon starvation or growth on cellulose. Our presently reported work opens new possibilities for understanding sugarcane biomass saccharification by A. niger hydrolases and for the construction of more efficient enzymatic cocktails for second-generation bioethanol. This work also enable the identification of multiple kinases and phosphatases involved in the sensing of carbon or energetic status, while demonstrating the overlapping and distinct roles of snfA and schA in the regulation of CreA derepression and hydrolytic enzyme production in A.nidulans.

A. nidulans

A. nidulans

Aspergillus niger

Aspergillus niger

bagaço de cana-de-açúcar explodido

carbon catabolite repression

cellulase

celulase

creA

creA

hemicellulase

hemicelulase

repressão catabólica do carbono

schA

schA.

snfA

snfA

steam-exploded sugarcane bagasse

xilanase

xlnR

xlnR

xylanase

Estudos genéticos e moleculares da produção de celulases e hemicelulases em Aspergillus nidulans e Aspergillus niger / The genetic and molecular studies of cellulase and hemicellulase production in Aspergillus nidulans and Aspergillus niger.

Paula Fagundes de Gouvêa

31 July 2013

O mundo se depara atualmente com a perspectiva de um significativo aumento na demanda por etanol combustível. O bagaço de cana está entre os maiores subprodutos agroindustriais no Brasil, sendo uma das alternativas na utilização para a produção do etanol de segunda geração. A degradação do bagaço de cana requer a ação de muitas enzimas diferentes que são reguladas transcripcionalmente. Considerando-se que o custo de celulases e hemicelulases contribuem substancialmente no preço do bioetanol, novos estudos visando o entendimento da eficiência e produtividade de celulases são de grande importância. Para entender como melhorar coquetéis de enzimas que podem hidrolizar o bagaço de cana-de-açúcar pré-tratado, uitlizou-se um experimento de genômica para investigar-se quais genes e vias são transcripcionalmente moduladas durante o crescimento de A. niger em bagaço de cana-de-açúcar explodido. Neste trabalho foram identificados genes que codificam celulases e hemicelulases com aumento da expresão durante o crescimento em bagaço de cana-de-açúcar explodido. Foi também realizada a determinação do acúmulo de mRNA de diversos genes que codificam transportadores para verificar se estes eram induzidos por xilose e por depedência de glicose. Foram identificados 18 genes que corresponde a 58% de celulases preditas em A. niger e 21 genes que correponde a 58% de hemicelulases preditas em A. niger os quias foram altamente expressos durante o crescimento em bagaço de cana-de-açúcar explodido. Foi investigado também o papel central realizado pelas proteínas quinases e fosfatases não essenciais (NPKs e NPPs, respectivamente) quando em presença de celulose como fonte de carbono, no sensoriamento do estado energético e na subsequente via de sinalização no fungo filamentoso modelo Aspergillus nidulans. O estudo com A. nidulans identificou 11 quinases e 7 fosfatases não essências, NPKs e NPPs, respectivamente, envolvidas na produção de celulases e em alguns casos, na produção também de hemicelulases. O envolvimento destas NPKs identificadas na resposta induzida por avicel e na desrepressão foram acessados pela análise do transcriptoma da cepa selvagem e por microscopia de fluorescência através da cepa de fusão CreA::GFP expressa no selvagem e no background dos mutantes de NPKs. A ausência das quinases snfA e schA reduziu dramaticamente a resposta transcricional induzida por celulose incluindo a expressão de enzimas hidrolíticas e transportadores, enquanto que a ausência de snfA resultou em uma quase completa modulação gênica induzida por celulose. O mecanismo pelo qual essas duas quinases controlam a transcrição gênica foi identificado, onde os dois mutantes de quinases foram capazes de desbloquear o CreA mediante a repressão catabólica do carbono (CCR), sob condições de desrepressão, como em baixa presença de carbono ou crescimento em celulose. Desta forma, este trabalho abriu novas possibilidades para o entendimento da sacarificação do bagaço de cana-de-açúcar por hidrolases de A. niger e para a construção de coquetéis de enzimas mais eficientes para a obtenção do etanol de segunda geração. Também possibilitou a identificação de muitas quinases e fosfatases envolvidas no sensoriamento do carbono e do estado energético, as quais demonstraram papéis sobrespostos e distintos de snfA e schA na regulação da desrepressão de CreA e na produção de enzimas hidrolíticas em A. nidulans. / The world today is faced with the prospect of a significant increase in demand for fuel ethanol. Sugarcane bagasse is among the largest agro-industrial by-products in Brazil, one of the alternatives in use for the production of second generation ethanol. Degradation of sugarcane bagasse requires the action of many different enzymes which are transcriptionally regulated. Considering that the costs of cellulases and hemicellulases contribute substantially to the price of bioethanol, new studies aimed at understanding and improving cellulase efficiency and productivity are of paramount importance. To understand how to improve enzymatic cocktails that can hydrolyze pretreated sugarcane bagasse, we used a genomics approach to investigate which genes and pathways are transcriptionally modulated during growth of A. niger on steam-exploded sugarcane bagasse. We also sought to determine whether the mRNA accumulation of several steam-exploded sugarcane bagasseinduced genes encoding putative transporters is induced by xylose and dependent on glucose. We identified 18 genes that corresponds to 58% of A. niger predicted cellulases and 21 genes that correspond to 58% of A. niger predicted hemicellulases, that were highly expressed during growth on sugarcane bagasse. The central role performed by nonessential protein kinases (NPK) and phosphatases (NPP) when grown on cellulose as a sole carbon source, in the sensing energetic status and the subsequent signalling pathways was assessed in the model filamentous fungus Aspergillus nidulans. This study identified multiple kinases and phosphatases (NPKs and NPPs, respectively) involved in the sensing of carbon or energetic status, while demonstrating the overlapping and distinct roles of snfA and schA in the regulation of CreA derepression and hydrolytic enzyme production in A.nidulans. The involvement of the identified NPKs in avicel-induced responses and CreA derepression was assessed by genome-wide transcriptomics and fluorescent microscopy of a CreA::GFP fusion proteinexpressed in the wild-type and NPK-deficient mutant backgrounds. The absence of either the schA or snfA kinase dramatically reduced cellulose-induced transcriptional responses including the expression of hydrolytic enzymes and transporters, while the absence snfA resulted in a near complete loss of wild-typecellulose-induced gene modulation. The mechanism by which these two NPKs controlled gene transcription was identified, as neither of NPK-deficient mutants were able to unlock CreA-mediated carbon catabolite repression, under derepressing conditions, such as carbon starvation or growth on cellulose. Our presently reported work opens new possibilities for understanding sugarcane biomass saccharification by A. niger hydrolases and for the construction of more efficient enzymatic cocktails for second-generation bioethanol. This work also enable the identification of multiple kinases and phosphatases involved in the sensing of carbon or energetic status, while demonstrating the overlapping and distinct roles of snfA and schA in the regulation of CreA derepression and hydrolytic enzyme production in A.nidulans.

A. nidulans

Aspergillus niger

bagaço de cana-de-açúcar explodido

celulase

creA

hemicelulase

repressão catabólica do carbono

schA

snfA

xilanase

xlnR

A. nidulans

Aspergillus niger

carbon catabolite repression

cellulase

creA

hemicellulase

schA.

snfA

steam-exploded sugarcane bagasse

xlnR

xylanase