采用10 mg/g纤维素酶R-10预处理芦苇秸秆,研究了酶解预处理对芦苇厌氧产气潜力的影响,分析了氢气-甲烷联产过程中微生物群落结构演替规律.结果表明:酶解预处理后,芦苇秸秆在产氢阶段的累积产气量和φ(H_2)分别达到42.5 m L/g和52.1%;在...采用10 mg/g纤维素酶R-10预处理芦苇秸秆,研究了酶解预处理对芦苇厌氧产气潜力的影响,分析了氢气-甲烷联产过程中微生物群落结构演替规律.结果表明:酶解预处理后,芦苇秸秆在产氢阶段的累积产气量和φ(H_2)分别达到42.5 m L/g和52.1%;在产甲烷阶段,累积产气量稳定上升,最高值可达137.5 m L/g,是对照组产气量的5倍.由扫描电镜(SEM)观察可知,产氢阶段以短杆状和梭状菌为主,产甲烷阶段以长杆菌为主.PCR-DGGE(聚合酶链式反应-变性梯度凝胶电泳)分析表明,芦苇在酶解预处理后,其厌氧联产过程中微生物群落呈规律性演替,产氢阶段的优势微生物分别为具有降解纤维素产氢气功能的嗜热纤维素菌Clostridium thermocellum(条带B20)、具有高效产氢潜力的兼性厌氧产气肠杆菌Enterobacter aerogenes(条带B28);在产甲烷阶段,其优势微生物为可利用氢营养途径合成甲烷的产甲烷古菌Methanoculleus bourgensis(条带A3)、Methanoculleus horonobensis(条带A13).经纤维素酶预处理后,芦苇秸秆厌氧联产的累积产气量、φ(H_2)提高显著,具有纤维素降解功能的细菌和可利用氢营养途径合成甲烷的古菌为主要优势微生物.展开更多
Effect of commercial cellulose enzymes was investigated by batch enzymatic hydrolysis at 15.0% (w/v) solid. It was found that the best commercial cellulose enzyme was Cellic(R) CTec comparing to Accellerase 1000TM...Effect of commercial cellulose enzymes was investigated by batch enzymatic hydrolysis at 15.0% (w/v) solid. It was found that the best commercial cellulose enzyme was Cellic(R) CTec comparing to Accellerase 1000TM and Accelerase 1500TM. The Cellic(R) CTec gave the highest reducing sugar concentration and rice straw conversion. Moreover, when the hydrolysate obtained from hydrolysis using Cellic(R) CTec was fermented by Saccharomyces cerevisiae TISTR 5596, it would give the highest ethanol. In this study, the Cellic(R) CTec was used for fed-batch prehydrolysis prior to ethanol production by simultaneous saccharification and fermentation (SSF) way at 20% (w/v) solid loading. It could produce 35.76 g/L or 4.6% (v/v) of ethanol concentration and 83.67 L/ton dry matter (DM) of yield.展开更多
Water hyacinth is a raw material for long-term sustainable production of cellulosics ethanol. In this study, the acid pretreatment and enzymatic hydrolysis were used to evaluate to produce more sugar, to be fermented ...Water hyacinth is a raw material for long-term sustainable production of cellulosics ethanol. In this study, the acid pretreatment and enzymatic hydrolysis were used to evaluate to produce more sugar, to be fermented to ethanol. Separated hydrolysis and fermentation (SHF) studies were carried out to produce ethanol from water hyacinth leaves. Dilute sulfuric acid pretreatment and enzymatic hydrolysis were conducted to select the optimum pretreatment conditions. The optimum pretreatment conditions included T = 135 ℃, t = 30 min, and sulfuric acid concentration = 0.1 M. The residue was enzymatically hydrolyzed using the mixture of enzymes cellulase, xylanase and pectinase. The maximum enzymatic saccharification of cellulosic material (76.8%) was achieved. SHF by mono-culture of Saccharomyces cerevisiae KM1195 achieved the highest yields of ethanol. Furthermore, ethanol production was accomplished with the co-culture ofS. cerevisiae TISTR5048 and Candida tropicalis TISTR5045 which produced the highest increase in ethanol Yield. In this case, the ethanol concentration of 3.42 (g/L), percentage of the theoretical ethanol yield of 99.9%, the ethanol yield of 0.27 g/g and the productivity of 0.22 g/L/h were obtained. This suggested that mild acid pretreatment and co-cultureare promising methods to improve enzymatic hydrolysis and ethanol production from water hyacinth.展开更多
In this study we used l-allyl-3-methyl imidazole formate ([Amim][COOH]) as ionic liquid to pre-treat the cellulose and determined the rate of polymerization and enzymatic hydrolysis. The results showed that pretreat...In this study we used l-allyl-3-methyl imidazole formate ([Amim][COOH]) as ionic liquid to pre-treat the cellulose and determined the rate of polymerization and enzymatic hydrolysis. The results showed that pretreatment with ([Amim][COOH]) significantly decreased the cellulose polymerization. As the pretreatment temperature went up, the enzymatic hydrolysis rate was first increased and then decreased The maximal enzymatic hydrolysis rate was achieved when the pretreatment temperature was 90 ℃. Under the ultrasonic condition, the initial rate of enzmatic hydrolysis for the ionic liquid-treated cellulose was up to 11.10 gL-1h-1, which was 33% increase compared to the untreated cellulose. Scanning Electronic Microscopy (SEM) and Fourier Transform Infrared-Raman Spectroscop (FT-IR) analysis showed that ionic liquidtreated cellulose started to depolymerize. In addition, the cr3'stallinity of the cellulose was significantly decreased after pretreatment with ionic liquid.展开更多
文摘采用10 mg/g纤维素酶R-10预处理芦苇秸秆,研究了酶解预处理对芦苇厌氧产气潜力的影响,分析了氢气-甲烷联产过程中微生物群落结构演替规律.结果表明:酶解预处理后,芦苇秸秆在产氢阶段的累积产气量和φ(H_2)分别达到42.5 m L/g和52.1%;在产甲烷阶段,累积产气量稳定上升,最高值可达137.5 m L/g,是对照组产气量的5倍.由扫描电镜(SEM)观察可知,产氢阶段以短杆状和梭状菌为主,产甲烷阶段以长杆菌为主.PCR-DGGE(聚合酶链式反应-变性梯度凝胶电泳)分析表明,芦苇在酶解预处理后,其厌氧联产过程中微生物群落呈规律性演替,产氢阶段的优势微生物分别为具有降解纤维素产氢气功能的嗜热纤维素菌Clostridium thermocellum(条带B20)、具有高效产氢潜力的兼性厌氧产气肠杆菌Enterobacter aerogenes(条带B28);在产甲烷阶段,其优势微生物为可利用氢营养途径合成甲烷的产甲烷古菌Methanoculleus bourgensis(条带A3)、Methanoculleus horonobensis(条带A13).经纤维素酶预处理后,芦苇秸秆厌氧联产的累积产气量、φ(H_2)提高显著,具有纤维素降解功能的细菌和可利用氢营养途径合成甲烷的古菌为主要优势微生物.
文摘Effect of commercial cellulose enzymes was investigated by batch enzymatic hydrolysis at 15.0% (w/v) solid. It was found that the best commercial cellulose enzyme was Cellic(R) CTec comparing to Accellerase 1000TM and Accelerase 1500TM. The Cellic(R) CTec gave the highest reducing sugar concentration and rice straw conversion. Moreover, when the hydrolysate obtained from hydrolysis using Cellic(R) CTec was fermented by Saccharomyces cerevisiae TISTR 5596, it would give the highest ethanol. In this study, the Cellic(R) CTec was used for fed-batch prehydrolysis prior to ethanol production by simultaneous saccharification and fermentation (SSF) way at 20% (w/v) solid loading. It could produce 35.76 g/L or 4.6% (v/v) of ethanol concentration and 83.67 L/ton dry matter (DM) of yield.
文摘Water hyacinth is a raw material for long-term sustainable production of cellulosics ethanol. In this study, the acid pretreatment and enzymatic hydrolysis were used to evaluate to produce more sugar, to be fermented to ethanol. Separated hydrolysis and fermentation (SHF) studies were carried out to produce ethanol from water hyacinth leaves. Dilute sulfuric acid pretreatment and enzymatic hydrolysis were conducted to select the optimum pretreatment conditions. The optimum pretreatment conditions included T = 135 ℃, t = 30 min, and sulfuric acid concentration = 0.1 M. The residue was enzymatically hydrolyzed using the mixture of enzymes cellulase, xylanase and pectinase. The maximum enzymatic saccharification of cellulosic material (76.8%) was achieved. SHF by mono-culture of Saccharomyces cerevisiae KM1195 achieved the highest yields of ethanol. Furthermore, ethanol production was accomplished with the co-culture ofS. cerevisiae TISTR5048 and Candida tropicalis TISTR5045 which produced the highest increase in ethanol Yield. In this case, the ethanol concentration of 3.42 (g/L), percentage of the theoretical ethanol yield of 99.9%, the ethanol yield of 0.27 g/g and the productivity of 0.22 g/L/h were obtained. This suggested that mild acid pretreatment and co-cultureare promising methods to improve enzymatic hydrolysis and ethanol production from water hyacinth.
文摘In this study we used l-allyl-3-methyl imidazole formate ([Amim][COOH]) as ionic liquid to pre-treat the cellulose and determined the rate of polymerization and enzymatic hydrolysis. The results showed that pretreatment with ([Amim][COOH]) significantly decreased the cellulose polymerization. As the pretreatment temperature went up, the enzymatic hydrolysis rate was first increased and then decreased The maximal enzymatic hydrolysis rate was achieved when the pretreatment temperature was 90 ℃. Under the ultrasonic condition, the initial rate of enzmatic hydrolysis for the ionic liquid-treated cellulose was up to 11.10 gL-1h-1, which was 33% increase compared to the untreated cellulose. Scanning Electronic Microscopy (SEM) and Fourier Transform Infrared-Raman Spectroscop (FT-IR) analysis showed that ionic liquidtreated cellulose started to depolymerize. In addition, the cr3'stallinity of the cellulose was significantly decreased after pretreatment with ionic liquid.
