Optimization of liquid ammonia pretreatment variables for maximum enzymatic hydrolysis yield of energy cane bagasse

•Temperature, residence time and ammonium hydroxide to biomass ratio were significant on the sugar yields from dilute ammonia pretreated energy cane bagasse.•Temperature was the most effective pretreatment variable on sugar yields, followed by ammonium hydroxide to biomass ratio.•A strong correlatio...

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Bibliographic Details
Published in:Industrial crops and products 2017-09, Vol.103, p.122-132
Main Authors: Oladi, Saeed, Aita, Giovanna M.
Format: Article
Language:English
Subjects:
adverse effects
ammonia
ammonium hydroxide
bagasse
Bioconversion
biomass
Energy cane
enzymatic hydrolysis
glucose
lignin
prediction
Pretreatment
Process optimization
response surface methodology
solubilization
system optimization
temperature
xylan
xylose
yields
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Summary:•Temperature, residence time and ammonium hydroxide to biomass ratio were significant on the sugar yields from dilute ammonia pretreated energy cane bagasse.•Temperature was the most effective pretreatment variable on sugar yields, followed by ammonium hydroxide to biomass ratio.•A strong correlation was found between lignin removal and cellulose digestibility.•Optimum pretreatment conditions for maximum glucose yield were 208°C, 36min and an ammonium hydroxide to biomass ratio of 0.4:1.•A sugar yield of 30.77g glucose and 3.99g xylose per 100g (dry weight) of untreated biomass was predicted by the model and confirmed experimentally. This study aimed at optimizing a liquid ammonium hydroxide pretreatment for energy cane bagasse for maximum sugar yields (glucose and xylose) via response surface methodology. Optimized pretreatment parameters included temperature (160–220°C), ammonium hydroxide to biomass ratio (0–0.5:1) and residence time (30–60min). Temperature was found to be the dominant pretreatment parameter followed by ammonium hydroxide to biomass ratio. High temperatures and long residence times had a negative effect on sugar yields. Sugar yields had the highest correlation with lignin removal. Based on our quadratic models fitted on the experimental results, optimum pretreatment conditions for maximum glucose yield were 208°C, for 36min and at an ammonium hydroxide to biomass ratio of 0.4:1. A glucose yield of 30.77g glucose/100g (dry weight) untreated biomass and a xylose yield of 3.99g xylose/100g (dry weight) untreated biomass were predicted by the model. Optimum pretreatment conditions for maximum xylose yield were 160°C, for 60min and at an ammonium hydroxide to biomass ratio of 0.31:1. These conditions resulted in a predicted xylose yield of 9.10g xylose/100g (dry weight) untreated biomass and a glucose yield of 23.34g glucose/100g (dry weight) untreated biomass. The low xylose yields observed were attributed to the high amounts of xylan lost due to solubilization. The quadratic models were found to be reliable for the prediction of sugar yields within the design space. All predicted values were experimentally confirmed with 95% confidence of the predicted values.
ISSN:0926-6690
1872-633X
DOI:10.1016/j.indcrop.2017.02.023