Journal article
Optimizing dilute acid hydrolysis of hemicellulose in a nitrogen-rich cellulosic material--dairy manure
Bioresource technology, Vol.94(1), pp.33-41
08/2004
Handle:
https://hdl.handle.net/2376/101418
PMID: 15081484
Abstract
Effective dilute acid hydrolysis of dairy manure which contains roughly 12% hemicellulose on a dry matter basis can produce a variety of mono-sugars such as arabinose, xylose and galactose, as well as to further benefit utilization of cellulose in the manure. To enhance the effectiveness of this dilute acid hydrolysis, the effect of manure nitrogen content was studied because some reactions such as the browning reaction between amino acids and reducing sugars and acid-base reactions involving ammonia and acid interfere with the hydrolysis. Two dairy manure samples were used to study this nitrogen effect; the original manure and the pretreated manure derived from a solid/liquid separation pretreatment. The pretreated manure had a total nitrogen content of 1.3% dry matter (DM) while the original dairy manure had twice that amount with a total nitrogen content of 2.6% DM. Results found that the optimal conditions for hydrolysis of manure hemicellulose were 2 h reaction time, 1% sulfuric acid concentration, 135 degrees C, and 10% sample concentration using the pretreated dairy manure as raw material. Under these conditions the corresponding sugar yield from hemicellulose was 111% and sugar concentration in the solution reached 16.5 g/l. At the same time, the hydrolyzed solid had 43% DM of cellulose, which was much higher than both the original manure containing 22% and the pretreated manure with 32%.
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Details
- Title
- Optimizing dilute acid hydrolysis of hemicellulose in a nitrogen-rich cellulosic material--dairy manure
- Creators
- Wei Liao - Center for Multiphase Environmental Research, Washington State University, Pullman, WA 99163, USA. wliao@mail.wsu.eduYan LiuChuanbin LiuShulin Chen
- Publication Details
- Bioresource technology, Vol.94(1), pp.33-41
- Academic Unit
- Biological Systems Engineering, Department of; Plant Pathology, Department of
- Publisher
- England
- Identifiers
- 99900546629101842
- Language
- English
- Resource Type
- Journal article