Abstract
This paper reviews the chemical hydrolysis processes of dairy manure fiber to make its sugar accessible to microorganisms during anaerobic digestion and identifies obstacles and opportunities. Researchers, so far, investigated acid, alkali, sulfite, and advanced oxidation processes (such as hydrogen peroxide assisted by microwave/ultrasound irradiation, conventional boiling, and wet oxidation), or their combinations. Generally, dilute acid (3–10%) is less effective than concentrated acid (12.5–75%), which decrystallizes the cellulose. Excessive alkaline may produce difficult-to-degrade oxycellulose. Therefore, multi-step acid hydrolysis (without alkaline) is preferred. Such processes yielded 84% and 80% manure-to-glucose and -xylose conversion, respectively. Acid pretreatment increases lignin concentration in the treated manure and hinders subsequent enzymatic processes but is compatible with fungal cellulolytic enzymes which favor low pH. Manure high alkalinity affects dilute acid pretreatment and lowers glucose yield. Accordingly, the ratio of manure to the chemical agent and its initial concentration, reaction temperature and duration, and manure fineness need optimization because they affect the hydrolysis rate. Optimizing these factors or combining processes should balance removing hemicellulose and/or lignin and increasing cellulose concentrations while not hindering any subsequent process. The reviewed methods are neither economical nor integratable with the on-farm anaerobic digestion. Economic analysis and energy balance should be monolithic components of the research. More research is required to assess the effects of nitrogen content on these processes, optimize it, and determine if another pretreatment is necessary.
Highlights
Cattle manure is low-cost renewable lignocellulosic waste biomass that does not compete with food when used as a substrate for biofuel; it is currently under extensive research as feedstock for biofuel production
Cow manure has relatively high cellulosic content (20–26% of the dry matter (DM)) not all its volatile solids (VS) can be converted to methane (CH4 ) because cellulose and hemicellulose are protected by lignin which is non-biodegradable in anaerobic digestion
Converting manure’s of one or both of them improved the enzymatic hydrolysis of the cellulose fibers
Summary
Cattle manure is low-cost renewable lignocellulosic waste biomass that does not compete with food when used as a substrate for biofuel; it is currently under extensive research as feedstock for biofuel production. In 2001, cattle produced around 86% of the Canadian livestock manure, i.e., 146 million tonnes (wet basis) [1]. Cow manure has relatively high cellulosic content (20–26% of the dry matter (DM)) not all its volatile solids (VS) can be converted to methane (CH4 ) because cellulose and hemicellulose are protected by lignin which is non-biodegradable in anaerobic digestion. Little has been done to recover the ultimate potential energy in cattle manure through bioprocesses This is mainly because of the complex physicochemical composition of manure (Chen et al, 2003); preliminary studies to convert all reduced-carbon in manure to biofuel on a large-scale basis have not been successful [7,20]. Energies 2021, 14, 6159 research on chemical methods investigated to hydrolyze dairy manure fiber and identifies obstacles and opportunities
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