LAUSR

ABSTRACT Cost-effective biosorbents made from the byproducts of agriculture, forest, and related industries, such as barley straw, canola meal, and wood sawdust, have significant water adsorption capacity, showing a great potential for selective water removal from bioalcohols to produce fuel grade products. However, there is a challenge that the biosorbents are not stable when they come in contact with aqueous solution. There are organic carbons released from biosorbents to liquid phase, which needs to be addressed before this technology is applied in the industrial purification of bioalcohols. In this work, raw barley straw representing an abundant group of cellulosic materials in the above-mentioned industries was used as a model material. A methodology of chemical and physical treatment was developed to treat barley straw which successfully enhanced the stability and reduced the total organic carbon release from the material into the aqueous solution. In addition, the pre-treated barley straw biosorbent had significantly increased micropores, and the Brunauer--Emmett--Teller surface area favored by water adsorption compared with raw barley straw. It also had higher water uptake and dynamic water adsorption selectivity. The pre-treated barley straw was able to selectively remove water and generate concentrated ethanol.