Abstract
Acid-impregnation and its combination with steam explosion were evaluated and optimized using Response Surface Methodology. At 10% solid-liquid ratio, cogon was impregnated with diluted H2SO4 solution (0 to 3%, w/w) at different ranges of temperature (40 to 120 °C) and varied time (0 to 130 min). Impregnated samples were then subjected to enzymatic saccharification using 60 FPU/g Accelerase 1500™. After enzymatic saccharification, the concentration of reducing sugar released was measured using Dinitrosalicylic (DNS) Colorimetric Method. Based on the results, Response Surface Model (RSM) showed that the optimum condition, predicting 7.18% Reducing Sugar Yield (RSY), was impregnation of cogon using 1.9% H2SO4 at 91.8 °C for 56 min. Experimental verification of optimum condition, done in triplicates, showed 6.35 + 0.05% RSY. Acid-impregnated cogon was subjected to steam explosion to improve saccharifiability. Factors varied were temperature (137 to 222 °C) and exposure time (17 to 582 s). Steam-exploded samples were saccharified and RSY was determined. RSM indicated that the best steam explosion condition, predicting 7.91% RSY, was 179 °C and 500 s. Experimental verification of optimum condition showed 8.78 + 0.02% RSY. Using RSY as basis, steam explosion improved saccharifiability of H2SO4-impregnated cogon by 38%, thus, increasing production of reducing sugars for potential bioethanol production.
Highlights
One of the major environmental issues we are facing today is climate change
The models generated to predict the optimal conditions for both acid-impregnation and its combination with steam explosion are valid based on the results of the experimental verification
Reducing sugar yield upon using acid-impregnation as pretreatment method for cogon was 6.35% and a follow-through steam explosion resulted to an 8.78% RSY
Summary
One of the major environmental issues we are facing today is climate change It is primarily caused by the human expansion of the greenhouse emissions which according to the 5th Assessment Report of the Intergovernmental Panel on Climate Change (IPCC), is from the energy supply (47%), industry (30%), transport (11%) and buildings (3%) sectors [1]. This vast dependence on fossil fuels and its impact to the environment led to extensive researches on renewable sources of fuels in many countries. Bioethanol as biofuel is one of the most researched alternative sources of energy Lignocellulosic material, such as cogon, is an abundant organic resource in the Philippines.
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