Abstract
Lignocellulosic materials have been considered as an alternative source from which liquid biofuel and fine chemicals can be produced with a moderate environmental impact. However, they can be contaminated with metals, soil, and ash, owing incrustation and corrosion of industrial reactors and pipelines. In this work, the use of ultrasound energy was applied for the removal of metals and nonmetals (Ba, Ca, Mg, Mn, P, S, Si, and Sr) from sugarcane straw. Ultrasound-assisted demineralization (UAD) experiments were carried out in ultrasonic baths in several frequencies (from 25 up to 130 kHz). The following experimental conditions were evaluated: demineralization solution (HNO3, HCl, H2SO4, H2O2, and H2O), H2O2 concentration (from 5 to 30% v v−1), extraction temperature (from 30 to 70 °C), sonication time (from 5 to 45 min), and ultrasound amplitude (from 10 to 70%). Better demineralization efficiencies (66%) were obtained employing an ultrasound bath operating at 25 kHz for 30 min, ultrasound amplitude of 60%, and using a diluted H2O2 solution (15% v v−1) at 70 °C. When the obtained results were compared with those obtained by mechanical stirring (MS, 500 rpm), it was observed that the use of ultrasound energy increased the demineralization efficiency up to 16%. Furthermore, acid hydrolysis was performed to evaluate the influence of US and mechanical stirring in fermentable sugars’ production. The total sugars’ yield (glucose, xylose, and arabinose) increased around 55% for both systems (US and MS). To prove the applicability of the proposed process, some experiments for scaling up were performed using several reaction loads (0.5 to 3 L). An attempt for scaling the proposed process up was well succeeded up to a 3 L load. Therefore, the proposed ultrasound-assisted procedure can be considered as a suitable alternative for high-efficiency demineralization from sugarcane straw.
Highlights
The decrease of fossil fuels resources associated with the need for the reduction of pollution and greenhouse gas emissions makes lignocellulosic biomass a promising alternative source for fuel and solvent production
To better evaluate the effect of the extraction solution, as well as every evaluated parameter for the proposed Ultrasound-assisted demineralization (UAD), the elemental concentration in untreated sugarcane straw obtained after sample digestion was tested by ICP-OES
Based on the results obtained in this study, it was observed that the US bath system achieved better extraction efficiency compared to that of mechanical stirring
Summary
The decrease of fossil fuels resources associated with the need for the reduction of pollution and greenhouse gas emissions makes lignocellulosic biomass a promising alternative source for fuel and solvent production. Lignocellulosic materials trap atmospheric carbon dioxide, reducing carbon and greenhouse gas emissions [3]. Considering any process regarding biomass valorization, a pretreatment step is necessary to ensure the selectivity and efficient biomass conversion. The pretreatment step consists of the fragmentation of lignocellulosic material, and separation of lignin, hemicellulose, cellulose, and inorganic materials [4]. Potentially alternative feedstocks to food raw materials have been studied. The so-called “second generation feedstocks” are considered wastes or subproducts of conventional routes, such as food industry waste, agricultural waste, peels, and straws [5].
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