Abstract
Olive Tree Pruning (OTP) biomass can be considered a suitable source of fermentable sugars for the production of second-generation bioethanol. The present study proposes a remarkable alternative for the valorization of olive tree pruning residues. OTP biomass was processed using a sequential calcium hydroxide pretreatment/enzymatic hydrolysis. A 24–1 half fractional factorial design was adopted for the screening of process variables and a central composite design was used for the optimization stage. Temperature and lime loading resulted statistically significant. The following optimal conditions were obtained: 0.01 g of Ca(OH)2/g of dry material, 20 g of H2O/g of dry material at 160 °C for 2 h. The mathematical model that governs this alkaline pretreatment was obtained with a 76% adjusted determination coefficient, which means that it is a good representation of the process. Under optimal operating conditions, 13% of the cellulose and 88% of the hemicellulose was solubilized. Moreover, the fermentable sugar content increased 1800% compared with the initial conditions, obtaining 240 g of glucose per kg of OTP residue. The fermentable sugars obtained after the calcium hydroxide pretreatment and enzymatic hydrolysis of OTP biomass yielded 2.8 g of ethanol/100 g of raw material.
Highlights
Energy policies that have been implemented in recent years are oriented towards the exploitation of renewable energy sources, greatly encouraged by economic and tax incentives [1]
The present study proposes a remarkable alternative for the valorization of olive tree pruning residues
The high Neutral Detergent Fiber (NDF) value obtained in our study showed that only 41% of Olive Tree Pruning (OTP) biomass consisted of soluble substances
Summary
Energy policies that have been implemented in recent years are oriented towards the exploitation of renewable energy sources, greatly encouraged by economic and tax incentives [1]. Countries intend to reach objectives on renewable energies with a relevant paradigm change in the exploitation of renewable sources [2]. These sources do not generate hazardous waste and help reduce the greenhouse effect. Lignocellulosic materials have been proposed within the concept of precursors for a wide range of value-added products [3]. This concept stimulates the participation of agriculture and involves energy recovery from waste [4]. Its great abundance, low cost and lignocellulosic composition, make this residue appropriate as a renewable energy source, with many environmental advantages [3, 6]
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