Low thermal pre-treatment of palm kernel expeller to enhance microalgal hydrogen production

The production of hydrogen from microalgae has inevitably intrigued considerable interests off late. However, the commercial production of microalgal hydrogen is not yet feasible due to the intricate production processes and expensive procedures. Therefore, this research work intended to streamline the microalgal hydrogen gen-eration by utilizing the organic solid waste, palm kernel expeller (PKE), for converting into microalgal hydrogen. Accordingly, the impacts of low thermal pre-treatment method using hydrolysis process was studied at 50 degrees C, 70 degrees C, and 90 degrees C to overcome the recalcitrance of lignocellulosic PKE in associating with the rate of microalgal hydrogen production. The results evidenced that the maximum hydrogen yield was attained at 638 mL H2/g microalgae under the dark anaerobic environment whilst using PKE that was pre-treated at 90 degrees C for 4 h. In comparison with untreated PKE, this microalgal hydrogen yield had increased by two folds. The release of inhibitory compounds had increased significantly at 50 degrees C. Thereafter, the zeroth order model was employed to quantify the kinetics of microalgal hydrogen production. The highest rate was successfully achieved at 128 mL H2/g microalgae-d while subsisting on 90 degrees C pre-treated PKE for 4 h.

Automated summary

The production of hydrogen from microalgae using palm kernel expeller (PKE) as feedstock was studied. A low thermal pre-treatment method using hydrolysis process was used to improve the hydrogen yield. The results showed that the maximum hydrogen yield was achieved using PKE pre-treated at 90 degrees C for 4 h, with a two-fold increase compared to untreated PKE. The release of inhibitory compounds increased significantly at 50 degrees C, and the kinetics of microalgal hydrogen production followed a zeroth order model.