A New Approach for Economical Pretreatment of Corncobs

Huge amounts of waste acid and wastewater are generated during the corncob pretreatment process, which limits chemical utilization of biomass resources to produce value-added chemicals and biofuels. In this work, a new approach, i.e., reuse of the corncob pretreatment liquid, is proposed toward diminishing acid and water consumption. Metal ions and soluble proteins in the pretreatment liquid were analyzed by the inductively coupled plasma atomic emission spectroscopy (ICP-AES) and the Coomassie rilliant blue G250 method, respectively. The results showed that the increament of soluble proteins and total metal ions in solution by three reuse rounds of the pretreatment liquid is nearly identical to that in solution by new added pretreatment liquid. Besides, the surface morphology of the corncob obtained by three reuse rounds of the liquid pretreatment did not exhibit significant difference comparing to that of the corncob acquired by new liquid pretreatment. Further, selection basis of an optimal reuse round of the pretreatment liquid is suggested depending on the effective removal of soluble proteins and metal ions from corncobs. By repeated use of the pretreatment liquid, the consumption of both acid and water during the corncob pretreatment process is expected to be significantly reduced.

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