Li, JianHe, Zhen2016-11-292016-11-292016-01-010944-1344http://hdl.handle.net/10919/73531Membrane bioelectrochemical reactors (MBERs) integrate membrane filtration into bioelectrochemical systems for sustainable wastewater treatment and recovery of bioenergy and other resource. Mathematical models for MBERs will advance the understanding of this technology towards further development. In the present study, a mathematical model was implemented for predicting current generation, membrane fouling, and organic removal within MBERs. The relative root-mean-square error was used to examine the model fit to the experimental data. It was found that a constant to determine how fast the internal resistance responds to the change of the anodophillic microorganism concentration could have a dominant impact on current generation. Hydraulic cross-flow exhibited a minor effect on membrane fouling unless it was reduced below 0.5 m s−1. This MBER model encourages further optimization and eventually can be used to guide MBER development.3897 - 3906 (10) page(s)application/pdfenIn CopyrightEnvironmental SciencesEnvironmental Sciences & EcologyBioelectrochemical systemMicrobial fuel cellMembrane separationMathematical modelingWastewater treatmentWASTE-WATER TREATMENTMICROBIAL FUEL-CELLSBIOREACTORPERFORMANCETECHNOLOGYSYSTEMDevelopment of a dynamic mathematical model for membrane bioelectrochemical reactors with different configurationsArticle - RefereedEnvironmental Science and Pollution Researchhttps://doi.org/10.1007/s11356-015-5611-3234