Abstract:
Te use of biomass as carbon precursors has been extensively investigated, with a particular emphasis on examining the properties
of derived porous carbon and its application in electrical double-layer capacitors (EDLCs). Biomass-derived porous carbon-based
electrodes have shown promising properties that can improve the efciency of EDLCs. However, despite the extensive research in
this feld, no defnitive solution has been proposed. Tis review investigates in depth three main factors that impact the
electrochemical performance of derived porous carbon-based electrodes: (1) the initial properties of raw biomass as carbon
precursors, (2) operating conditions, and (3) physicochemical properties of biomass-derived porous carbon materials. Examined
operating conditions include synthesis techniques, activating agents, the mass ratio of the activating agent to the raw biomass as
porous carbon precursors, carbonization/activation duration, operating temperature, and the mass of the active material in the
electrode. Te surface morphology and surface functional groups were used to evaluate the physicochemical properties of derived
porous carbon materials. Multiple factors infuence the properties of porous carbon derived from biomass and, consequently, the
efciency of the electrodes made from these materials. Tis study reveals that the properties of porous carbon-based electrodes
derived from biomass vary from one biomass to another and are afected by various parameters, conditions, and synthesis
techniques. Terefore, it is impossible to rely exclusively on a single factor to improve the electrochemical performance of EDLC
electrodes. A thorough consideration of the multiple factors is required to optimize the properties and performance of the
electrodes.
