Abstract
Powdery hierarchical porous carbons serve as cost‐effective, functional materials in various fields, namely energy storage, heterogeneous catalysis, electrochemistry, and water/wastewater treatment. Such powdered activated carbons (PAC) limit new module designs and require further preparation steps, for example, adding polymeric binders, to be shaped into a standalone geometry. Polymeric binders, however, can block PACs’ catalytic and active sites and, more importantly, pose the risk of secondary pollution for environmental purposes, especially in the context of clean water supply. This study introduces a novel synthesis method for fabricating freestanding nitrogen‐doped carbons with hierarchical porosity using chitosan and sucrose as green precursors. Chitosan supplies nitrogen and acts as a backbone, giving a freestanding geometry to the final product, and sucrose is a carbon‐rich precursor. The proposed method employs ice‐ and hard‐templating for macropores and mesopores and combines carbonization and activation steps with no required activating agent. Final freestanding carbons function as adsorbents for removing persistent pollutants, as binder‐free electrodes with high specific surface area and capacitive current, and as tubular gas diffusion electrodes for oxygen reduction reactions. These freestanding carbons enable new module designs and can be scaled‐up by numbering‐up, serving as bio‐based functional materials for a wide range of applications involving porous heteroatom‐doped carbons.
Highlights
We have introduced a novel approach with onestep carbonization and activation for the production of N-doped monolithic carbons through ice- and silica-templating and using chitosan and sucrose as precursors
Commercial GAC particles with a BET surface area of 1355 m2 g−1 resulted in an adsorption capacity of 135 mg g−1 and a rate constant of 0.016 h−1 under similar experimental conditions
The micro- and mesoporosity of the final products were tunable from a microporedominated carbon (ChiSuc_Br_1000) to mesopore-dominated ones (ChiSuc & ChiSuc_GDE) with the same precursors and silica content depending on the mold’s material, type, and sintering temperature
Summary
Introduction materials in various fields, namely energy storage, heterogeneous catalysis, electrochemistry, and water/wastewater treatment Such powdered activated carbons (PAC) limit new module designs and require further preparation steps, for example, adding polymeric binders, to be shaped into a standalone. Final freestanding carbons function as adsorbents for removing persistent pollutants, as binderfree electrodes with high specific surface area and capacitive current, and as tubular gas diffusion electrodes for oxygen reduction reactions These freestanding carbons enable new module designs and can be scaled-up by numbering-up, serving as bio-based functional materials for a wide range of applications involving porous heteroatom-doped carbons.
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