Abstract
Heteroatom doping, involving the introduction of atoms with distinct electronegativity into carbon materials, has emerged as an effective approach to optimize their charge distribution. In this study, we designed a strategy to synthesize in-situ Mn, N co-doped carbon nanospheres (Mn-NC) through the polycondensation of 2,6-diaminopyridine and formaldehyde in synchronization with Mn2+ chelation to form Mn-polytriazine precursor, followed by calcination to form carbonaceous solid. Then Mn-NC was fabricated into a capacitive deionization (CDI) electrode for the selective removal of uranium ions (U (VI)), which is commonly found in radioactive water. Interestingly, Mn-NC exhibited good selectivity for UO22+ capture with a demonstrated adsorption capacity of approximately 194 mg/g @1.8 V. The systematic analysis of the adsorption mechanism of UO22+ revealed that N dopants within Mn-NC can coordinate with the U (VI) ions, thereby facilitating the removal process. Our study presents a straightforward and convenient strategy for removing UO22+ ions by harnessing the coordination effect, eliminating the requirement for pore size control. © 2023 Elsevier Ltd
Original language | British English |
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Journal | Chemosphere |
Volume | 342 |
DOIs | |
State | Published - 2023 |
Keywords
- Adsorption sites
- Capacitive deionization
- Charge enrichment
- Coordination
- Uranium ions
- Adsorption
- Carbon
- Chemical bonds
- Electronegativity
- Nanospheres
- Pore size
- Uranium dioxide
- 2,6 diaminopyridine
- carbon
- formaldehyde
- manganese
- nanosphere
- uranium
- Adsorption site
- Carbon material
- Carbon nanosphere
- Co-doped
- Doped carbons
- Heteroatoms
- Uranium ion
- adsorption
- carbon nanotube
- cation
- electrode
- aqueous solution
- Article
- Brunauer Emmett Teller method
- chelation
- comparative study
- current density
- deconvolution
- electrodeposition
- electron transport
- energy consumption
- impedance spectroscopy
- oxidation reduction reaction
- photoelectron spectroscopy
- pore size
- pore size distribution
- precursor
- radioactive wastewater
- Raman spectrometry
- room temperature
- scanning electron microscopy
- Soxhlet extraction
- surface area
- Ions