|
|
-
sp.2 carbon served to produce radicals by PDS activation in an electron-accepting process
-
Graphitic and pyridinic N facilitated ROS generation
-
C=O contributed to 1O2 formation
-
Removal efficiency decreased from 85.72% to 32.53% at 30 min in 2nd cycle
|
[98] |
|
|
-
Sieving to small-sized biochar (0–75 µm) enhanced PDS activation due to more graphitic and aromatic carbon, COOH content, and higher SSA
-
COOH groups promoted SO4•− and •OH formation
-
Biochar mediated electron transfer from SMT to PDS
-
Electron-rich active sites transfer electrons to PDS for SO4•−, •OH, 1O2, and •O2− generation
|
[99] |
-
Spent tea leave
-
Pre-oxidation: 250 °C, 0.5 h, air environment
-
Pyrolysis: 500 °C, 1 h, N2 atmosphere
|
|
-
Pre-adsorption was beneficial to the subsequent catalytic degradation
-
Delocalized π-electrons and Fe facilitated SO4•−, •OH, and 1O2 generation
|
[100] |
-
Dairy manure
-
Anaerobic digestion: 37 °C, 35 days
-
Pyrolysis: 800 °C, 2 h, N2 atmosphere
|
|
-
Defects were positively correlated with degradation potential (R2 = 0.92)
-
Electron-rich C=O promoted •O2− and 1O2 generation
-
Graphitic N accelerated electron transfer from carbon to O2 for 1O2 formation
-
Pyridine N was not an active site
-
Graphitic structure facilitated electron transfer between SMX and PMS
-
Removal efficiency decreased from 90.2% to 62.5% in 5th cycle
|
[101] |
-
Straw
-
Pyrolysis: 700 °C, 2 h, N2 atmosphere
-
N doping: Thiourea + biochar, pyrolysis: 800 °C, 2 h, N2 atmosphere
|
-
[TC] = 20 mg L−1, [Biochar] = 200 mg L−1, [PDS] = 2 mM, pH = 7
-
97% removed in 60 min and 100% in 120 min
|
-
Reaction mainly relied on nonradical electron transfer between TC and PDS due to enhanced graphitization degree
-
Radicals had no effect on TC degradation
-
Removal efficiency decreased from 100% to 55% in 3rd cycle
|
[102] |
-
Rice husk
-
Pyrolysis: 850 °C, 1 h
|
|
|
[103] |
-
Wheat straw + B doping
-
Pyrolysis: 900 °C, 2 h, N2 atmosphere
-
KOH activation: 600 °C, 2 h, N2 atmosphere
-
Acid (HCl) washing
|
|
-
B species acted as Lewis acid sites enhancing PDS adsorption
-
Defects and sp.2-conjugated π-system facilitated electron transfer
-
B substitution in carbon matrix enhanced catalyst stability due to active sites reversible transformation during catalytic activation
-
Removal efficiency decreased from 92% to 90% in 5th cycle
|
[49] |
|
|
-
Synergy between S and N moieties altered surrounding electron density
-
•OH, SO4•−, and 1O2 participated in the catalytic reaction
-
Removal rate decreased gradually from 0.202 min−1 to 0.019 min−1 in 4th cycle
|
[95] |
|
|
-
Pyridinic and pyrrolic N at edge sites disturbed electron density to create active sites
-
Graphitic N was not well correlated with catalytic activity
-
PDS was reduced at electron-rich N while SDZ was oxidized around adjacent electron-deficient C
-
Reaction was dominated by an electron transfer regime that was unaffected by inorganic anions except NOM
-
Removal efficiency decreased from 96.5% to 83.0% after 3 cycles
|
[15] |
-
Wetland plants (reed) + N doping
-
Pyrolysis: 900 °C, 90 min, N2 atmosphere
|
|
-
Quaternary N induces asymmetric spin density and low electron density to adjacent carbons, facilitating the chemical bonding with negatively charged O atoms of the O-O bond in PDS for free radicals formations
-
Large SSA and π−π interactions between OG aromatic rings graphitic carbon structure enhanced adsorption
-
Catalytic activity was governed by nonradical pathway of surface-activated PDS complexes and 1O2
-
Removal efficiency decreased from 98.3% to 45.0 ± 2.0% after 5 runs
|
[92] |
-
Spirulina residue + N doping
-
Pyrolysis: 900 °C, 90 min, N2 atmosphere
-
Acid (HCl) washing
|
|
-
Biochar provided electron-mediating medium between SMX and PDS for nonradical degradation
-
N doping caused a redistribution of charge densities in graphitic carbons where PDS will then bond with positively charged O atoms adjacent to N dopants to enhance activation performance
-
Surface-activated metastable PDS/carbon complex participated in reaction
-
Removal efficiency decreased from 100% to 42.51% after 3 cycles
|
[29] |