Fenton-like activity and pathway modulation via single-atom sites and pollutants comediates the electron transfer process

Abstract: The studies on the origin of versatile oxidation pathways toward targeted pollutants in the single-atom catalysts (SACs)/peroxymonosulfate (PMS) systems were always associated with the coordination structures rather than the perspective of pollutant characteristics, and the analysis of mechanism commonality is lacking. In this work, a variety of single-atom catalysts (M-SACs, M: Fe, Co, and Cu) were fabricated via a pyrolysis process using lignin as the complexation agent and substrate precursor. Sixteen kinds… Show more

“…To investigate the reactive species and reaction mechanism of the PAA/ND system in alkaline water samples, reference is made to recent research by Guo et al 34 They established that electron transfer and free radicals oxidation pathways could simultaneously occur within the same AWT system, influenced by the energy gaps between the catalytic oxidation complexes and pollutants and the electrophilic index of organic pollutants.…”

“…To investigate the reactive species and reaction mechanism of the PAA/ND system in alkaline water samples, reference is made to recent research by Guo et al They established that electron transfer and free radicals oxidation pathways could simultaneously occur within the same AWT system, influenced by the energy gaps between the catalytic oxidation complexes and pollutants and the electrophilic index of organic pollutants. Based on this, it was initially hypothesized that the efficiency increase is attributable to the nonradical electron transfer contribution during the decomposition of PAA, similar to the degradation of aromatic compounds by PAA-based AWT induced by the electron transfer from the target substance to free radicals, as proposed by Kim et al The activation of PAA and the degradation of PFOA involve electron transfer from PFOA (an electron donor) to PAA (an electron acceptor), with ND acting as an efficient electron transfer mediator.…”

Prehydrated Electrons Activated by Continuous Electron Transfer Stemmed from Peracetic Acid Homolysis Mediated by Diamond Surface Defects for Enhanced PFOA Destruction

“…To investigate the reactive species and reaction mechanism of the PAA/ND system in alkaline water samples, reference is made to recent research by Guo et al 34 They established that electron transfer and free radicals oxidation pathways could simultaneously occur within the same AWT system, influenced by the energy gaps between the catalytic oxidation complexes and pollutants and the electrophilic index of organic pollutants.…”

“…To investigate the reactive species and reaction mechanism of the PAA/ND system in alkaline water samples, reference is made to recent research by Guo et al They established that electron transfer and free radicals oxidation pathways could simultaneously occur within the same AWT system, influenced by the energy gaps between the catalytic oxidation complexes and pollutants and the electrophilic index of organic pollutants. Based on this, it was initially hypothesized that the efficiency increase is attributable to the nonradical electron transfer contribution during the decomposition of PAA, similar to the degradation of aromatic compounds by PAA-based AWT induced by the electron transfer from the target substance to free radicals, as proposed by Kim et al The activation of PAA and the degradation of PFOA involve electron transfer from PFOA (an electron donor) to PAA (an electron acceptor), with ND acting as an efficient electron transfer mediator.…”

Prehydrated Electrons Activated by Continuous Electron Transfer Stemmed from Peracetic Acid Homolysis Mediated by Diamond Surface Defects for Enhanced PFOA Destruction

“… However, the issue of sluggish dynamics of Fe II generation still limits the practical applications of Fenton technique (eqs and , Text S1 and Figure S1). − F e ( I I ) + H 2 O 2 → F e ( I I I ) + • O H + normalO normalH − goodbreak0em3em⁣ k = 80 .25em normalM − 1 .25em s − 1 F e ( I I I ) + H 2 O 2 → F e ( I I ) + normalH normalO 2 • + H + goodbreak0em1em⁣ k = 9.1 × 10 − 7 .25em normalM − 1 .25em s − 1…”

“… However, the issue of sluggish dynamics of Fe II generation still limits the practical applications of Fenton technique (eqs and , Text S1 and Figure S1). − …”

New Insights into Photo-Fenton Chemistry: The Overlooked Role of Excited Iron^III Species

“…Although conventional Fenton oxidation can be enhanced using electron sacrificial agents to promote Fe(III) reduction, there are inherent disadvantages such as poor stability, recovery difficulties, secondary pollution, and high economic costs. 11 In Fenton chain reactions, Fe(III) can be slowly reduced by reacting with H 2 O 2 (eq 2), indicating the ability of H 2 O 2 to reduce Fe(III). Therefore, the inherent drawbacks of enhancing Fenton oxidation with reducing species would be effectively avoided if the ability of Fe(III) to oxidize H 2 O 2 is enhanced.…”

Hydrogen Peroxide as an Ideal Electron Donor for Long-Lasting Fenton Chemistry: Strong Enhancement of Fe(III) Activity by Heteroatom-Doped Nanocarbons