An enzyme-mimic single Fe-N
            <sub>3</sub>
            atom catalyst for the oxidative synthesis of nitriles via C─C bond cleavage strategy

Qin, Jingzhong; Han, Bo; Liu, Xixi; Dai, Wen; Wang, Yanxin; Luo, Huihui; Lu, Xiaomei; Nie, Jiabao; Xian, Chensheng; Zhang, Zehui

doi:10.1126/sciadv.add1267

Cited by 45 publications

(45 citation statements)

References 48 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…As depicted in Figure 6 f, the EPR signal displayed the characteristic fingerprint of spin adducts as a result of ·O 2 – , further confirming that the reactive oxygen species was ·O 2 – . 40 , 41 …”

Section: Resultsmentioning

confidence: 99%

“…Furthermore, the reactive oxygen species were explored during the oxidative transformation of N -ethylaniline into aniline over the ZnN 4 -SAC catalyst by radical inhibition experiments (Figure e and Table S9). , The conversion greatly decreased from 56% under the standard conditions to 10% in the presence of a radical scavenger of 2,6-di- tert -butyl-4-methylphenol (BHT), suggesting that the reaction should proceed via the radical reaction process. The presence of superoxide radical (·O 2 – ) scavengers (PBQ; 1,4-benzoquinone) greatly inhibited the reaction, while the addition of singlet oxygen (1O 2 ) scavengers (FA; furfuryl alcohol) and hydroxyl radical (·OH) scavengers (IPA; iso-propyl alcohol) showed no significant influence.…”

Section: Resultsmentioning

confidence: 99%

“…Next, we used the electron paramagnetic resonance (EPR) technique with 5,5-dimethyl-1-pyrroline N -oxide (DMPO) as the spin trap at room temperature. As depicted in Figure f, the EPR signal displayed the characteristic fingerprint of spin adducts as a result of ·O 2 – , further confirming that the reactive oxygen species was ·O 2 – . , …”

Section: Resultsmentioning

confidence: 99%

“…As depicted in Figure 6f, the EPR signal displayed the characteristic fingerprint of spin adducts as a result of •O 2 − , further confirming that the reactive oxygen species was •O 2 − . 40,41 After the identification of the reactive oxygen species, the plausible mechanism of oxidative cleavage of C−N bonds in Nalkylanilines and N,N-dialkylanilines was studied by GC−MS. First, the oxidative transformation of N-benzyl-N-ethylaniline was performed at 150 °C and 10 bar O 2 (Figure S10a).…”

Section: Oxidative Cleavage Of C−n Bonds In N-alkylbenzylamines and N...mentioning

confidence: 99%

See 3 more Smart Citations

Biomass-Derived Single Zn Atom Catalysts: The Multiple Roles of Single Zn Atoms in the Oxidative Cleavage of C–N Bonds

Qin

Han

et al. 2023

JACS Au

Self Cite

View full text Add to dashboard Cite

The C–N bond cleavage represents one kind of important organic and biochemical transformation, which has attracted great interest in recent years. The oxidative cleavage of C–N bonds in N , N -dialkylamines into N -alkylamines has been well documented, but it is challenging in the further oxidative cleavage of C–N bonds in N -alkylamines into primary amines due to the thermally unfavorable release of α-position H from N–C α –H and the paralleling side reactions. Herein, a biomass-derived single Zn atom catalyst (ZnN 4 -SAC) was discovered to be a robust heterogeneous non-noble catalyst for the oxidative cleavage of C–N bonds in N -alkylamines with O 2 molecules. Experimental results and DFT calculation revealed that ZnN 4 -SAC not only activates O 2 to generate superoxide radicals (·O 2 – ) for the oxidation of N -alkylamines to generate imine intermediates (C=N), but the single Zn atoms also served as the Lewis acid sites to promote the cleavage of C=N bonds in imine intermediates, including the first addition of H 2 O to generate α-hydroxylamine intermediates and the following C–N bond cleavage via a H atom transfer process.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Oxidative Cleavage Of C−n Bonds In N-alkylbenzylamines and N...mentioning

confidence: 99%

See 2 more Smart Citations

Biomass-Derived Single Zn Atom Catalysts: The Multiple Roles of Single Zn Atoms in the Oxidative Cleavage of C–N Bonds

Qin

Han

et al. 2023

JACS Au

Self Cite

View full text Add to dashboard Cite

show abstract

“…Recently, some research revealed that single‐atoms catalysts (SACs) [ 23 , 24 , 25 , 26 , 27 , 28 ] are the ideal candidate for the nanozymes because the atomically dispersed metal centers in SACs exhibit a high catalytic activity via maximized atomic utilization efficiency and active sites density. [ 29 , 30 ] Furthermore, the homogenous structure of metal atoms in SACs is an excellent platform to deeply understand the structure–activity relationships at the atomic level. The previous study [ 31 ] developed single iron atoms nanozymes (SANs) and proved their effectiveness for the O 2 activation in biosensing and biomedical.…”

Section: Introductionmentioning

confidence: 99%

Axial N Ligand‐Modulated Ultrahigh Activity and Selectivity Hyperoxide Activation over Single‐Atoms Nanozymes

et al. 2022

View full text Add to dashboard Cite

Learning and studying the structure–activity relationship in the bio‐enzymes is conducive to the design of nanozymes for energy and environmental application. Herein, Fe single‐atom nanozymes (Fe‐SANs) with Fe–N 5 site, inspired by the structure of cytochromes P450 (CYPs), are developed and characterized. Similar to the CYPs, the hyperoxide can activate the Fe(III) center of Fe‐SANs to generate Fe(IV)=O intermediately, which can transfer oxygen to the substrate with ultrafast speed. Particularly, using the peroxymonosulfate (PMS)‐activated Fe‐SANs to oxidize sulfamethoxazole, a typical antibiotic contaminant, as the model hyperoxides activation reaction, the excellent activity within 284 min −1 g −1 (catalyst) mmol −1 (PMS) oxidation rate and 91.6% selectivity to the Fe(IV)=O intermediate oxidation are demonstrated. More importantly, instead of promoting PMS adsorption, the axial N ligand modulates the electron structure of FeN 5 SANs for the lower reaction energy barrier and promotes electron transfer to PMS to produce Fe(IV)=O intermediate with high selectivity. The highlight of the axial N coordination in the nanozymes in this work provides deep insight to guide the design and development of nanozymes nearly to the bio‐enzyme with excellent activity and selectivity.

show abstract

Engineering Atomically Dispersed Cu–N₁S₂ Sites via Chemical Vapor Deposition to Boost Enzyme‐Like Activity for Efficient Tumor Therapy

Xu,

Li,

Han

et al. 2023

Advanced Materials

View full text Add to dashboard Cite

Single‐atom nanozymes (SAzymes), with well‐defined and uniform atomic structures, are an emerging type of natural enzyme mimics. Currently, it is important but challenging to rationally design high‐performance SAzymes and deeply reveal the interaction mechanism between SAzymes and substrate molecules. Herein, this work reports the controllable fabrication of a unique Cu−N1S2‐centred SAzyme (Cu‐N/S‐C) via a chemical vapor deposition‐based sulfur‐engineering strategy. Benefiting from the optimized geometric and electronic structures of single‐atom sites, Cu‐N/S‐C SAzyme shows boosted enzyme‐like activity, especially in catalase‐like activity, with a 13.8‐fold increase in the affinity to hydrogen peroxide (H2O2) substrate and a 65.2‐fold increase in the catalytic efficiency when compared to Cu‐N‐C SAzyme with Cu−N3 sites. Further theoretical studies reveal that the increased electron density around single‐atom Cu is achieved through electron redistribution, and the efficient charge transfer between Cu‐N/S‐C and H2O2 is demonstrated to be more beneficial for the adsorption and activation of H2O2. The as‐designed Cu‐N/S‐C SAzyme possesses an excellent antitumor effect through the synergy of catalytic therapy and oxygen‐dependent phototherapy. This study provides a strategy for the rational design of SAzymes, and the proposed electron redistribution and charge transfer mechanism will help to understand the coordination environment effect of single‐atom metal sites on H2O2‐mediated enzyme‐like catalytic processes.

show abstract

An enzyme-mimic single Fe-N ₃ atom catalyst for the oxidative synthesis of nitriles via C─C bond cleavage strategy

Cited by 45 publications

References 48 publications

Biomass-Derived Single Zn Atom Catalysts: The Multiple Roles of Single Zn Atoms in the Oxidative Cleavage of C–N Bonds

Biomass-Derived Single Zn Atom Catalysts: The Multiple Roles of Single Zn Atoms in the Oxidative Cleavage of C–N Bonds

Axial N Ligand‐Modulated Ultrahigh Activity and Selectivity Hyperoxide Activation over Single‐Atoms Nanozymes

Engineering Atomically Dispersed Cu–N₁S₂ Sites via Chemical Vapor Deposition to Boost Enzyme‐Like Activity for Efficient Tumor Therapy

Contact Info

Product

Resources

About

An enzyme-mimic single Fe-N 3 atom catalyst for the oxidative synthesis of nitriles via C─C bond cleavage strategy

Cited by 45 publications

References 48 publications

Biomass-Derived Single Zn Atom Catalysts: The Multiple Roles of Single Zn Atoms in the Oxidative Cleavage of C–N Bonds

Biomass-Derived Single Zn Atom Catalysts: The Multiple Roles of Single Zn Atoms in the Oxidative Cleavage of C–N Bonds

Axial N Ligand‐Modulated Ultrahigh Activity and Selectivity Hyperoxide Activation over Single‐Atoms Nanozymes

Engineering Atomically Dispersed Cu–N1S2 Sites via Chemical Vapor Deposition to Boost Enzyme‐Like Activity for Efficient Tumor Therapy

Contact Info

Product

Resources

About

An enzyme-mimic single Fe-N ₃ atom catalyst for the oxidative synthesis of nitriles via C─C bond cleavage strategy

Engineering Atomically Dispersed Cu–N₁S₂ Sites via Chemical Vapor Deposition to Boost Enzyme‐Like Activity for Efficient Tumor Therapy