Boosting Electrochemical Oxygen Reduction Performance of Iron Phthalocyanine through Axial Coordination Sphere Interaction

Zhang, Wenlin; Meeus, Eva J.; Wang, Lei; Zhang, Luhua; Yang, Shuangcheng; Bruin, Bas de; Reek, Joost N. H.; Yu, Fengshou

doi:10.1002/cssc.202102379

Cited by 32 publications

(29 citation statements)

References 62 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…24 25−27 In another study, Zhang et al reported molecular iron phthalocyanine supported on functionalized multiwalled carbon nanotubes (CNTs) and obtained an N−Fe−N 4 site with the axial N atom coordinated to the FeN 4 and CNTs, yielding enhanced ORR performance in comparison to the nonfunctionalized FePc/CNT and stateof-the-art Pt/C catalyst. 28 Several theoretical studies have suggested that the activity of Fe−N 4 SACs is restricted by the strong binding of reaction intermediate (e.g., OH*) on the single Fe site, and the introduction of an axial coordination effect can decrease the orbital hybridization of Fe active center with ORR intermediates, leading to accelerated ORR activity. 29−32 It is worth noting that most of the current theoretical understanding of the ORR activity was based on the charge-neutral model (CNM), which keeps constant charge and neglects the surface charge effect.…”

Section: ■ Introductionmentioning

confidence: 99%

Axial Coordination Effect on the Oxygen Reduction Reaction of FeN₄ Electrocatalysts Based on Grand Canonical Density Functional Theory

Zhou

Tang

2022

J. Phys. Chem. C

View full text Add to dashboard Cite

The Fe–N–C materials are promising noble-free alternatives to Pt-based oxygen reduction reaction (ORR) electrocatalysts. Identifying the actual active structure of FeN4-based moieties is helpful for the regulation and design of high-performance electrocatalysts. However, the current theoretical researches were mostly based on the charge-neutral model (CNM), which cannot accurately describe the electrochemical interface. Herein, we employed the constant potential based grand canonical density functional theory (GC-DFT) computations to study the ORR mechanism of axially decorated FeN4 electrocatalysts. We studied around ten types of axial ligands, and the constant potential energetics and microkinetic modeling demonstrated that the Fe center can exhibit excellent activity for boosting the four-electron ORR via covalently linked −NH2 ligand. The lowering of the antibonding d z 2 –p z orbital is responsible for weakening the adsorption of oxygen in FeN4–Ls to promote ORR activity, and the −NH2 decoration led to the lowest antibonding orbital energy. In particular, the adsorption free energy (ΔG*O2) and O–O bond length (L O–O) of the adsorbed O2 reactant can be used as the effective energetic and geometric descriptors to describe the ORR activity of FeN4–Ls electrocatalysts. Our results not only elucidate the axial coordination effect on the ORR performance of FeN4 SACs but also demonstrate the importance of electrode potential in computational electrochemistry.

show abstract

Section: ■ Introductionmentioning

confidence: 99%

Axial Coordination Effect on the Oxygen Reduction Reaction of FeN₄ Electrocatalysts Based on Grand Canonical Density Functional Theory

Zhou

Tang

2022

J. Phys. Chem. C

View full text Add to dashboard Cite

show abstract

“…This work explored the axial coordination effect of different electron donating groups on the Fe center of FePc. The −NH 2 axial ligand is the most electron‐donating, which endowed the FePc with the highest ORR activity, including a positive onset potential of 1.0 V versus RHE and a half‐wave potential ( E 1/2 ) of 0.92 V versus RHE [31] . DFT study evidenced that the electron‐donating ligands could facilitate the adsorption and activation of O 2 .…”

Section: Axial Coordination Modification Of Sacsmentioning

confidence: 97%

“…The À NH 2 axial ligand is the most electron-donating, which endowed the FePc with the highest ORR activity, including a positive onset potential of 1.0 V versus RHE and a half-wave potential (E 1/2 ) of 0.92 V versus RHE. [31] DFT study evidenced that the electrondonating ligands could facilitate the adsorption and activation of O 2 . Inspired by the biosystems, Liu and co-workers designed an ORR electrocatalyst by covalently attaching an axial imidazolecoordinated porphyrin to MWCNTs.…”

Section: N-containing Ligandsmentioning

confidence: 99%

“…Yu et al. first modified ligands such as −NH 2 , −OH and −COOH on the surface of commercial MWCNTs, which subsequently axially coordinated with the Fe active center of FePc (Figure 2c) [31] . This work explored the axial coordination effect of different electron donating groups on the Fe center of FePc.…”

Section: Axial Coordination Modification Of Sacsmentioning

confidence: 99%

“…Yu et al first modified ligands such as À NH 2 , À OH and À COOH on the surface of commercial MWCNTs, which subsequently axially coordinated with the Fe active center of FePc (Figure 2c). [31] This work explored the axial coordination effect of different electron donating groups on the Fe center of FePc. The À NH 2 axial ligand is the most electron-donating, which endowed the FePc with the highest ORR activity, including a positive onset potential of 1.0 V versus RHE and a half-wave potential (E 1/2 ) of 0.92 V versus RHE.…”

Section: N-containing Ligandsmentioning

confidence: 99%

See 2 more Smart Citations

Controlled Modification of Axial Coordination for Transition‐Metal Single‐Atom Electrocatalyst

Liu

Yang

et al. 2022

Chemistry A European J

View full text Add to dashboard Cite

Single-atom catalysts (SACs) have emerged as a new frontier in areas such as electrocatalysis, photocatalysis, and enzymatic catalysis. Aided by recent advances in the synthetic methodologies of nanomaterials, atomic characterization technologies, and theoretical calculation modeling, various SACs have been prepared for a variety of catalytic reactions. To meet the requirements of SACs with distinctive performance and appreciable selectivity, much research has been carried out to adjust the coordination configuration and electronic properties of SACs. This concept summarizes the latest advances in the experimental and computational efforts aimed at tuning the axial coordination of SACs. Series of atoms, functional groups or even macrocycles are oriented into the atomic metal center, and how this affects the electrocatalytic performance is also reviewed. Finally, this concept presents perspectives for the further precise design, preparation and in-situ detection of axially coordinated SACs.

show abstract

Electronic States Regulation Induced by the Synergistic Effect of Cu Clusters and Cu‐S₁N₃ Sites Boosting Electrocatalytic Performance

Zhan

Chen

et al. 2023

Adv Funct Materials

Self Cite

View full text Add to dashboard Cite

The precise coordination environment manipulation and interfacial electron redistribution are significant strategies for the modulation of electronic configuration and intermediates adsorption behaviors, while the complex synergistic effect is yet to materialize due to the lack of catalyst platform. Herein, an atomic-scale catalyst platform containing single Cu site with tunable coordination environment (Cu-N 4 or Cu-S 1 N 3 ) and easy decoration of Cu cluster (Cu x ) for electrochemical O 2 reduction reaction (ORR) is reported. Theoretical analysis shows that the charge redistribution and up-shifting d-band center of single Cu site induced by the asymmetrical coordination environment and Cu x effectively strength *OOH adsorption. The modulation in intermediates adsorption enables Cu-S 1 N 3 /Cu x a superior ORR performance compared with the samples without S atom and/or Cu x . Moreover, the adsorption behavior of *OOH and d-band center of single Cu site tuned by coordination environment and interfacial interactions are correlated linearly with catalytic potential, e.g., half-wave potential and reaction kinetic, e.g., Tafel slope for ORR, indicating the high applicability of the intermediate adsorption strength and d-band center as the indicators for catalytic performance. This study provides a comprehensive modulation strategy for electron configuration and intermediates adsorption behaviors, and can be extended to facilitate other protoncoupled electron transfer reactions.

show abstract

Boosting Electrochemical Oxygen Reduction Performance of Iron Phthalocyanine through Axial Coordination Sphere Interaction

Cited by 32 publications

References 62 publications

Axial Coordination Effect on the Oxygen Reduction Reaction of FeN₄ Electrocatalysts Based on Grand Canonical Density Functional Theory

Axial Coordination Effect on the Oxygen Reduction Reaction of FeN₄ Electrocatalysts Based on Grand Canonical Density Functional Theory

Controlled Modification of Axial Coordination for Transition‐Metal Single‐Atom Electrocatalyst

Electronic States Regulation Induced by the Synergistic Effect of Cu Clusters and Cu‐S₁N₃ Sites Boosting Electrocatalytic Performance

Contact Info

Product

Resources

About

Boosting Electrochemical Oxygen Reduction Performance of Iron Phthalocyanine through Axial Coordination Sphere Interaction

Cited by 32 publications

References 62 publications

Axial Coordination Effect on the Oxygen Reduction Reaction of FeN4 Electrocatalysts Based on Grand Canonical Density Functional Theory

Axial Coordination Effect on the Oxygen Reduction Reaction of FeN4 Electrocatalysts Based on Grand Canonical Density Functional Theory

Controlled Modification of Axial Coordination for Transition‐Metal Single‐Atom Electrocatalyst

Electronic States Regulation Induced by the Synergistic Effect of Cu Clusters and Cu‐S1N3 Sites Boosting Electrocatalytic Performance

Contact Info

Product

Resources

About

Axial Coordination Effect on the Oxygen Reduction Reaction of FeN₄ Electrocatalysts Based on Grand Canonical Density Functional Theory

Axial Coordination Effect on the Oxygen Reduction Reaction of FeN₄ Electrocatalysts Based on Grand Canonical Density Functional Theory

Electronic States Regulation Induced by the Synergistic Effect of Cu Clusters and Cu‐S₁N₃ Sites Boosting Electrocatalytic Performance