Axial Ligand Coordination Tuning of the Electrocatalytic Activity of Iron Porphyrin Electrografted onto Carbon Nanotubes for the Oxygen Reduction Reaction

Zhou, Xin‐You; Xu, Chao; Guo, Pengpeng; Sun, Wei‐Li; Wei, Ping‐Jie; Liu, Jingang

doi:10.1002/chem.202100736

Cited by 33 publications

(26 citation statements)

References 73 publications

(58 reference statements)

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“…Electron paramagnetic resonance spectroscopy confirmed a 5-coordinate thiophene CoTTP complex at low temperature in toluene solution . Fe(II)tetra(pentafluorophenyl) porphyrin electrografted onto carbon nanotubes and axially coordinated with thiophene produced an increased rate of oxygen reduction compared with the porphyrin on nanotubes alone …”

Section: Introductionmentioning

confidence: 93%

In Situ Imaging and Computational Modeling Reveal That Thiophene Complexation with Co(II)porphyrin/Graphite Is Highly Cooperative

et al. 2022

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Scanning tunneling microscopy (STM) was employed to quantitively investigate in situ binding of 3-phenyl thiophene (PhTh) to Co(II)octaethyl porphyrin (CoOEP) supported on highly ordered pyrolytic graphite (HOPG) in fluid solution. To our knowledge, this is the first single-molecule level study of a complexation reaction between a metalloporphyrin and a sulfur base at the solution/solid interface and one of the few examples of thiophene coordination with a d7 transition metal. Real-time imaging experiments revealed that PhTh binds reversibly to HOPG-supported CoOEP at room temperature. The coordination process increases with increasing PhTh concentration. The nearest-neighbor analysis of STM images indicates that the complexation reaction is cooperative. Because PhTh does not bind to CoOEP in solution, the STM results strongly suggest that the presence of HOPG is crucial to observe ligand binding and cooperativity in this system. Periodic plane-wave density functional theory (DFT) computations corroborate that PhTh has low binding affinity toward CoOEP in solution but predict that the ligand can adsorb to CoOEP/HOPG through coordination with S atoms or interact through noncovalent π–π bonding with the porphyrin chromophore. Three possible structures were considered, and DFT theory was used to calculate binding energies and free energies. In solution and on the HOPG surface both a π–π configuration and a η1(S) configuration have similar computed energies. The η1(S) structure shows the largest stabilization in going from the vapor to adsorbed on HOPG. We also show that statistical analysis of nearest neighbors is more sensitive to cooperative binding than is fitting with the Temkin or Langmuir isotherm. The implication is that isotherm fitting alone is insufficient for identifying cooperative binding on surfaces.

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Section: Introductionmentioning

confidence: 93%

In Situ Imaging and Computational Modeling Reveal That Thiophene Complexation with Co(II)porphyrin/Graphite Is Highly Cooperative

et al. 2022

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“…Liu et al constructed a molecular catalyst by modifying iron porphyrin on the surface of multiwall carbon nanotubes (MWCNTs) through axial coordination. [28] They studied the effect of various ligands including S-thiophene, N-imidazole, and Ocarboxylate, of which N-imidazole proved to be the best axial ligand for the composite catalyst with efficient ORR activity. Figure 2a shows the configuration of the N-imidazole-coordinated catalyst.…”

Section: N-containing Ligandsmentioning

confidence: 99%

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

Liu

Yang

et al. 2022

Chemistry A European J

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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.

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“…With this feature taken into consideration, people have paid more attentions to engineering the coordination configuration of the M-N 4 active sites in metallomacrocycles for achieving higher activity. [30][31][32][33][34][35][36][37] For instance, a combined collaborative effect has been achieved between the pyridine axial ligand on carbon substrate surface and the peripheral chlorine substituents of iron phthalocyanine in a 16(Cl)FePc-py-SWCNTs composite, which in turn leaded to an enhanced ORR activity. [38] Moreover, the axial coordination of 2-methylimidazole ligands toward the hemin Fe (III) sites in a hemin-modified UiO-66 MOF film was found to greatly accelerate the charge transfer rate and boost the intrinsic ORR performance.…”

Section: Introductionmentioning

confidence: 99%

“…Since these ligands are tethered directly with the metal active centers, they play an important role in regulating the overall reactivity. With this feature taken into consideration, people have paid more attentions to engineering the coordination configuration of the M‐N 4 active sites in metallomacrocycles for achieving higher activity [30–37] . For instance, a combined collaborative effect has been achieved between the pyridine axial ligand on carbon substrate surface and the peripheral chlorine substituents of iron phthalocyanine in a 16(Cl)FePc‐py‐SWCNTs composite, which in turn leaded to an enhanced ORR activity [38] .…”

Section: Introductionmentioning

confidence: 99%

Engineering the Electronic Structure of Active Centers in Metalloporphyrins to Boost Oxygen Reduction Reaction Activity

Zhou

Xia

2022

ChemElectroChem

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Inspired by the ligand‐promoted high reactivity of the heme active center in cytochrome c oxidase (CcO) toward oxygen reduction reaction (ORR), this work proposes a new strategy for improving the efficiency of metalloporphyrin‐catalyzed ORR. We carried out a comparative study between two graphene/cobalt porphyrin complexes, the rGO/TMPPCo formed by noncovalent π‐π stacking, and the rGO‐Ci/TMPPCo with cobalt porphyrins (TMPPCo) axially coordinated with the 1‐carboimidazole (Ci) ligands on reduced graphene oxide (rGO) surface. The involvement of the axial ligand was found to greatly reduce the ORR overpotential by 120 mV in acidic medium, while hydrodynamic tests revealed an unaltered reaction mechanism. This positive effect of axial ligand has been rationalized by both electronic “push effect” and steric “trans effect”. The results of this work highlight the importance of a rationally engineered electronic structure of active sites in heterogeneous catalysis, providing insights for the fabrication of highly‐efficient ORR electrocatalysts.

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Axial Ligand Coordination Tuning of the Electrocatalytic Activity of Iron Porphyrin Electrografted onto Carbon Nanotubes for the Oxygen Reduction Reaction

Cited by 33 publications

References 73 publications

In Situ Imaging and Computational Modeling Reveal That Thiophene Complexation with Co(II)porphyrin/Graphite Is Highly Cooperative

In Situ Imaging and Computational Modeling Reveal That Thiophene Complexation with Co(II)porphyrin/Graphite Is Highly Cooperative

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

Engineering the Electronic Structure of Active Centers in Metalloporphyrins to Boost Oxygen Reduction Reaction Activity

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