First principles study of oxygen molecule interaction with the graphitic active sites of a boron-doped pyrolyzed Fe–N–C catalyst

Fajrial, Apresio Kefin; Saputro, Adhitya Gandaryus; Agusta, Mohammad Kemal; Rusydi, Febdian; Nugraha, Nugraha; Dipojono, Hermawan Kresno

doi:10.1039/c7cp02390a

Cited by 36 publications

(40 citation statements)

References 40 publications

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“…Structures with the lowest formation energy are those where the B atom is directly bound to the N atom of NiN 4 center, similar to what has been observed in the FeN 4 -G system. 36 We also find that BN substitution lowers the total energy of the system, indicated by a more negative formation energy compared to its corresponding undoped structure, as depicted in Figure 2. For instance, BN substitution on NiN 4 -G lowers the formation energy of the system by 1.25 eV.…”

Section: ■ Results and Discussionmentioning

confidence: 51%

“…We used the previously obtained most stable structure of interior and edge NiN 4 sites to be doped with boron. In determining the position of boron defect, we followed the procedure outlined by Fajrial et al 36 The framework constitutes a stepwise approach of initially substituting a B atom, followed by a N atom. The procedure is reiterated in Section S3.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…The trend is similar to that reported in the BN-doped FeN 4 -G structure where the localized p-orbitals of the B dopant are actively responsible for facilitating the ORR dissociative mechanism. 36 CO 2 Reduction to CO and HCOOH. In this section, we discuss the electrochemical reduction of CO 2 into CO and HCOOH over the previously obtained undoped and BNdoped NiN 4 SAC structures.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…The configuration of additional boron and nitrogen sites on the SACs was located using a stepwise procedure introduced in our previous work. 36 All of the structures were modeled under the Atomic Simulation Environment (ASE) package 44 and visualized using the Visualization for Electronic and Structural Analysis (VESTA) program. 45 The formation energy (E form ) of each structure was calculated using…”

Section: ■ Computational Methodsmentioning

confidence: 99%

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Two-Electron Electrochemical Reduction of CO₂ on B-Doped Ni–N–C Catalysts: A First-Principles Study

et al. 2021

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We evaluate the electrocatalytic activity of graphene-supported NiN4 active center in facilitating two-electron CO2 electrochemical reduction into CO and HCOOH, as well as the competing hydrogen evolution reaction. NiN4 center is found to be more stable in zigzag-edge and armchair-edge proximity of graphene, confirming experimental evidence. In an attempt to reduce the CO2 reduction overpotential, we construct a neighboring-site environment of NiN4 center and BN substitutional defect. B-doped structures are found to be capable of reducing the CO2 reduction energy barrier through direct (HCOOH pathway) or indirect (CO pathway) participation in facilitating CO2 reduction-related key intermediates. In most Ni sites, the presence of adjacent BN site is also discovered to change the product selectivity from CO to HCOOH. Our result predicts that B-doped NiN4 sites on the interior side (NiN4BN-G) and on the armchair-edge side of tilted orientation (t-NiN4BN-AGNR) are HCOOH-selective. Although the rest of zigzag-edge and armchair-edge sites have a tendency to selectively produce CO and HCOOH, respectively, the undesirable hydrogen evolution reaction is found to be more dominant and therefore obscuring the potential. Our result demonstrates that the hydrogen evolution reaction is most likely to occur on top of a neighboring C atom instead of on the Ni center, in contrast to the commonly understood mechanism. To ultimately suppress the activity of the hydrogen evolution reaction, we predict that an effective electrocatalyst optimization cannot be realized by only selecting the best metal center and dopant pair but also by altering the neighbor’s electronic structure.

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Section: ■ Results and Discussionmentioning

confidence: 51%

Section: ■ Results and Discussionmentioning

confidence: 99%

Section: ■ Results and Discussionmentioning

confidence: 99%

Section: ■ Computational Methodsmentioning

confidence: 99%

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Two-Electron Electrochemical Reduction of CO₂ on B-Doped Ni–N–C Catalysts: A First-Principles Study

et al. 2021

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“…Furthermore, they chose the most stable active site configuration, indicating that the active site could reduce the activation energy of oxygen dissociation with DFT calculations. In addition, Fajrial et al 23 reported that the dissociation of O 2 molecule on the boron‐doped FeNC catalyst through density functional theory (DFT). They found that the activation energy of O 2 dissociation on B‐doped FeNC catalyst is half of that on the un‐doped FeN 4 G.…”

Section: Introductionmentioning

confidence: 99%

Mechanisms of oxygen reduction reaction on B doped FeN ₄ G and FeN ₄ CNT catalysts for proton‐exchange membrane fuel cells

Niu

et al. 2021

Int J Energy Res

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Density functional theory (DFT) was used to calculate the stability, oxygen reduction reaction (ORR) mechanism and activity of B-doped FeN 4 CNT (carbon nano-tube [CNT]) and FeN 4 G (G, graphene). The B-doped catalysts are more stable and active than that of the un-doped, especially for FeN 4 B2 G and FeN 4 B2 CNT. Based on the Mulliken charge and electrostatic potential surface of these catalysts, Fe atom is found to be the most active site for the adsorption of O-contained species. It is shown that their adsorption energies decrease in the range: O > OH > Co-ad OH > OOH > O 2 > H 2 O > H 2 O 2 on these catalysts. H 2 O 2 will be directly dissociated into two co-adsorbed OH* or O* + H 2 O* instead of H 2 O 2 on the graphene series catalysts, and the process of reaction (H 2 O 2 + * ! 2OH*) on the active sites of the CNT series catalysts is strongly exothermic. Hence, desorption of H 2 O 2 * into the solution is difficult to proceed during the oxygen reduction process. All the catalysts are expected to promote a single site four electron process through the reaction path of I (O 2 ! O 2 * ! OOH* ! O* ! OH* ! H 2 O) except for the catalyst of FeN 4 CNT. The rate-determining step (RDS) for ORR process on FeN 4 B2 G is the first reduction step (O 2 * ! OOH*), while the RDS is the fourth reduction step (OH* ! H 2 O) for the other catalysts. FeN 4 B2 G exhibits the largest onset potentials of 0.53 V, which is larger than the on-set potential of un-doped B FeN 4 G catalyst (0.39 V). In addition, the B-doped FeN 4 CNT catalyst shows the better activity compared to the un-doped ones.

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Tunable Electronic and Magnetic Properties of Graphene‐Embedded Transition Metal‐N₄ Complexes: Insight From First‐Principles Calculations

Cao

2018

Chemistry An Asian Journal

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Motivated by the development of transition-metal-nitrogen-carbon (TM-N-C) materials for catalysts and molecular electronics, we investigated the electronic and magnetic properties of TMN -graphene materials with different central atoms (TM=Ti, V, Cr, Mn, Fe, Co, Ni and Cu) and different concentrations. The first-principles results show that a widely tunable magnetic moment in the range from 0 to 4 μ can be obtained in this kind of material by varying the central TM atom, and a regular transition of the electronic property from metallic to half-metallic and to semiconducting characteristics is observed in MnN -graphene upon changing the concentration. We find that the peculiar relationship between the electronic characteristics of graphene and its lattice parameters plays a decisive role in determining the electronic and magnetic properties. Our findings are useful for the design of TM-N-C materials for catalysis, spintronics, and molectronics.

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First principles study of oxygen molecule interaction with the graphitic active sites of a boron-doped pyrolyzed Fe–N–C catalyst

Cited by 36 publications

References 40 publications

Two-Electron Electrochemical Reduction of CO₂ on B-Doped Ni–N–C Catalysts: A First-Principles Study

Two-Electron Electrochemical Reduction of CO₂ on B-Doped Ni–N–C Catalysts: A First-Principles Study

Mechanisms of oxygen reduction reaction on B doped FeN ₄ G and FeN ₄ CNT catalysts for proton‐exchange membrane fuel cells

Tunable Electronic and Magnetic Properties of Graphene‐Embedded Transition Metal‐N₄ Complexes: Insight From First‐Principles Calculations

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First principles study of oxygen molecule interaction with the graphitic active sites of a boron-doped pyrolyzed Fe–N–C catalyst

Cited by 36 publications

References 40 publications

Two-Electron Electrochemical Reduction of CO2 on B-Doped Ni–N–C Catalysts: A First-Principles Study

Two-Electron Electrochemical Reduction of CO2 on B-Doped Ni–N–C Catalysts: A First-Principles Study

Mechanisms of oxygen reduction reaction on B doped FeN 4 G and FeN 4 CNT catalysts for proton‐exchange membrane fuel cells

Tunable Electronic and Magnetic Properties of Graphene‐Embedded Transition Metal‐N4 Complexes: Insight From First‐Principles Calculations

Contact Info

Product

Resources

About

Two-Electron Electrochemical Reduction of CO₂ on B-Doped Ni–N–C Catalysts: A First-Principles Study

Two-Electron Electrochemical Reduction of CO₂ on B-Doped Ni–N–C Catalysts: A First-Principles Study

Mechanisms of oxygen reduction reaction on B doped FeN ₄ G and FeN ₄ CNT catalysts for proton‐exchange membrane fuel cells

Tunable Electronic and Magnetic Properties of Graphene‐Embedded Transition Metal‐N₄ Complexes: Insight From First‐Principles Calculations