Nanoscale Iron Nitride, ε-Fe<sub>3</sub>N: Preparation from Liquid Ammonia and Magnetic Properties

Zieschang, Anne-Marie; Bocarsly, Joshua D.; Dürrschnabel, Michael; Molina‐Luna, Leopoldo; Kleebe, Hans‐Joachim; Seshadri, Ram; Albert, Barbara

doi:10.1021/acs.chemmater.6b04088

Cited by 48 publications

(38 citation statements)

References 50 publications

(102 reference statements)

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“…The Fe 3 N and Ta 5 N 6 crystals grown on other facets of substrates show polycrystalline features as further confirmed by X-ray diffraction (XRD) patterns (Figures S1 and S2, Supporting Information). [14] The single-crystalline structure is further confirmed by selected area electron diffraction pattern with a diameter of ≈1 µm in the inset of Figure 2a. Figure The crystalline structure of Fe 3 N single crystal is investigated using Cs-corrected scanning transmission electron microscopy (STEM) coupled with focused ion beam.…”

Section: Metallic Porous Single Crystalsmentioning

confidence: 67%

Metallic Porous Iron Nitride and Tantalum Nitride Single Crystals with Enhanced Electrocatalysis Performance

Zhang

Lin

et al. 2018

Advanced Materials

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Previous studies show that the metalnitrogen moieties with unsaturated nitrogen coordination numbers possess higher catalytic activities and the reported smallest nitrogen coordination number is confirmed to be ≈2 for Co-N 2 and Fe-N 2 moieties using extended X-ray absorption fine structure spectra analysis. [4][5][6] These results indeed give an in-depth insight at the atomic level into structural dependence of catalytic activity of metal nitride nanoparticles by closely correlating the average structural information with catalytic performances. However, the active metalnitrogen moieties confined at the surface layer of materials that host catalysis reactions still remain unclear.Building metal-nitrogen moieties with unsaturated nitrogen coordination numbers to enhance material's catalytic activity remains a fundamental challenge. The state-of-the-art pyrolysis technique of specific precursors is commonly used to construct metal-nitrogen moieties. However, the simultaneous presence of multiple metal species in most composite catalysts makes it highly complex to understand the nature of metal-nitrogen moieties. [7][8][9][10] The short length scale of nanostructured catalysts makes it extremely challenging to quantify metal-nitrogen moiety structure and distributions and to correspondingly elucidate the electronic structure features and unusual activity. The metal-nitrogen moieties are indeed a kind of active clusters at atomic level, which are strictly confined at lattice in local structures in crystalline composites. The polycrystalline or amorphous states of composites make it highly uncertain to construct resolved metal-nitrogen moieties and to accordingly expose these active centers on material's surfaces to host catalysis reactions. Another consideration should be given to the resolved structural feature and chemical composition of moieties that tailor electronic structures to facilitate catalysis functionalities.Single crystals with porosity, combining the advantages of long-range structural coherence of bulk crystals and large surface areas of porous materials, could provide opportunities to host the metal-nitrogen moieties with unsaturated nitrogen coordination on surface. The long-range structural coherence in single crystals offers the possibility to stabilize the metalnitrogen moieties in lattice of local structures on crystalline surfaces especially on the condition that the surface moieties have similar chemical compositions to bulk crystals. Porous Altering a material's catalytic properties would require identifying structural features that deliver electrochemically active surfaces. Single-crystalline porous materials, combining the advantages of long-range ordering of bulk crystals and large surface areas of porous materials, would create sufficient active surfaces by stabilizing 2D active moieties confined in lattice and may provide an alternative way to create high-energy surfaces for electrocatalysis that are kinetically trapped. Here, a radical concept of building active metalnitrogen moieties ...

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Section: Metallic Porous Single Crystalsmentioning

confidence: 67%

Metallic Porous Iron Nitride and Tantalum Nitride Single Crystals with Enhanced Electrocatalysis Performance

Zhang

Lin

et al. 2018

Advanced Materials

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“…[20,21] It demonstrates the N-doping in carbond uring the nitridation process. [10] The peak at 707.3 eV is considered as metallic iron nitride (g'-Fe 4 N). [22,23] It is confirmed that the F-1 :2.5 600 contains ac ertain amount of carbon and furtherp rovest hat heteroatoms (O and N) are dopedi nto the Chem.E ur.J.2017, 23,17592 -17597 www.chemeurj.org carbon.I na ddition, the high-resolution Fe 2p spectrum is shown in Figure 5d.I tc an be clearly observed that the Fe 2p spectrum consists of five peaks:t he peaks at 710.0 and 713.0 eV are ascribed to Fe 2p 3/2 of Fe 2 + and Fe 3 + ,a nd the peaks at 724.5 and 726.4 eV are ascribed to Fe 2p 1/2 of Fe 2 + and Fe 3 + .…”

Section: Resultsmentioning

confidence: 99%

“…Thus, this iron oxide is an amorphous iron oxide.B ased on previousr eports, this amorphous iron oxide is iron monoxide (Fe 1-x O). [10] The peak at 707.3 eV is considered as metallic iron nitride (g'-Fe 4 N). [25] Additionally,t he XPS spectra of F-1 :2.5 580 and F-1 :2.5 620 are shown in Figure S5.…”

Section: Resultsmentioning

confidence: 99%

“…[6][7][8][9][10][11][12][13] Generally,i ron nitridee xhibits ferromagnetism at room temperature, with high saturation magnetization and high magnetic moment. [6][7][8][9][10][11][12][13] Generally,i ron nitridee xhibits ferromagnetism at room temperature, with high saturation magnetization and high magnetic moment.…”

Section: Introductionmentioning

confidence: 99%

“…Recently,t he research of iron nitride was mainly concentrated on the electrochemical catalysis and magnetism. [6][7][8][9][10][11][12][13] Generally,i ron nitridee xhibits ferromagnetism at room temperature, with high saturation magnetization and high magnetic moment. Owing to the difference of nitrogen content and crystal structure,t he magnetic moment of the ferromagnetic iron nitride shows certain differences.…”

Section: Introductionmentioning

confidence: 99%

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Magnetic γ′‐Fe₄N/Fe₃C, χ‐Fe₅C₂, and θ‐Fe₃C by a Simple Route for Application as Electrochemical Catalysts

Lei

Zhao

et al. 2017

Chemistry A European J

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An ew and simple methodt of abricate magnetic Fe 4 N/Fe 3 Cs amples is reported.M eanwhile, pure phase iron carbides (q-Fe 3 Ca nd c-Fe 5 C 2 )w ere obtained by controlling experimental conditions.T he structures, magnetic properties, and morphology of the samples were investigated according to the generalized analysiso fX -ray diffraction,X -ray photoelectrons pectroscopy,a sw ell as transmission electron microscopy and vibrating sample magnetometry.T he magnetic properties measurement revealed the remarkable magnetic properties of the samples at 2a nd 300 K. The application of the prepared samples as catalysts for oxygen evolution reactionw as also investigated in alkaline solution.T his simple and convenient route provides an ew path to fabricate other metal nitrides and carbides.

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Emergent Magnetic States and Tunable Exchange Bias at 3d Nitride Heterointerfaces

et al. 2022

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Interfacial magnetism stimulates the discovery of giant magnetoresistance (MR) and spin–orbital coupling across the heterointerfaces, facilitating the intimate correlation between spin transport and complex magnetic structures. Over decades, functional heterointerfaces composed of nitrides have seldom been explored due to the difficulty in synthesizing high‐quality nitride films with correct compositions. Here, the fabrication of single‐crystalline ferromagnetic Fe3N thin films with precisely controlled thicknesses is reported. As film thickness decreases, the magnetization dramatically deteriorates, and the electronic state changes from metallic to insulating. Strikingly, the high‐temperature ferromagnetism is maintained in a Fe3N layer with a thickness down to 2 u.c. (≈8 Å). The MR exhibits a strong in‐plane anisotropy; meanwhile, the anomalous Hall resistivity reverses its sign when the Fe3N layer thickness exceeds 5 u.c. Furthermore, a sizable exchange bias is observed at the interfaces between a ferromagnetic Fe3N and an antiferromagnetic CrN. The exchange bias field and saturation moment strongly depend on the controllable bending curvature using the cylinder diameter engineering technique, implying the tunable magnetic states under lattice deformation. This work provides a guideline for exploring functional nitride films and applying their interfacial phenomena for innovative perspectives toward practical applications.

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Nanoscale Iron Nitride, ε-Fe₃N: Preparation from Liquid Ammonia and Magnetic Properties

Cited by 48 publications

References 50 publications

Metallic Porous Iron Nitride and Tantalum Nitride Single Crystals with Enhanced Electrocatalysis Performance

Metallic Porous Iron Nitride and Tantalum Nitride Single Crystals with Enhanced Electrocatalysis Performance

Magnetic γ′‐Fe₄N/Fe₃C, χ‐Fe₅C₂, and θ‐Fe₃C by a Simple Route for Application as Electrochemical Catalysts

Emergent Magnetic States and Tunable Exchange Bias at 3d Nitride Heterointerfaces

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Nanoscale Iron Nitride, ε-Fe3N: Preparation from Liquid Ammonia and Magnetic Properties

Cited by 48 publications

References 50 publications

Metallic Porous Iron Nitride and Tantalum Nitride Single Crystals with Enhanced Electrocatalysis Performance

Metallic Porous Iron Nitride and Tantalum Nitride Single Crystals with Enhanced Electrocatalysis Performance

Magnetic γ′‐Fe4N/Fe3C, χ‐Fe5C2, and θ‐Fe3C by a Simple Route for Application as Electrochemical Catalysts

Emergent Magnetic States and Tunable Exchange Bias at 3d Nitride Heterointerfaces

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Nanoscale Iron Nitride, ε-Fe₃N: Preparation from Liquid Ammonia and Magnetic Properties

Magnetic γ′‐Fe₄N/Fe₃C, χ‐Fe₅C₂, and θ‐Fe₃C by a Simple Route for Application as Electrochemical Catalysts