Structural and magnetic properties of Co-N thin films deposited using magnetron sputtering at 523 K

et al. 2019

Phys. Rev. B

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In this work, we measured N self-diffusion in the Co-N system and found an unexpected result that N diffuses out almost completely around 500 K, leaving behind fcc Co irrespective of the amount of N used to deposit Co-N. On the other hand, in previous attempts the Co 4 N phase has always been grown at 550 K or above. In view of our finding, it appears that fcc Co could have been mistaken for Co 4 N, probably due to the closeness of their lattice parameters (LP; fcc Co = 3.54 Å, Co 4 N= 3.74 Å). Therefore, Co 4 N -an interesting material for its high spin-polarization ratio and high magnetic moment remained unexplored. By bringing down the growth temperature, we report the growth of stoichiometric Co 4 N epitaxial thin films. Films were grown using a direct current reactive magnetron sputtering process on LaAlO 3 (LAO mismatch 1.4%) and MgO (mismatch 11.3%) substrates and their structural and magnetic properties were studied. Precise magnetic moment (M s ) of Co 4 N samples were measured using polarized neutron reflectivity and compared with bulk magnetization results. We found that the M s of Co 4 N is higher due to a magnetovolume effect. Unlike previous findings, we observed that substrates induce misfit strain and strain inhomogeneity is the cause of modifications in magnetic ensemble such as coercivity, saturation magnetization, and magnetic anisotropy. A consequence of incoherent strain present in our samples is also reflected in the magnetic anisotropy leading to a superposition of strong fourfold and a small fraction of uniaxial magnetic anisotropy. Obtained results are presented and discussed in this work.

Section: Resultssupporting

confidence: 61%

Section: Resultsmentioning

confidence: 44%

Section: Resultsmentioning

confidence: 62%

Section: Methodsmentioning

confidence: 99%

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Structural and magnetic properties of stoichiometric Co4N epitaxial thin films

et al. 2019

Phys. Rev. B

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“…Theoretical values of enthalpy of formation (∆H • f ) for Fe 4 N is about -12 kJ mol −1 [22], whereas those for Co 4 N are slightly above or below 0 for hcp Co or fcc Co [11]. This also implies that at a higher T s , Co 4 N system will be less stable as compared to Fe 4 N. In a recent work, we studied the phase formation process in the Co-N system at T s = 300 K [23] and 523 K [24]. We found that at T s = 523 K, N incorporation in the Co-N system is minimal and the phases formed are similar to a fcc Co having LP∼3.52Å.…”

Section: Introductionmentioning

confidence: 99%

Structure and magnetization of Co4N thin film

Journal of Magnetism and Magnetic Materials

et al. 2018

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In this work, we studied the local structure and the magnetization of Co 4 N thin films deposited by a reactive dc magnetron sputtering process. The interstitial incorporation of N atoms in a fcc Co lattice is expected to expand the structure and such expansion yields interesting magnetic properties characterized by a larger than Co magnetic moment and a very high value of spin polarization ratio in Co 4 N. By optimizing the growth conditions, we prepared Co 4 N film having lattice parameter close to its theoretically predicted value. The N concentration was measured using secondary ion mass spectroscopy. Detailed magnetization measurements using bulk magnetization method and polarized neutron reflectivity confirm that the magnetic moment of Co in Co 4 N is higher than that of Co.

Structure, Thermal Stability, and Magnetism of Ni₄N Thin Films

Physica Rapid Research Ltrs

Stahn

2020

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Herein, the synthesis, structure, thermal stability, and magnetic properties of Ni 4 N thin films are studied. Ni 4 N is difficult to synthesize in the correct chemical order and stoichiometry due to unfavorable thermodynamics. During the synthesis of Ni-N thin films, it is found that the substrate temperature (T s) is a critical parameter affecting the growth of a Ni 4 N phase. The Ni 4 N phase transforms into an amalgamation of [NiþNi 3 N] phases even if the T s rises just above 300 K. These results elucidate a correlation between atomic diffusion and T s. N self-diffusion measurements carried out using secondary-ion mass spectroscopy indicate that substantial N self-diffusion is occurring at low T s. A comparison of N self-diffusion coefficients in Fe-N, CoN , and Ni-N indicates that N self-diffusion in Ni-N lies between that of Fe-N and CoN and exhibits a greater correlation with the enthalpy of formation. A transformation from the cubic-to-tetragonal deformation in the Ni 4 N crystal lattice as a function of increasing N concentration is evident from the X-ray diffraction and X-ray absorption near-edge spectroscopy measurements. Magnetization measurements confirm a nonferromagnetic state of Ni 4 N at 300 K, which transforms into a ferromagnetic state at 15 K.