2017
DOI: 10.1002/chem.201700203
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Synthesis of Hexagonal FeMnP Thin Films from a Single‐Source Molecular Precursor

Abstract: The first heterobimetallic phosphide thin film containing iron, manganese, and phosphorus, derived from the single-source precursor FeMn(CO) (μ-PH ), has been prepared using a home-built metal-organic chemical vapor deposition apparatus. The thin film contains the same ratio of iron, manganese, and phosphorus as the initial precursor. The film becomes oxidized when deposited on a quartz substrate, whereas the film deposited on an alumina substrate provides a more homogeneous product. Powder X-ray diffraction c… Show more

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Cited by 10 publications
(15 citation statements)
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“…The Co 2p XPS spectrum is shown in Figure d, where the peaks at 777.3 eV (Co 2p 3/2 ) and 789.3 eV (Co 2p 1/2 ) stem from the Co—P bond in Mn 0.67 Co 1.33 P, the peaks at 781.1 eV (Co 2p 3/2 ) and 796.5 eV (Co 2p 1/2 ) result from Co 2+ and Co 3+ states in the Mn 0.67 Co 1.33 P surface, as well as the peaks at 784.7 eV (Co 2p 3/2 ) and 801.3 eV (Co 2p 1/2 ) result from the spin orbit splitting of Co . The Mn 2p XPS spectrum shown in Figure e only presents four peaks obtained from oxidation states of Mn at 639.9, 644.1, 652.3, and 654.5 eV, which is because of the surface oxidation of Mn 0.67 Co 1.33 P . In addition, the P 2p XPS spectrum shown in Figure f shows two peaks at 128.5 and 133.1 eV, which originate from P in Mn 0.67 Co 1.33 P and phosphate/phosphite (PO 4 − and others) on the surface, respectively .…”
Section: Resultsmentioning
confidence: 99%
“…The Co 2p XPS spectrum is shown in Figure d, where the peaks at 777.3 eV (Co 2p 3/2 ) and 789.3 eV (Co 2p 1/2 ) stem from the Co—P bond in Mn 0.67 Co 1.33 P, the peaks at 781.1 eV (Co 2p 3/2 ) and 796.5 eV (Co 2p 1/2 ) result from Co 2+ and Co 3+ states in the Mn 0.67 Co 1.33 P surface, as well as the peaks at 784.7 eV (Co 2p 3/2 ) and 801.3 eV (Co 2p 1/2 ) result from the spin orbit splitting of Co . The Mn 2p XPS spectrum shown in Figure e only presents four peaks obtained from oxidation states of Mn at 639.9, 644.1, 652.3, and 654.5 eV, which is because of the surface oxidation of Mn 0.67 Co 1.33 P . In addition, the P 2p XPS spectrum shown in Figure f shows two peaks at 128.5 and 133.1 eV, which originate from P in Mn 0.67 Co 1.33 P and phosphate/phosphite (PO 4 − and others) on the surface, respectively .…”
Section: Resultsmentioning
confidence: 99%
“…Both films exhibit a FM and superparamagnetic nature due to their small crystallite sizes. 105 It is important to remark the stability of the Fe 2 P hexagonal phase in all the above-mentioned nanostructures in contrast with the metastable nature of this phase in the bulk compounds, typically requiring a long series of high temperature thermal treatments. Unfortunately, there are no published reports completely dedicated to the influence of size-reduction on the magnetocaloric properties of Fe 2 P or more generally (Mn,Fe) 2 (P,Si).…”
Section: F Fe 2 P Familymentioning
confidence: 99%
“…In this way, Fe 3 P and FeMnP thin films on quartz have been obtained using H 2 Fe 3 (CO) 9 P t Bu and FeMn(CO) 8 (μ-PH 2 ) as precursors. 21,22 The method was extended to afford additional compositional variation by codecomposing isostructural precursors with varying stoichiometry. This yielded (Fe 1-…”
Section: Introductionmentioning
confidence: 99%