Gas‐Pulsed CVD for Film Growth in the CuNiN System

Lindahl, Erik; Ottosson, Mikael; Carlsson, Jan‐Otto

doi:10.1002/cvde.201106919

Cited by 8 publications

(4 citation statements)

References 40 publications

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“…The strong growth rate dependence of ammonia on the other hand would indicate a blocking of the surface by the ligands of the metal precursor or by ligand fragments which have a low reactivity against gas phase NH 3 and -NH x surface species. These observations are in line with what has been observed previously for ALD of NiO from Ni(thd) 2 and water precursors where it was also found that large excess of water was needed for saturation (19). The differences in reaction order for the two precursors at the two temperatures indicates different reactions for the The microstructure of the initially formed crystallites for a deposition temperature of 230°C is depicted in fig 4 A-C.…”

Section: Resultssupporting

confidence: 89%

“…The requirement for the metal precursor for Ni 3 N CVD is due to the metastable nature of the deposit and a high reactivity against both -NH x as well as atomic hydrogen at reasonable low temperatures is needed. Surface -NH x are expected to react in a similar way as -OH groups which are known to react with the bis(2,2,6,6-tetramethyl-3,5-heptanedionato)Ni(II) (Ni(thd) 2 ) precursor to produce NiO (19,20). Also the similar Cu(thd) 2 precursor is known to react with surface hydrogen on metallic surfaces (21).…”

Section: Introductionmentioning

confidence: 97%

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Chemical Vapour Deposition of Metastable Ni₃N

2009

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Metastable nickel nitride (Ni3N) has been chemically vapour deposited by the use of bis(2,2,6,6-tetramethyl-3,5-heptanedionato)Ni(II) (Ni(thd)2) and ammonia precursors. The growth on both non-etched Si(100) and amorphous SiO2 is polycrystalline at deposition temperatures between 200-290{degree sign}C. However, at the highest temperatures the impurity level of oxygen and carbon originating from the metal precursor ligand, is about 5%. The growth rate dependence of temperature is divided into three different regions with large differences in activation energies, interpreted as different factors controlling the growth. In addition the deposition rate as a function of precursor supply as well as the incubation time for the growth initiation are different at temperatures which are further indications of differences in reaction mechanism. By substitution of NH3 for H2 to the reactant gas the growth mechanism is shown to occur via surface -NHx groups.

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Section: Resultssupporting

confidence: 89%

Section: Introductionmentioning

confidence: 97%

Chemical Vapour Deposition of Metastable Ni₃N

2009

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“…Time-resolved precursor delivery can also be used to deposit thin films of ternary or quaternary materials. By combining known CVD and ALD chemistries for Cu 3 N and Ni 3 N in a sequential manner separated by NH 3 pulses a ternary solid solution of Cu 3‑x Ni x+y N can be deposited . In contrast, no deposition at all was obtained when using a nonpulsed CVD approach where all precursors were mixed together.…”

Section: Time-resolved Precursor Supply In Cvdmentioning

confidence: 99%

“…By combining known CVD and ALD chemistries for Cu 3 N and Ni 3 N in a sequential manner separated by NH 3 pulses a ternary solid solution of Cu 3-x Ni x+y N can be deposited. 15 In contrast, no deposition at all was obtained when using a nonpulsed CVD approach where all precursors were mixed together. This is speculated to be due to mutual blocking of the surface chemical reactions by the ligands or fragments of the ligands of the metal precursors; Cu(hfac) 2 and Ni(thd) 2 .…”

Section: ■ Introductionmentioning

confidence: 99%

Time as the Fourth Dimension: Opening up New Possibilities in Chemical Vapor Deposition

Pedersen

2016

Chem. Mater.

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Thin films of inorganic materials are essential to several technologies we take for granted in our everyday lives. They form the basis of touch screens in smart phones and the electronic components in computers. Dating back more than a century, chemical vapor deposition (CVD) is one of the most common methods to form these films. In CVD, the atoms needed for the thin film are typically supplied by a continuous flow of gaseous precursor molecules and incorporated into the film by gas phase and surface chemical reactions. The continuous demand for more precise thin film fabrication on more complex shapes at lower temperatures sets a demand for more advanced CVD methods. The development of better designed precursor molecules is one important path to evolve CVD, the other path is to evolve the way in which we do CVD. In this perspective I will describe how using time as a fourth dimension in CVD can enable fabrication of new thin film materials and material structures at lower temperatures and on more complex substrate geometries by accessing new types of CVD chemistries available in time-resolved CVD.

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Easy Access to Ni₃N– and Ni–Carbon Nanocomposite Catalysts

Clavel

Molinari

Kraupner

et al. 2014

Chemistry A European J

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In the search for alternative materials to current expensive catalysts, Ni has been addressed as one of the most promising and, on this trail, its corresponding nitride. However, nickel nitride is a thermally unstable compound, and therefore not easy to prepare especially as nanoparticles. In the present work, a sol-gel-based process (the urea glass route) is applied to prepare well-defined and homogeneous Ni3N and Ni nanoparticles. In both cases, the prepared crystalline nanoparticles (∼25 nm) are dispersed in a carbon matrix forming interesting Ni3N- and Ni-based composites. These nanocomposites were characterised by means of several techniques, such as XRD, HR-TEM, EELS, and the reaction mechanism was investigated by TGA and IR and herein discussed. The catalytic activity of Ni3N is investigated for the first time, to the best of our knowledge, for hydrogenation reactions involving H2, and here compared to the one of Ni. Both materials show good catalytic activities but, interestingly, give a different selectivity between different functional groups (namely, nitro, alkene and nitrile groups).

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Gas‐Pulsed CVD for Film Growth in the CuNiN System

Cited by 8 publications

References 40 publications

Chemical Vapour Deposition of Metastable Ni₃N

Chemical Vapour Deposition of Metastable Ni₃N

Time as the Fourth Dimension: Opening up New Possibilities in Chemical Vapor Deposition

Easy Access to Ni₃N– and Ni–Carbon Nanocomposite Catalysts

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Gas‐Pulsed CVD for Film Growth in the CuNiN System

Cited by 8 publications

References 40 publications

Chemical Vapour Deposition of Metastable Ni3N

Chemical Vapour Deposition of Metastable Ni3N

Time as the Fourth Dimension: Opening up New Possibilities in Chemical Vapor Deposition

Easy Access to Ni3N– and Ni–Carbon Nanocomposite Catalysts

Contact Info

Product

Resources

About

Chemical Vapour Deposition of Metastable Ni₃N

Chemical Vapour Deposition of Metastable Ni₃N

Easy Access to Ni₃N– and Ni–Carbon Nanocomposite Catalysts