0000000000670098

AUTHOR

Jolien Dendooven

showing 6 related works from this author

Atomic layer deposition of ternary ruthenates by combining metalorganic precursors with RuO4 as the co-reactant

2022

In this work, the use of ruthenium tetroxide (RuO4) as a co-reactant for atomic layer deposition (ALD) is reported. The role of RuO4 as a co-reactant is twofold: it acts both as an oxidizing agent and as a Ru source. It is demonstrated that ALD of a ternary Ru-containing metal oxide (i.e. a metal ruthenate) can be achieved by combining a metalorganic precursor with RuO4 in a two-step process. RuO4 is proposed to combust the organic ligands of the adsorbed precursor molecules while also binding RuO2 to the surface. As a proof of concept two metal ruthenate processes are developed: one for aluminum ruthenate, by combining trimethylaluminum (TMA) with RuO4; and one for platinum ruthenate, by c…

Materials scienceHydrogenRUTHENIUMOXIDE THIN-FILMSDIFFUSION BARRIERInorganic chemistryOxidechemistry.chemical_elementAmorphous solidInorganic ChemistryChemistryAtomic layer depositionchemistry.chemical_compoundPhysics and AstronomychemistryALUMINUM-OXIDEOxidizing agentThin filmPlatinumTernary operationDalton Transactions
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A liquid alkoxide precursor for the atomic layer deposition of aluminum oxide films

2020

For large-scale atomic layer deposition (ALD) of alumina, the most commonly used alkyl precursor trimethylaluminum poses safety issues due to its pyrophoric nature. In this work, the authors have investigated a liquid alkoxide, aluminum tri-sec-butoxide (ATSB), as a precursor for ALD deposition of alumina. ATSB is thermally stable and the liquid nature facilitates handling in a bubbler and potentially enables liquid injection toward upscaling. Both thermal and plasma enhanced ALD processes are investigated in a vacuum type reactor by using water, oxygen plasma, and water plasma as coreactants. All processes achieved ALD deposition at a growth rate of 1-1.4 angstrom/cycle for substrate tempe…

DECOMPOSITIONMaterials scienceSubstrate (electronics)Chemical vapor depositionEPITAXYEpitaxyPyrophoricitychemistry.chemical_compoundAtomic layer depositionTHIN-FILMSDeposition (phase transition)alumiiniThin filmTEMPERATUREplasma processingAL2O3Surfaces and InterfacesatomikerroskasvatusCondensed Matter PhysicsSurfaces Coatings and FilmsChemistryCHEMICAL-VAPOR-DEPOSITIONPhysics and AstronomySINGLEchemistryChemical engineeringALDatomic layer depositionAlkoxideGROWTHohutkalvotJournal of Vacuum Science & Technology A
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Atomic Layer Deposition of Localized Boron- and Hydrogen-Doped Aluminum Oxide Using Trimethyl Borate as a Dopant Precursor

2020

Atomic layer deposition (ALD) of boron-containing films has been mainly studied for use in two-dimensional materials and for B doping of Si. Furthermore, lithium-containing borates show great promi...

Materials scienceHydrogenDopantGrapheneTrimethyl borateGeneral Chemical EngineeringInorganic chemistryDopingchemistry.chemical_element02 engineering and technologyGeneral ChemistryNitride010402 general chemistry021001 nanoscience & nanotechnology01 natural sciences0104 chemical scienceslaw.inventionAtomic layer depositionchemistry.chemical_compoundchemistrylawMaterials Chemistry0210 nano-technologyBoronChemistry of Materials
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Reaction pathways for atomic layer deposition with lithium hexamethyl disilazide, trimethyl phosphate, and oxygen plasma

2020

Atomic layer deposition (ALD) of lithium-containing films is of interest for the development of next-generation energy storage devices. Lithium hexamethyl disilazide (LiHMDS) is an established precursor to grow these types of films. The LiHMDS molecule can either be used as a single-source precursor molecule for lithium or as a dual-source precursor molecule for lithium and silicon. Single-source behavior of LiHMDS is observed in the deposition process with trimethylphosphate (TMP) resulting in the deposition of crystalline lithium phosphate (Li3PO4). In contrast, LiHMDS exhibits dual-source behavior when combined with O2 plasma, resulting in a lithium silicate. Both processes were characte…

Materials scienceInorganic chemistryReaction productschemistry.chemical_elementEnergy storageCoatings and FilmsPlasmaAtomic layer depositionchemistry.chemical_compoundElectronicOptical and Magnetic MaterialsPhysical and Theoretical ChemistryOXIDESPrecursorsALUMINUM PHOSPHATEMoleculesatomikerroskasvatusSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsTrimethyl phosphateSurfacesChemistryGeneral EnergylitiumchemistryOxygen plasmaLithiumAdsorptionohutkalvotALUMINUM PHOSPHATE
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The co-reactant role during plasma enhanced atomic layer deposition of palladium

2020

Atomic layer deposition (ALD) of noble metals is an attractive technology potentially applied in nanoelectronics and catalysis. Unlike the combustion-like mechanism shown by other noble metal ALD processes, the main palladium (Pd) ALD process using palladium(ii)hexafluoroacetylacetonate [Pd(hfac)2] as precursor is based on true reducing surface chemistry. In this work, a thorough investigation of plasma-enhanced Pd ALD is carried out by employing this precursor with different plasmas (H2*, NH3*, O2*) and plasma sequences (H2* + O2*, O2* + H2*) as co-reactants at varying temperatures, providing insights in the co-reactant and temperature dependence of the Pd growth per cycle (GPC). At all te…

Materials scienceHydrogenAnnealing (metallurgy)Inorganic chemistryGeneral Physics and Astronomychemistry.chemical_element02 engineering and technologyengineering.material010402 general chemistry021001 nanoscience & nanotechnology01 natural sciences0104 chemical sciencesCatalysisAtomic layer depositionchemistryX-ray photoelectron spectroscopyImpurityengineeringNoble metalPhysical and Theoretical Chemistry0210 nano-technologyPalladiumPhysical Chemistry Chemical Physics
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Atomic layer deposition of localised boron- and hydrogen-doped aluminium oxide using trimethyl borate as a dopant precursor

2020

Atomic layer deposition (ALD) of boron-containing films has been mainly studied for use in 2D materials and for B-doping of Si. Furthermore, lithium-containing borates show great promise as solid electrolyte coatings for enhanced energy storage. In this work, we examine trimethyl borate (TMB) and triethyl borate (TEB) in combination with O2 plasma as precursors for ALD of B-containing films, targeting the growth of B2O3. It is found that films grown from TEB contain no boron. Further work with TMB as a boron-containing precursor showed promising initial growth on a SiO2 or Al2O3 surface, but a rapid decrease of the growth rate during subsequent ALD cycles indicating surface inhibition durin…

trimethyl borateenergy storageatomic layer depositiontiethyl borateelectrolyte coatingsatomikerroskasvatus
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