0000000000788486

AUTHOR

Perttu Sippola

showing 5 related works from this author

Comparison of mechanical properties and composition of magnetron sputter and plasma enhanced atomic layer deposition aluminum nitride films

2018

A comparative study of mechanical properties and elemental and structural composition was made for aluminum nitride thin films deposited with reactive magnetron sputtering and plasma enhanced atomic layer deposition (PEALD). The sputtered films were deposited on Si (100), Mo (110), and Al (111) oriented substrates to study the effect of substrate texture on film properties. For the PEALD trimethylaluminum–ammonia films, the effects of process parameters, such as temperature, bias voltage, and plasma gas (ammonia versus N2/H2), on the AlN properties were studied. All the AlN films had a nominal thickness of 100 nm. Time-of-flight elastic recoil detection analysis showed the sputtered films t…

elastic moduliMaterials scienceta22102 engineering and technologySubstrate (electronics)mechanical propertiesNitride01 natural sciencesAtomic layer depositionSputtering0103 physical sciencesTexture (crystalline)Composite materialThin filmta216kemiallinen analyysiAlNsputter deposition010302 applied physicsta114Surfaces and InterfacesSputter deposition021001 nanoscience & nanotechnologyCondensed Matter PhysicsX-ray diffractionfysikaaliset ominaisuudetSurfaces Coatings and FilmsElastic recoil detectionmetrologythin filmsAtomic Layer DepositionmetrologiaALDmechanical testingchemical analysisaluminum nitridesputteringohutkalvot0210 nano-technologyJournal of Vacuum Science & Technology A
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Structural and chemical analysis of annealed plasma-enhanced atomic layer deposition aluminum nitride films

2016

Plasma-enhanced atomic layer deposition was utilized to grow aluminum nitride (AlN) films on Si from trimethylaluminum and N2:H2 plasma at 200 °C. Thermal treatments were then applied on the films which caused changes in their chemical composition and nanostructure. These changes were observed to manifest in the refractive indices and densities of the films. The AlN films were identified to contain light element impurities, namely, H, C, and excess N due to nonideal precursor reactions. Oxygen contamination was also identified in the films. Many of the embedded impurities became volatile in the elevated annealing temperatures. Most notably, high amounts of H were observed to desorb from the…

Materials scienceNanostructureAnnealing (metallurgy)ta221Analytical chemistry02 engineering and technologyNitride01 natural sciencesimpuritiesAtomic layer depositionImpurity0103 physical sciences010302 applied physicsta213Wide-bandgap semiconductorSurfaces and Interfacesatomikerroskasvatus021001 nanoscience & nanotechnologyCondensed Matter PhysicsSurfaces Coatings and FilmsAmorphous solidCarbon filmatomic layer depositionaluminum nitride films0210 nano-technologyepäpuhtaudetJournal of Vacuum Science and Technology A
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Atomic layer deposition of AlN from AlCl3 using NH3 and Ar/NH3 plasma

2018

The atomic layer deposition (ALD) of AlN from AlCl3 was investigated using a thermal process with NH3 and a plasma-enhanced (PE)ALD process with Ar/NH3 plasma. The growth was limited in the thermal process by the low reactivity of NH3, and impractically long pulses were required to reach saturation. Despite the plasma activation, the growth per cycle in the PEALD process was lower than that in the thermal process (0.4A ° vs 0.7A ° ). However, the plasma process resulted in a lower concentration of impurities in the films compared to the thermal process. Both the thermal and plasma processes yielded crystalline films; however, the degree of crystallinity was higher in the plasma process. The…

optical propertiescrystal structureMaterials scienceSiliconta221Analytical chemistrychemistry.chemical_element02 engineering and technologyoptiset ominaisuudet01 natural sciencespiezoelectric filmsAtomic layer depositionCrystallinityImpurity0103 physical sciencesWaferta216010302 applied physicsta114Plasma activationWide-bandgap semiconductorSurfaces and InterfacesPlasmaatomikerroskasvatus021001 nanoscience & nanotechnologyCondensed Matter PhysicsSurfaces Coatings and Filmsdermatologychemistryatomic layer deposition0210 nano-technologyJournal of Vacuum Science and Technology A
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Low-temperature atomic layer deposition of SiO2/Al2O3 multilayer structures constructed on self-standing films of cellulose nanofibrils

2018

In this paper, we have optimized a low-temperature atomic layer deposition (ALD) of SiO 2 using AP-LTO® 330 and ozone (O 3 ) as precursors, and demonstrated its suitability to surface-modify temperature-sensitive bio-based films of cellulose nanofibrils (CNFs). The lowest temperature for the thermal ALD process was 80°C when the silicon precursor residence time was increased by the stop-flow mode. The SiO 2 film deposition rate was dependent on the temperature varying within 1.5–2.2 Å cycle −1 in the temperature range of 80–350°C, respectively. The low-temperature SiO 2 process that resulted was combined with the conventional trimethyl aluminium + H 2 O process in order to prepare thin mul…

Water sensitivityMaterials scienceDiffusion barrierSiliconGeneral Mathematicsta221General Physics and Astronomychemistry.chemical_element02 engineering and technology01 natural sciencesOxygenAtomic layer depositionchemistry.chemical_compoundnanorakenteetHybrid multilayersSiO0103 physical sciencesCelluloseta216diffusion barrierta218low-temperature atomic layer depositionDiffusion barrierLow-temperature atomic layer deposition010302 applied physicsta214ta114water sensitivityta111General Engineeringcellulose nanofibrilsAtmospheric temperature range021001 nanoscience & nanotechnologyhybrid multilayerschemistryChemical engineeringCellulose nanofibrilsohutkalvotSiO20210 nano-technologyLayer (electronics)Water vaporPhilosophical Transactions of the Royal Society A : Mathematical Physical and Engineering Sciences
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Atomic layer deposition of AlN from AlCl3 using NH3 and Ar/NH3 plasma

2018

The atomic layer deposition (ALD) of AlN from AlCl3 was investigated using a thermal process with NH3 and a plasma-enhanced (PE)ALD process with Ar/NH3 plasma. The growth was limited in the thermal process by the low reactivity of NH3, and impractically long pulses were required to reach saturation. Despite the plasma activation, the growth per cycle in the PEALD process was lower than that in the thermal process (0.4 Å vs 0.7 Å). However, the plasma process resulted in a lower concentration of impurities in the films compared to the thermal process. Both the thermal and plasma processes yielded crystalline films; however, the degree of crystallinity was higher in the plasma process. The fi…

crystal structureihotautioppiatomikerroskasvatusoptiset ominaisuudetpiezoelectric films
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