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Crystallinity of inorganic films grown by atomic layer deposition: Overview and general trendsAtomic layer epitaxy - a valuable tool for nanotechnology?Phosphopeptide enrichment with stable spatial coordination on a titanium dioxide coated glass slide.Synthesis and characterisation of cyclopentadienyl complexes of barium: precursors for atomic layer deposition of BaTiO3.Advanced thin film technology for ultrahigh resolution X-ray microscopy.Fabrication of nanocluster silicon surface with electric discharge and the application in desorption/ionization on silicon-mass spectrometry.Nanofocusing of hard X-ray free electron laser pulses using diamond based Fresnel zone platesFollowing the dynamics of matter with femtosecond precision using the X-ray streaking method.X-ray ptychographic computed tomography at 16 nm isotropic 3D resolution.Osteoclasts in the interface with electrospun hydroxyapatite.Atomic layer deposition chemistry: recent developments and future challenges.Atomic layer deposition of oxide thin films with metal alkoxides as oxygen sourcesMolecular organization of the tear fluid lipid layer.Beam-induced damage on diffractive hard X-ray opticsStudy of bismuth alkoxides as possible precursors for ALD.Liposomes for entrapping local anesthetics: a liposome electrokinetic chromatographic study.Reaction mechanism studies on atomic layer deposition of Nb2O5 from Nb(OEt)5 and water.Destruction of Deinococcus geothermalis biofilm by photocatalytic ALD and sol-gel TiO2 surfaces.Programming nanostructured soft biological surfaces by atomic layer deposition.TiO2 Photocatalysis-DESI-MS Rotating Array Platform for High-Throughput Investigation of Oxidation Reactions.Atomic Layer Deposition of Rhenium Disulfide.Metal oxide multilayer hard mask system for 3D nanofabrication.Ta2O5- and TiO2-based nanostructures made by atomic layer deposition.Inert ambient annealing effect on MANOS capacitor memory characteristics.Surface modification of acetaminophen particles by atomic layer deposition.Integrated photocatalytic micropillar nanoreactor electrospray ionization chip for mimicking phase I metabolic reactions.Preparation and bioactive properties of nanocrystalline hydroxyapatite thin films obtained by conversion of atomic layer deposited calcium carbonate.Nucleation and Conformality of Iridium and Iridium Oxide Thin Films Grown by Atomic Layer Deposition.Osteogenic and osteoclastogenic differentiation of co-cultured cells in polylactic acid-nanohydroxyapatite fiber scaffolds.Silver coated platinum core-shell nanostructures on etched Si nanowires: atomic layer deposition (ALD) processing and application in SERS.Bismuth precursors for atomic layer deposition of bismuth-containing oxide filmsAtomic Layer Deposition and Chemical Vapor Deposition of Tantalum Oxide by Successive and Simultaneous Pulsing of Tantalum Ethoxide and Tantalum ChlorideHigh Aspect-Ratio Iridium-Coated Nanopillars for Highly Reproducible Surface-Enhanced Raman Scattering (SERS)Adhesion and mechanical properties of nanocrystalline hydroxyapatite coating obtained by conversion of atomic layer-deposited calcium carbonate on titanium substrateElectrospinning of calcium carbonate fibers and their conversion to nanocrystalline hydroxyapatiteIntegration of atomic layer deposited nanolaminates on silicon waveguides (Conference Presentation)Slot waveguide ring resonators coated by an atomic layer deposited organic/inorganic nanolaminateCoating and functionalization of high density ion track structures by atomic layer depositionAlkylsilyl compounds as enablers of atomic layer deposition: analysis of (Et3Si)3As through the GaAs processStudies on atomic layer deposition of IRMOF-8 thin films
P50
Q29041533-60A7B57C-E53A-4293-A389-E916C46CF1E6Q30053083-694D5D69-BDFF-43FA-B19A-B146E9057229Q30877725-5CD772D7-BD55-4C82-8C76-11AB3387A21DQ33431849-2F7446D0-2E49-46B7-868E-85371837C9CDQ33488423-844A1598-7657-4A60-BD47-98603017BA67Q33553512-B1D631B0-85FD-42A1-B7BF-092BE6BDBF32Q34166589-97089E0F-8CF7-4766-9AEE-1F8BB9EC175EQ34830148-9D09CF55-48AA-4BFB-9467-4FAC80142D36Q37511842-02CC4E79-6EB4-412E-B98B-E7CF431B79A8Q38837650-9197547E-5788-46EE-9FF4-D9D95146AA05Q40547151-D3915529-4675-40FE-B435-AD9AB3FCB1B9Q40769825-8E14F36D-69F5-4D6E-AC36-75B3E0304A79Q41899472-04CBCEE9-57D4-4416-AAB3-91103EDFB083Q42019743-AEDEFC89-21B7-40A0-B6F3-D360FD18ED00Q43070527-48A10B8B-1158-4D07-B34A-7F7909F02751Q43112408-02D0D7A0-4E43-4B15-A501-3F2860E4A7FCQ43268688-FCDE1805-BF46-4091-844B-00E512727569Q45364083-0E046844-3A5D-48B9-B7E0-FADFD1D068E1Q45407409-A7FB2CFB-493C-40DA-B634-ACF139137891Q47859515-A55191FC-9E0D-442A-8702-8299C337B437Q48044160-7D02B10C-4225-41A2-9245-53FDBDBFC4E4Q50034949-AE20CAEA-D672-4E5B-B05F-8B89627E8BA9Q50449054-1BC92CCB-E8BF-4BAD-9ECC-E32D731A2BD1Q50747131-5C867300-B589-4241-AFA9-6721842B6266Q50906622-A4ABECB2-9052-4F58-B80B-54CC157F3983Q51550322-9EFD588D-FB95-4532-A74C-1F2AF7935DB4Q53014346-BD0EE898-CA59-4B69-8680-E7110BEBB717Q53021159-8554F8AB-CB6D-4D64-91F8-D93972CF07F6Q53267364-25C237DE-7FC6-45D0-97B8-92F5385A7BCFQ54041066-335D91B6-9C73-4935-9A77-5FE2CE469121Q56698971-4770E8CB-9CCF-4987-9219-80EB2F278D3FQ56867203-74271F9D-3667-4E1B-8783-9334D6A62279Q57159719-B7111139-C2A3-4E73-8C90-6B32EE7FFAACQ57213754-39C4478A-FBE8-47DA-8399-68E890272027Q57216616-B9555BC6-907B-4FDB-ADCE-10C6FBF7E9FAQ57390256-C37B4D92-A331-488C-AED5-DE6368ABEF4EQ57390295-A9B10563-19F0-4AEB-A8ED-C15BF591D99AQ57397803-30F987AA-88E9-47D6-8FE5-2448973939DFQ57397812-57BE4B69-1CA8-4E10-ABFE-12F903E2ED57Q57397823-95FEAC0F-4D62-4940-85FC-C8296964FB39
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Mikko Ritala
@ast
Mikko Ritala
@en
Mikko Ritala
@es
Mikko Ritala
@sl
type
label
Mikko Ritala
@ast
Mikko Ritala
@en
Mikko Ritala
@es
Mikko Ritala
@sl
prefLabel
Mikko Ritala
@ast
Mikko Ritala
@en
Mikko Ritala
@es
Mikko Ritala
@sl
P1053
N-7268-2013
P106
P1153
7006596681
P21
P2456
P31
P3829
P496
0000-0002-6210-2980
P569
2000-01-01T00:00:00Z