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Chain-length-dependent impact of band broadening on the molar-mass determination of synthetic polymers via size-exclusion chromatography.Planet-satellite nanostructures made to order by RAFT star polymers.Long-lived intermediates in reversible addition-fragmentation chain-transfer (RAFT) polymerization generated by ? radiationReversible addition-fragmentation chain-transfer polymerization: Unambiguous end-group assignment via electrospray ionization mass spectrometryRAFTing down under: Tales of missing radicals, fancy architectures, and mysterious holesThe reversible addition-fragmentation chain transfer process and the strength and limitations of modeling: Comment on ?the magnitude of the fragmentation rate coefficient?Mechanism and kinetics of dithiobenzoate-mediated RAFT polymerization. I. The current situationModeling RAFT polymerization kinetics via Monte Carlo methods: cumyl dithiobenzoate mediated methyl acrylate polymerizationFacile Access to Chain Length Dependent Termination Rate Coefficients via Reversible Addition−Fragmentation Chain Transfer (RAFT) Polymerization: Influence of the RAFT Agent StructureChain Length Dependent Termination in Butyl Acrylate Free-Radical Polymerization Studied via Stationary and Pulsed Laser Initiated RAFT PolymerizationShielding effects in polymer-polymer reactions. II. Reactions between linear and star-branched chains with up to six armsOne-Pot RAFT/“Click” Chemistry via Isocyanates: Efficient Synthesis of α-End-Functionalized PolymersEnd-Group Analysis of Polymers by Electrospray Ionization Mass Spectrometry: 2-Methyl-1-[4-(methylthio)phenyl]-2-morpholinopropan-1-one Initiated Free-Radical PhotopolymerizationTermination Rate Coefficient of Dimethyl Itaconate: Comparison of Modeling and Experimental ResultsCharacterization of Z-RAFT Star Polymerization of Butyl acrylate by Size-Exclusion ChromatographyZ-RAFT star polymerization of styrene: Comprehensive characterization using size-exclusion chromatographyFunctional binary micropattern of hyperbranched poly(ether amine) (hPEA-AN) network and poly(ether amine) (PEA) brush for recognition of guest moleculesThe Structure of Gold-Nanoparticle Networks Cross-Linked by Di- and Multifunctional RAFT OligomersSilica-Coated Magnetite Nanoparticles Carrying a High-Density Polymer Brush Shell of Hydrophilic PolymerSurface Modification of Wood Flour via ARGET ATRP and Its Application as Filler in ThermoplasticsPolyethylene-Grafted Gold and Silver Nanoparticles Using Catalyzed Chain Growth (CCG)
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Q47290722-1770C669-2949-4B09-875E-794A69D2EC26Q51062181-3D2C4A90-F817-49B4-A4FE-21185F772D42Q57353834-C16B215F-534C-4A0B-9BB5-5D42C1505E00Q57353913-EEE6E129-A5FA-46C8-BABF-CA958B92912EQ57353943-473D8D51-DEF5-405F-8430-9EB66229CB0CQ57353996-D0E7C0A4-176D-4703-BF86-DBEAEEB9D28AQ57355101-27AA92A6-FB92-4682-BB06-DEABD15B4577Q57361613-4EA907BD-7EA7-47CC-A95C-3F1DD0CEEAD7Q57367349-F18E1526-EC72-444F-B833-9D918BDF7DC9Q57367900-2D92BFD0-64FB-4BC0-A207-75E6CB2A6F59Q57371420-BD3BBCF4-C9E7-48BB-B5A7-FE960F1C7A2BQ60173385-178C4E90-45EA-4D57-8AD0-C0284989E2EFQ60420978-902A32F5-E547-4717-BADF-7C801A8076A0Q60421022-43C4A288-41C3-47C5-B18A-860C521B841EQ63971877-3A5E9E93-58C8-4771-A4C9-5A213DC39338Q63971918-24623E6F-D6C5-4ED5-9A3C-A2EE7FBFA8BFQ83156675-BE7AC9AE-C52C-401E-8F70-7631E608BCE2Q86073960-460B3F30-B82A-4758-8C0F-64328B28BA35Q89018505-95CC725B-AA27-4BD5-A1DB-2926BACC93BEQ92978739-F2538D67-76EC-4224-9641-A36D8B1C1E32Q92979082-7729FDE6-BA03-49DA-A0F4-259AC492EB95
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description
Forscher
@de
chercheur
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investigador
@es
researcher
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wetenschapper
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հետազոտող
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研究者
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name
Philipp Vana
@ast
Philipp Vana
@en
Philipp Vana
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Philipp Vana
@nl
type
label
Philipp Vana
@ast
Philipp Vana
@en
Philipp Vana
@es
Philipp Vana
@nl
prefLabel
Philipp Vana
@ast
Philipp Vana
@en
Philipp Vana
@es
Philipp Vana
@nl
P1153
6701636019
P31
P496
0000-0001-6032-3854