Verfügbarkeit: In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering

In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering:

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Bibliographische Detailangaben
1. Verfasser:	Zhang, Zhiyang 1988- (VerfasserIn)
Format:	Abschlussarbeit Buch
Sprache:	English
Veröffentlicht:	Berlin 2018
Schlagworte:	Aminothiophenol Oberflächenverstärkter Raman-Effekt Oberflächenplasmonresonanz Heterogene Katalyse Hochschulschrift
Online-Zugang:	Inhaltsverzeichnis Inhaltsverzeichnis
Beschreibung:	XIII, 140 Seiten Illustrationen, Diagramme (farbig)

Internformat

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Datensatz im Suchindex

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adam_text	TABLE OF CONTENTS ACKNOWLEDGMENTS................................................................................................................................V ZUSAMMENFASSUNG.............................................................................................................................VII ABSTRACT.............................................................................................................................................VIII TABLE O F CONTENTS............................................................................................................................... IX 1. MOTIVATION AND GOALS O F THE THESIS.............................................................................................. 1 2. RESEARCH BACKGROUND . ...................................................................................................................5 2.1 LOCALIZED SURFACE PLASMON RESONANCE..................................................................................... 5 2.1.1 LSPR ON NOBLE METAL NANOPARTICLES..................................................................................5 2.1.2 LSPR DECAY.......................................................................................................................... 6 2.2 PLASMONIC CATALYSIS.....................................................................................................................7 2.2.1 BRIEF INTRODUCTION................................................................................................................ 7 2.2.2 MECHANISMS OF PLASMONIC CATALYSIS..................................................................................8 2.2.3 CHALLENGES IN STUDYING PLASMONIC CATALYSIS...................................................................10 2.3 SURFACE-ENHANCED RAMAN SCATTERING (SERS)....................................................................... 10 2.3.1 RAMAN SCATTERING AND SERS............................................................................................10 2.3.2 SERS ENHANCEMENT MECHANISM...................................................................................... 12 2.4 SERS FOR STUDYING PLASMONIC CATALYSIS ....................... 15 2.4.1 BRIEF INTRODUCTION.............................................................................................................. 15 2.4.2 PHOTO-OXIDATION OF PATP .......................................................................... 15 2.4.2 PHOTO-REDUCTION O F PNTP................................................................................................. 19 2.5 SERS MICROFLUIDICS FOR REACTION MONITORING.................................................................. 21 3. THE ROLE O F METAL IONS IN PLASMON-CATALYZED OXIDATION: A CASE STUDY OF P ATP DIMERIZATION......................................................................................................................................... 23 3.1 MAIN CONTENT O F THE CHAPTER.................................................................................................... 23 3.2 INTRODUCTION.............................................................................................................................. 24 3.3 MATERIALS AND METHODS 25 3.3.1 MATERIALS. 25 3.3.2 SYNTHESIS O F GOLD NANOPARTICLES ....................................................................................... 25 3.3.3 SAMPLE PREPARATION USING GOLD NANOPARTICLES IN SOLUTION.............................................25 3.3.4 SAMPLE PREPARATION USING IMMOBILIZED GOLD NANOPARTICLES ......................................... 25 3.3.5 RAMAN EXPERIMENTS........................................................................................................... 25 3.3.6 XPS EXPERIMENTS................................................................................................................26 3.4 AG+, A U 3+, PT4+ AND HG2+ IONS INDUCE THE DIMERIZATION O F PATP TO DMAB...................27 3.5 AG+ INDUCED FORMATION O F DMAB DEPENDS ON LASER INTENSITY AND WAVELENGTH ............ . 31 3.6 AG+ INDUCED FORMATION O F DMAB IS FAVORED AT HIGH P H ....................................................33 3.7 FORMATION OF METAL OXIDE ON GOLD NANOPARTICLES ................................................................ 35 3.8 CONCLUSIONS............................................................................................................................... 38 4. THE ROLE O F LIGANDS IN HOT ELECTRON REDUCTION: A CASE STUDY O F P-NITROTHIOPHENOL REDUCTION............................................................................................................................................... 39 4.1 MAIN CONTENT O F THE CHAPTER.....................................................................................................39 4.2 INTRODUCTION...............................................................................................................................40 4.3 MATERIALS AND METHODS............................................................................................................. 41 4.3.1 MATERIALS.............................................................................................................................41 4.3.2 PREPARATION O F GOLD, SILVER AND COPPER NANOPARTICLES ................................................... 41 4.3.3 PREPARATION O F IMMOBILIZED METAL NANOPARTICLES.......................................................... 41 4.3.4 RAMAN EXPERIMENTS........................................................................................................... 41 4.4 CHARACTERIZATION O F THE METAL NANOSTRUCTURES....................................................................... 42 4.5 SIX-ELECTRON REDUCTION O F PNTP ON GOLD, SILVER AND COPPER NANOPARTICLES ..................... 44 4.6 SIX-ELECTRON REDUCTION IS FAVORED UNDER HIGH LASER INTENSITY .............................................. 46 4.7 LIGANDS ENHANCE HOT ELECTRON REDUCTION................................................................................ 50 4.8 THE PROPOSED MECHANISM O F HOT-ELECTRON INDUCED REDUCTION O F PN TP .......................... 53 4.9 HOT ELECTRON REDUCTION O F NITROBENZENE DERIVATIVES ............................................................. 55 4.10 CONCLUSIONS.............................................................................................................................56 5. THE PH-REVERSIBLE RESPONSE O F THE SERS SPECTRUM OF PATP ON SILVER NANOPARTICLES: CL IONS ENHANCE THE REDUCTION O F DMAB BY HOT ELECTRONS ............................................................... 57 5.1 MAIN CONTENT OF THE CHAPTER................................................................................................... 57 5.2 INTRODUCTION...............................................................................................................................58 5.3 MATERIALS AND METHODS............................................................................................................. 59 5.3.1 MATERIALS............................................................................................................................ 59 5.3.2 PREPARATION O F SILVER AND GOLD NANOPARTICLES ................................................................. 59 5.3.3 DMAB FORMATION AND PHOTO-REDUCTION ON SILVER NANOPARTICLES................................60 5.3.4 PNTP ASSAYS USING SILVER AND GOLD NANOPARTICLES........................................................60 5.3.5 RAMAN EXPERIMENTS...........................................................................................................60 5.4 THE DEPENDENCE O F THE PH-RELATED REVERSIBILITY O F THE SERS SPECTRUM O F PATP ON THE ACID SPECIES.............................................................................................................. 60 5.5 DMAB FORMATION ON SILVER DURING THE INCUBATION PROCESS ............................................... 62 5.6 THE ROLE O F LIGANDS IN THE PH-RELATED REVERSIBILITY O F THE PATP SPECTRUM ON SILVER ...... 64 5.7 PH IRREVERSIBILITY O F THE SERS SPECTRUM O F PATP ON GOLD NANOPARTICLE ........................ 65 5.8 CONCLUSIONS.............................................................................................................................. 66 6. CATALYSIS BY METAL NANOPARTICLES WITH A PLUG-IN SERS MICROFLUIDIC PLATFORM ................. 67 6.1 MAIN CONTENT O F THE CHAPTER.................................................................................................... 67 6.2 INTRODUCTION.............................................................................................................................. 68 6.3 MATERIALS AND METHODS............................................................................................................. 69 6.3.1 SYNTHESIS O F GOLD NANOPARTICLES...................................................................................... 69 6.3.2 PREPARATION O F IMMOBILIZED GOLD NANOPARTICLES ON GLASS ROD AND PDMS BLOCK......69 6.3.3 FABRICATION OF THE PLUG-IN SERS MICROFLUIDICS PLATFORM.............................................69 6.3.4 MODIFICATION IMMOBILIZED GOLD NANOPARTICLES WITH SERS PROBES..............................70 6.3.5 RAMAN EXPERIMENTS...........................................................................................................71 6.3.6 ESTIMATION O F SERS ENHANCEMENT FACTOR....................................................................... 71 6.4 SCHEME FOR THE PLUG-IN OPTOFLUIDIC PLATFORM 71 6.5 GOLD-CATALYZED THE REDUCTION OF PNTP BY NABPL UNDER CONTROLLED AQUEOUS CONDITION 74 6.5.1 OPTIMIZATION OF LASER INTENSITY TO AVOID SIDE PHOTOREACTION O F PNTP ...................... 74 6.5.2 SERS MONITORING O F REDUCTION O F PNTP TO PATP ON GOLD BY NABPL ..................... 75 6.5.3 ANALYSIS O F THE REACTION KINETICS.................................................................................... 77 6.5.4 PROPOSED MECHANISM FOR THE GOLD-CATALYZED REDUCTION O F PNTP BY NABPU ........... 79 6.6 DIMERIZATION OF PATP UNDER CONTROLLED GAS ATMOSPHERE .................................................. 80 6.7 CONCLUSIONS............................................................................................................................... 82 7. MAPPING THE INHOMOGENEITY IN PLASMONIC CATALYSIS WITH SERS MICROSPECTROSCOPY ....... 85 7.1 MAIN CONTENT O F THE CHAPTER....................................................................................................85 7.2 INTRODUCTION............................................................................................................................... 86 7.3 MATERIALS AND METHODS..............................................................................................................87 7.3.1 MATERIALS............................................................................................................................. 87 7.3.2 SYNTHESIS O F GOLD NANOPARTICLES.......................................................................................87 7.3.3 PREPARATION O F IMMOBILIZED GOLD NANOPARTICLES WITH PATP........................................87 7.3.4 RAMAN MEASUREMENTS....................................................................................................... 88 7.3.5 LAMP EMISSION SPECTRUM..................................................................................................88 7.3.6 ESTIMATION O F SERS ENHANCEMENT FACTOR ....................................................................... 88 7.4 CHARACTERIZATION O F METAL NANOSTRUCTURES.............................................................................. 88 7.5 PATP DIMERIZATION UNDER HIGH LASER INTENSITY ...................................................................... 89 7.6 SERS MAPPING O F DMAB FORMATION DURING THE INCUBATION O F PATP WITH THE CATALYST 92 7.6.1 EFFICIENT FORMATION O F DMAB IN AIR DURING THE INCUBATION ....................................... 92 7.6.2 EFFECTS O F INCUBATION TIME, O 2 IN AIR, ROOM LIGHT AND MOLECULAR COVERAGE................95 7.7 CONCLUSIONS............................................................................................................................... 99 8. APPLICATION O F PLASMONIC CATALYSIS IN SURFACE MOLECULAR PATTERNING ON SUPPORTED METAL NANOPARTICLES....................................................................................................................................... 101 8.1 MAIN CONTENT O F THE CHAPTER................................................................................................... 101 8.2 INTRODUCTION............................................................................................................................. 102 8.3 MATERIALS AND METHODS 103 8.3.1 MATERIALS.......................................................................................................................... 103 8.3.2 FABRICATION O F NANOPARTICLES...........................................................................................103 8.3.3 FUNCTIONALIZATION O F MONOLAYER ORGANIC MOLECULES ON IMMOBILIZED NANOPARTICLES..............................................................................................................................103 8.3.4 RAMAN MEASUREMENTS.....................................................................................................103 8.4 CHARACTERIZATION O F IMMOBILIZED GOLD NANOPARTICLES ......................................................... 104 8.5 PASSIVATION PATTERNING O F PATP VIA PLASMON-CATALYZED OXIDATION ................ 104 8.6 ACTIVATION PATTERNING O F PATP VIA PLASMON-CATALYZED REDUCTION ................................... 106 8.7 SERS IMAGING OF DM AB PATTERNS O F DIFFERENT SHAPES FOR INFORMATION STORAGE ........... 107 8.8 REWRITING OF THE PATTERN......................................................................................................... 109 8.9 CONCLUSIONS.............................................................................................................................110 9. SUMMARY AND OUTLOOK............................................................................................................I L L BIBLIOGRAPHY.....................................................................................................................................115 LIST O F FIGURES................................................................................................................................... 130 LIST O F SCHEMES................................................................................................................................. 133 LIST O F ABBREVIATIONS........................................................................................................................ 134 CURRICULUM VITAE...............................................................................................................................135 PUBLICATIONS....................................................................................................................................... 137 DECLARATION.........................................................................................................................................140
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author	Zhang, Zhiyang 1988-
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spelling	Zhang, Zhiyang 1988- Verfasser (DE-588)1169414907 aut In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering von M.S. Zhiyang Zhang Berlin 2018 XIII, 140 Seiten Illustrationen, Diagramme (farbig) txt rdacontent n rdamedia nc rdacarrier Dissertation Humboldt-Universität zu Berlin 2018 Aminothiophenol (DE-588)4502546-0 gnd rswk-swf Oberflächenverstärkter Raman-Effekt (DE-588)4172264-4 gnd rswk-swf Oberflächenplasmonresonanz (DE-588)4737046-4 gnd rswk-swf Heterogene Katalyse (DE-588)4123377-3 gnd rswk-swf (DE-588)4113937-9 Hochschulschrift gnd-content Heterogene Katalyse (DE-588)4123377-3 s Oberflächenplasmonresonanz (DE-588)4737046-4 s Oberflächenverstärkter Raman-Effekt (DE-588)4172264-4 s Aminothiophenol (DE-588)4502546-0 s DE-604 B:DE-101 application/pdf http://d-nb.info/1169168116/04 Inhaltsverzeichnis DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=030718229&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Zhang, Zhiyang 1988- In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering Aminothiophenol (DE-588)4502546-0 gnd Oberflächenverstärkter Raman-Effekt (DE-588)4172264-4 gnd Oberflächenplasmonresonanz (DE-588)4737046-4 gnd Heterogene Katalyse (DE-588)4123377-3 gnd
subject_GND	(DE-588)4502546-0 (DE-588)4172264-4 (DE-588)4737046-4 (DE-588)4123377-3 (DE-588)4113937-9
title	In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering
title_auth	In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering
title_exact_search	In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering
title_full	In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering von M.S. Zhiyang Zhang
title_fullStr	In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering von M.S. Zhiyang Zhang
title_full_unstemmed	In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering von M.S. Zhiyang Zhang
title_short	In situ characterization of plasmonic catalysis using surface-enhanced Raman scattering
title_sort	in situ characterization of plasmonic catalysis using surface enhanced raman scattering
topic	Aminothiophenol (DE-588)4502546-0 gnd Oberflächenverstärkter Raman-Effekt (DE-588)4172264-4 gnd Oberflächenplasmonresonanz (DE-588)4737046-4 gnd Heterogene Katalyse (DE-588)4123377-3 gnd
topic_facet	Aminothiophenol Oberflächenverstärkter Raman-Effekt Oberflächenplasmonresonanz Heterogene Katalyse Hochschulschrift
url	http://d-nb.info/1169168116/04 http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=030718229&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT zhangzhiyang insitucharacterizationofplasmoniccatalysisusingsurfaceenhancedramanscattering

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