Refine
Has Fulltext
- yes (113)
Is part of the Bibliography
- yes (113)
Year of publication
Document Type
- Doctoral Thesis (113) (remove)
Language
- English (113) (remove)
Keywords
- Supramolekulare Chemie (21)
- Selbstorganisation (18)
- Farbstoff (13)
- Merocyanine (10)
- Perylenbisimid (10)
- Perylenderivate (10)
- Aggregation (9)
- Fluoreszenz (9)
- Organische Chemie (9)
- perylene bisimide (9)
- Elektronentransfer (8)
- self-assembly (8)
- Squaraine (6)
- Chemische Synthese (5)
- Chromophor (5)
- Exziton (5)
- Katalyse (5)
- Nucleinsäuren (5)
- Self-assembly (5)
- supramolecular chemistry (5)
- Flüssigkristall (4)
- Ladungstransfer (4)
- Metallosupramolekulare Chemie (4)
- NMR-Spektroskopie (4)
- Naphthylisochinolinalkaloide (4)
- Perylenbisdicarboximide <Perylen-3,4:9,10-bis(dicarboximide)> (4)
- Perylene Bisimide (4)
- Polymere (4)
- Supramolekulare Struktur (4)
- Wasseroxidation (4)
- Aggregat <Chemie> (3)
- Ancistrocladaceae (3)
- Chirality (3)
- Chiralität <Chemie> (3)
- DNA (3)
- DNS (3)
- Energietransfer (3)
- Fotokatalyse (3)
- Hydrogel (3)
- Merocyanin (3)
- Quantenchemie (3)
- Ruthenium Komplexe (3)
- Selbstassemblierung (3)
- Self-Assembly (3)
- Triarylamine (3)
- Wasser (3)
- catalysis (3)
- electron transfer (3)
- energy transfer (3)
- fluorescence (3)
- metallosupramolecular chemistry (3)
- non-covalent interactions (3)
- organische Solarzelle (3)
- transient absorption (3)
- transient absorption spectroscopy (3)
- water oxidation (3)
- 10-bis(dicarboximide)> (2)
- 4:9 (2)
- Ancistrocladus (2)
- Aptamer (2)
- Aromatically annulated triquinacenes (2)
- Aromatisch anellierte Triquinacene (2)
- C-C coupling (2)
- Chiralität (2)
- Click-Chemie (2)
- Dyade (2)
- Energy Transfer (2)
- Exciton coupling (2)
- Exzitonenkopplung (2)
- FRET (2)
- Fluoreszenz-Resonanz-Energie-Transfer (2)
- Gold (2)
- Guanidinderivate (2)
- J- and H-Aggregate (2)
- J- and H-Aggregates (2)
- Liquid Crystal (2)
- Merocyanine dyes (2)
- Methyltransferase (2)
- Molekulare Erkennung (2)
- Nucleoside (2)
- Oligomere (2)
- Organic Chemistry (2)
- Organische Solarzelle (2)
- Organische Synthese (2)
- Organischer Feldeffekttransistor (2)
- Organischer Halbleiter (2)
- Oxidation (2)
- Perylenbisdicarboximide (2)
- Perylenbisdicarboximide <Perylen-3 (2)
- Perylenbisimide (2)
- Perylene bisimide (2)
- Photosensibilisator (2)
- Polycyclische Aromaten (2)
- Pyrene (2)
- RNA (2)
- RNS (2)
- Ringöffnungspolymerisation (2)
- Ruthenium complexes (2)
- Rutheniumkomplexe (2)
- SARS-CoV-2 (2)
- Scheibe-Aggregat (2)
- Selbstassoziation (2)
- Spinchemie (2)
- Strukturaufklärung (2)
- Supramolecular Chemistry (2)
- Transiente Absorption (2)
- Triarylamin (2)
- Triquinacenderivate (2)
- Wasserstoffbrückenbindung (2)
- Wirt-Gast-Beziehung (2)
- charge separation (2)
- charge transfer (2)
- cooperativity (2)
- curved hydrocarbons (2)
- cyclophane (2)
- dimer (2)
- gekrümmte Kohlenwasserstoffe (2)
- intervalence charge transfer (2)
- naphthylisoquinoline alkaloids (2)
- nicht-kovalente Wechselwirkungen (2)
- organic solar cell (2)
- organic solar cells (2)
- polymer-peptide-conjugate (2)
- redox cascade (2)
- ruthenium complexes (2)
- spin chemistry (2)
- supramolekulare Chemie (2)
- thiol-ene (2)
- triarylamine (2)
- triquinacene derivatives (2)
- "steepest descent-modest ascent" (1)
- "steilsten Abstieg - schwächste Aufstieg" (1)
- (bi)pyridine-based ligand (1)
- 2"-> (1)
- 2':6' (1)
- 5'-O-Methyldioncophylline D (1)
- A-D-A dyes (1)
- A. abbreviatus (1)
- A. likoko (1)
- Absolute Configuration (1)
- Absolute Konfiguration (1)
- Absorption (1)
- Acenes (1)
- Acetylneuraminsäure <N-> (1)
- Actinomyceten (1)
- Actinomycetes (1)
- Adsorption (1)
- Aggregate (1)
- Akzeptor <Chemie> (1)
- Alkaloid (1)
- Alkaloide (1)
- Alkoxylradikale (1)
- Alkoxylradikals (1)
- Aminosäuren (1)
- Amphiphile Verbindungen (1)
- Ancistrolikokine E3 (1)
- Anode (1)
- Anti-infectious activity (1)
- Antiausterity activity (1)
- Antimalariamittel (1)
- Antimicrobial activities (1)
- Antimicrobial proteins (1)
- Antimikrobielle Aktivitäten (1)
- Antimikrobieller Wirkstoff (1)
- Antitumor-Antibiotikum (1)
- Antitumor-antibitioc (1)
- Arene-Fluoroarene (1)
- Artificial Base Pair (1)
- Asymmetric synthesis (1)
- Asymmetrische Synthese (1)
- Atropisomere (1)
- Atropisomerie (1)
- Base pairing (1)
- Basenpaarung (1)
- Biomaterial (1)
- Bioorganic chemistry (1)
- Bioorganik (1)
- Bioorthogonal (1)
- Biradikal (1)
- Bodipy (1)
- Bola-Amphiphil (1)
- Bor-Stickstoff-Verbindungen (1)
- Borane (1)
- Boron-Nitrogen Dative Bond (1)
- CD-Spektroskopie (1)
- COVID-19 (1)
- Cage (1)
- Calix[4]aren (1)
- Carbazolderivate (1)
- Carboxylat-Rezeptor (1)
- Catalysis (1)
- Charge-transfer-Komplexe (1)
- Chemie (1)
- Chemische Bindung (1)
- Chemische Reaktion (1)
- Chemosensor (1)
- Chirality Transfer (1)
- Chlorin (1)
- Chlorinderivate (1)
- Chromophore (1)
- Circular Dichroism (1)
- Circular dichroism (1)
- Circular-Dichroismus (1)
- Computational chemistry (1)
- Computerchemie (1)
- Congo (1)
- Congolese Ancistrocladus plants (1)
- Coordination Polymer (1)
- Corannulene (1)
- Coronaviren (1)
- Covalent Organic Framework (1)
- Crosslinker (1)
- Crosslinking (1)
- Cyaninfarbstoff (1)
- Cyclic peptides (1)
- Cyclooctine (1)
- Cyclooctyne (1)
- Cyclophan (1)
- Cyclovoltammetrie (1)
- DOSY-NMR (1)
- Demethylase (1)
- Demethylierung (1)
- Demokratische Republik Kongo (1)
- Deoxyribozymes (1)
- Diamant (1)
- Diarylethen (1)
- Diarylethene (1)
- Diarylethylene (1)
- Dicarboximide (1)
- Dicarboximides (1)
- Dichtebestimmung in Theorie und Experiment (1)
- Dihydrooxazole (1)
- Dimer (1)
- Dimer-Konfiguration (1)
- Dimere (1)
- Dimeric Naphthylisoquinoline Alkaloids (1)
- Dioncophylline C (1)
- Donator <Chemie> (1)
- Donor (1)
- Donor-Akzeptor Triaden (1)
- Donor-Photosensibilisator-Akzeptor Triade (1)
- Drug Delivery System (1)
- Dyad (1)
- Dye (1)
- Dyes/pigments (1)
- Dünnschichttransistor (1)
- EPR spectroscopy (1)
- Electron Transfer (1)
- Electron density (1)
- Elektrochemie (1)
- Elektronendichte (1)
- Elektronendichtebestimmung (1)
- Elektronenspinresonanzspektroskopie (1)
- Energieaufnahme (1)
- Energietransfer <Mikrophysik> (1)
- Enzym (1)
- Enzyminhibitor (1)
- Epitranskriptom (1)
- Excitons (1)
- Farbstoffe (1)
- Farbstoffe/Pigmente (1)
- Festkörper-NMR (1)
- Festphasensynthese (1)
- Fluorescence (1)
- Fluoreszenzaktivierung (1)
- Fluoreszenzspektrometer (1)
- Fluoreszenzspektroskopie (1)
- Foldamers (1)
- Fulleren-Netzwerk (1)
- Fullerene (1)
- Funktionalisierung <Chemie> (1)
- Funktionelle Polymere (1)
- Galectine (1)
- Gelieren (1)
- Glucosyltransferasen (1)
- Glycoengineering (1)
- Gold Nanoparticles (1)
- Gold Nanopartikel (1)
- Grün fluoreszierendes Protein (1)
- Guanidiniocarbonylpyrrol (1)
- H-Aggregate (1)
- H-bonds (1)
- Halbleiter (1)
- Hekate (1)
- Helicene (1)
- Helicität <Chemie> (1)
- Helix- and Zick-Zack-Konformere (1)
- Helix- and Zig-Zag-Conformers (1)
- Helix-Coil-Transition (1)
- Helix-Knäuel-Umwandlung (1)
- Heterosolarzelle (1)
- Hexaarylbenzene (1)
- Hexaarylbenzole (1)
- Host-Guest Chemistry (1)
- Host-Guest-Chemistry (1)
- Hydrogen bond (1)
- Inhibitor (1)
- Intermolecular Interactions (1)
- Intermolekulare Wechselwirkungen (1)
- Intervalenzladungstransfer (1)
- Iridium-Photosensibilisator (1)
- Iridiumkomplexe (1)
- Isolation (1)
- Isolierung (1)
- Isolierung <Chemie> (1)
- J-Aggregat (1)
- J-Aggregate (1)
- J-Aggregates (1)
- J-aggregate (1)
- Jozimine A2 (1)
- Kinetic Self-assembly (1)
- Kinetik (1)
- Kohlenhydrate (1)
- Kohlenstoff (1)
- Kohn-Sham Orbitale (1)
- Kohn-Sham Orbitals (1)
- Kolloidalstabilität (1)
- Kombinatorische Synthese (1)
- Komplexierung (1)
- Konfiguration <Chemie> (1)
- Konformeren (1)
- Konglomerat (1)
- Kongo (1)
- Kooperativität (1)
- Koordinationspolymer (1)
- Koordinationspolymere (1)
- Kraftfeld (1)
- Kupplungsreaktion (1)
- Käfigverbindungen (1)
- Ladungstrennung (1)
- Lebende Polymerisation (1)
- Leitfähige Polymere (1)
- Lichtabsorption (1)
- Lichtsammelsystem (1)
- Ligand (1)
- Liquid Crystals (1)
- Living Polymerisation (1)
- Lower Critical Solution Temperature (LCST) (1)
- MRCI (1)
- Magnetfeldeffekt (1)
- Makrocyclische Verbindungen (1)
- Makrozyklus (1)
- Mechanismus (1)
- Merocyanine dye (1)
- Mesogen (1)
- Metabolismus (1)
- Metaheuristik-Suchmethoden (1)
- Metall-Ion (1)
- Metallosupramolecular chemistry (1)
- Methylierung (1)
- Michael addition (1)
- Michael-Addition (1)
- Molecular dynamics (1)
- Molecular probes (1)
- Molekül (1)
- Moleküldynamik (1)
- Moleküloptimierung (1)
- Moller-Plesset (1)
- Monoschicht (1)
- Mulliken-Hush (1)
- Multi Reference (1)
- Multireferenz (1)
- N-acetyllactosamine (1)
- NIQs (1)
- NIR chromophore (1)
- Nanodiamant (1)
- Nanopartikel (1)
- Nanoribbon (1)
- Nanosegregation (1)
- Nanostructure (1)
- Nanostrukturen (1)
- Naphthalinbisimid (1)
- Naphthochinonen (1)
- Naphthoquinones (1)
- Naphthyl Isoquinolines (1)
- Naphthylisochinoline (1)
- Naphthylisoquinolin (1)
- Naphthylisoquinoline (1)
- Naphthylisoquinoline alkaloids (1)
- Natural Products (1)
- Natural products (1)
- Naturstoffe (1)
- Nicht-Fulleren Akzeptor (1)
- Non-Fullerene Acceptor (1)
- Non-linear optics (1)
- Nonlinear Optical Properties of Organic Materials (1)
- Nucleic acids (1)
- Nucleosidanaloga (1)
- Nukleinsäure (1)
- OFETs (1)
- OLC (1)
- OLED (1)
- Oligomers and Polymers (1)
- Oligonucleotide (1)
- Onbead-Enzymscreening (1)
- Optimierungsmethoden (1)
- Optimization methods (1)
- Organic Field-Effect Transistor (1)
- Organic field-effect transistor (1)
- Organic semiconductors (1)
- Organische Halbleiter (1)
- PEDOT (1)
- PNA (1)
- Pancreatic cancer (1)
- Paracyclophane (1)
- Pentacen (1)
- Peptid-Nucleinsäuren (1)
- Peptidsynthese (1)
- Perylen-Farbstoffe (1)
- Perylenbisanhydrid (1)
- Perylenbisimiden (1)
- Perylenbisimides (1)
- Perylene Bisimides (1)
- Perylentetracarbonsäurederivate (1)
- Pflanzenzelle (1)
- Pflanzenzellkulturen (1)
- Phosphoramidite (1)
- Phosphorylase (1)
- Photochemie (1)
- Photochemistry (1)
- Photochromie (1)
- Photoconductivity (1)
- Phytochemical investigations of a Congolese Ancistrocladus Liana (1)
- Phytochemie (1)
- Plant cell cultures (1)
- Polyamin (1)
- Polycarbazole (1)
- Polycyclic aromatic hydrocarbons (1)
- Polymer (1)
- Polymerhalbleiter (1)
- Polymerkomplexe (1)
- Polymerlösung (1)
- Polymorphismus (1)
- Porosität (1)
- Porous Materials (1)
- Porphyrin (1)
- Protease (1)
- Protein Corona (1)
- Proteinadsorption (1)
- Proteinen mit antimikrobieller Wirkung (1)
- Protonen-NMR-Spektroskopie (1)
- Protonenreduktion (1)
- Pyren (1)
- Pyrenderivate (1)
- Quadruplex-DNS (1)
- Quality assessment of antimalarial medicines from the Congo (1)
- Quantenchemische Rechnungen (1)
- Quantifizierung (1)
- Quantum Chemical CD Calculations (1)
- Quantum Chemical Calculations (1)
- Quantum mechanics / molecular modeling (1)
- Quasi-Newton-Verfahren (1)
- RAFT (1)
- RNA G-quadruplex (1)
- RNA labeling (1)
- RNA modifications (1)
- RNA structures (1)
- Raman (1)
- Raumfüllung (1)
- Redox-Kaskade (1)
- Redoxkaskade (1)
- Redoxreaktion (1)
- Reduction (1)
- Reticular Chemistry (1)
- Ribozym (1)
- Ribozymes (1)
- Ring closing metathesis (1)
- Ringschlussmetathese (1)
- Rotation (1)
- Ruthenium (1)
- Ruthenium-Photosensibilisator (1)
- Räumliche Anordnung (1)
- Röntgendiffraktometrie (1)
- SARS (1)
- SELEX (1)
- SERS (1)
- SIB (1)
- Second coordination sphere engineering (1)
- Self-Assembly in Water (1)
- Self-Sortierung (1)
- Sialic acids (1)
- Sialinsäuren (1)
- Solid-State NMR Spectroscopy (1)
- Sonogashira (1)
- Sonogashira-Hagihara-Reaktion (1)
- Space filling (1)
- Spectroscopy (1)
- Speicher <Informatik> (1)
- Spektroelektrochemie (1)
- Spermin (1)
- Spin flip (1)
- Spin labels (1)
- Spin-Sonde (1)
- Spin-chemistry (1)
- Squarain Farbstoffe (1)
- Squaraine Dyes (1)
- Stacking (1)
- Structural elucidation (1)
- Supercap (1)
- Superkondensator (1)
- Supramolecular Block Copolymers (1)
- Supramolecular Interaction (1)
- Supramolecular aggregates (1)
- Supramolecular electronics (1)
- Supramolekulare Aggregate (1)
- Synthese (1)
- Synthesediamant (1)
- Synthetischer Farbstoff (1)
- TD-DFT (1)
- Tabusuche (1)
- Targeting (1)
- Taxol (1)
- Terpyridinderivate <2 (1)
- Terrylenbisimid (1)
- Terrylenderivate (1)
- Terrylene bisimide (1)
- Theoretical Chemistry (1)
- Theoretische Charakterisierung (1)
- Theoretische Chemie (1)
- Theorie (1)
- Thermodynamics (1)
- Thiophen (1)
- Tiplet emiters (1)
- Tiplett Emitter (1)
- Total Synthesis (1)
- Totalsynthese (1)
- Triad (1)
- Triplett (1)
- Two-photon absorption (1)
- UV-VIS-Spektroskopie (1)
- UV/Vis-Absorption (1)
- Vergleich (1)
- Vesikel (1)
- Wasserlösliche Polymere (1)
- Wasseroxidationsreaktion (1)
- Wasserspaltung (1)
- Wasserstoffbrücken (1)
- Water (1)
- Water Oxidation (1)
- Wirkmechanismus (1)
- Wirkstoff-Träger-System (1)
- Wirt-Gast-Komplex-Chemie (1)
- X-Ray Diffraction (1)
- XNA (1)
- Xanthin (1)
- Zelladhäsion (1)
- Zellkultur (1)
- Zinc Chlorin (1)
- Zink (1)
- Zinkchlorine (1)
- Zweidimensionale NMR-Spektroskopie (1)
- Zweiphotonenabsorption (1)
- [FeFe] hydrogenase mimic (1)
- [FeFe]-Hydrogenase Imitator (1)
- acceptor (1)
- aggregation (1)
- alkaloids-Quinoid (1)
- amodiaquine (1)
- angeregte Zustände (1)
- artemether - lumefantrine (1)
- atropisomer (1)
- biradical (1)
- bola-amphiphile (1)
- boranes (1)
- calix[4]arene (1)
- capillary zone electrophoresis (1)
- carbohydrate chemistry (1)
- carboxylate receptor (1)
- charge recombination (1)
- charge-separated state (1)
- chirality (1)
- chlorin (1)
- complexation (1)
- computational chemistry (1)
- conformational search (1)
- cooperative (1)
- coordination polymer (1)
- cyclic trimer (1)
- cyclic voltammetry (1)
- cyclische Trimere (1)
- diamond (1)
- dicarboximide (1)
- dimerer Naphthylisochinolin-Alkaloide (1)
- dipolar aggregation (1)
- domain shift (1)
- donor-acceptor dyads (1)
- donor-acceptor triads (1)
- donor-photosensibilisator-acceptor triad (1)
- dyad (1)
- dyads (1)
- dye (1)
- dyes (1)
- dyes/pigments (1)
- electron density (1)
- enzyme engineering (1)
- excited states (1)
- exciton coupling (1)
- exciton dynamics (1)
- excitonic chirality (1)
- experimental and theoretical determination of electron density (1)
- folda-dimer (1)
- force field (1)
- fullerene network (1)
- functional dyes (1)
- galectin-1 (1)
- global minimum (1)
- gold (1)
- guanidiniocarbonyl pyrrole (1)
- halbleitende Polymere (1)
- hexaarylbenzenes (1)
- host-guest (1)
- host-guest chemistry (1)
- hydrogel (1)
- hydrogen bond (1)
- impurity profiling (1)
- inherent chirality (1)
- inhibitor (1)
- intervalence charge-transfer (1)
- iridium complex (1)
- iridium photosensitizer (1)
- isotropic hyper fine coupling (1)
- ladungsgetrennte Zustände (1)
- light harvesting (1)
- liquid crystal (1)
- macrocycle (1)
- macrocycles (1)
- magnetic field effect (1)
- mechanism (1)
- merocyanine dye (1)
- merocyanines (1)
- metabolism (1)
- metaheuristic methods (1)
- metal-ion-ligand coordination (1)
- metallosupramolecular π-amphiphiles (1)
- mode of action (1)
- molecular recognition (1)
- molekulare Erkennung (1)
- multichromophoric arrays (1)
- n-type semiconductors (1)
- nanomaterials (1)
- naphthalene diimide (1)
- near infrared chirality (1)
- neutral polyradical (1)
- neutrales Polyradikal (1)
- non-fullerene acceptor (1)
- nucleic acid (1)
- null-aggregate (1)
- oligo(phenylene ethynylene) (OPE) (1)
- oligothiophenes (1)
- on surface self-assembly (1)
- onbead enzym screening (1)
- optical properties (1)
- optische Eigenschaften (1)
- organic photovoltaics (1)
- organic semiconductor (1)
- organic transistor (1)
- organische Photovoltaik (1)
- organische Solarzellen (1)
- organischer Feldeffekttransistor (1)
- organischer Transitor (1)
- organogelator (1)
- pentacene (1)
- perylene bisimide dimers (1)
- perylene dyes (1)
- photocatalysis (1)
- photoinduced electron transfer (1)
- photoinduzierter Elektronentransfer (1)
- photophysics (1)
- pi-pi Wechselwirkungen (1)
- pi-pi- stacking (1)
- polar solution (1)
- polare Lösung (1)
- poly(2-oxazoline)s (1)
- polyamine (1)
- polycarbazole (1)
- polyglycidol (1)
- protease (1)
- protein adsorption (1)
- protein crystallography (1)
- protein-ligand-interaction (1)
- proton reduction (1)
- quantenchemische Berechnungen (1)
- quaterrylene bisimide (1)
- quercetin (1)
- radical ion pair (1)
- resveratrol (1)
- ring opening polymerisation (1)
- ring-opening polymerization (1)
- rotation (1)
- ruthenium photosensitizer (1)
- seco-NIQs-Naphthylisoindolinone (1)
- selbst organisierende Monolagen (SAM) (1)
- selbstaggregierten (1)
- self-assembled monolayer (SAM) (1)
- self-sorting (1)
- semiconducting polymers (1)
- short-range JCT-coupling (1)
- solid-state emitter (1)
- spacer-controlled self-assembly (1)
- spectroscopy (1)
- spermine (1)
- spin relaxation (1)
- structural elucidation (1)
- structural restriction (1)
- substandard and falsified medicines from the Congo (1)
- sucrose phosphorylase (1)
- supramolecular (1)
- supramolekular (1)
- supramolekularen Elektronik (1)
- theoretical characterisation (1)
- theoretical investigations (1)
- theoretische Untersuchungen (1)
- thin film transistor (1)
- topological analysis (1)
- topologische Analyse (1)
- transiente Absorption (1)
- transiente Absorptionsspektroskopie (1)
- triaryalmine (1)
- triplet (1)
- vesicle (1)
- water oxidation reation (1)
- xanthine (1)
- zyklische Peptide (1)
Institute
- Institut für Organische Chemie (113) (remove)
Sonstige beteiligte Institutionen
Helically Twisted Graphene Nanoribbons: Bottom-up Stereospecific Synthesis and Characterization
(2024)
Over the past decade, substantial progress has been made in synthesizing atomically precise carbon nanostructures, with a focus on graphene nanoribbons (NRs) through advanced synthetic techniques. Despite these advancements, precise control over the stereochemistry of twisted NRs remains challenging. This thesis introduces a strategic approach to achieve absolute control over the single-handed helical conformation in a cove-edged NR, utilizing enantiopure [n]helicenes as a molecular wrench to intricately dictate the overall conformation of the NR.
Enantiopure [7]helicenes were stitched to the terminal K-regions of a conjugated pyrene NR using a stereospecific and site-selective palladium(II)-catalyzed annulative π-extension (APEX) reaction, resulting in a helically twisted NR with an end-to-end twist of 171°, the second-largest twist reported so far in the literature for twistacenes. The helical end-to-end twist increases with each addition of benzene ring to the central acene core, suggesting that the extra strain induced by the terminal [7]helicenes maintains such a high level of twist.
The quantum chemical calculations were conducted to investigate the impact of twisting on the conformational population. At room temperature, the central backbone of the nanoribbon adopts the twisted helicity opposite to that of the attached [7]helicene, constituting around 99% of the molecular population. For instance, (P)-[7]helicenes produce a left-handed helical nanoribbon, while (M)-[7]helicenes produce a right-handed helical nanoribbon. In the presence of helicenes of opposite chirality, the nanoribbon adopts a waggling conformation. The helically twisted nanoribbons are conformationally robust, as variable temperature chiroptical measurements showed no change in CD and CPL spectra. The proposed strategy, involving the late-stage addition of [n]helicene units through the APEX reaction, appears promising for streamlining the synthesis of diverse cove edge NR variants with desired conformations.
In addition to single-handed helically twisted nanoribbons, the symmetry-based functional properties of C2 and C1 symmetric pyrene-fused single and double [n]helicene compounds were studied. Owing to its higher structural rigidity, the C1 symmetric heptagonal ring-containing molecules exhibited exceptional configurational stability along with remarkable chiroptical properties compared to their C2 symmetric as well as pristine helicene congeners.
The goal of this thesis was to investigate the influence of rotational restriction between individual parts and of the varying electron density in the bridging unit of D B A systems on the exchange interaction 2J, and thus the electronic coupling between a donor state and an acceptor state. A better understanding of how to influence the underlaying spin dynamics in such donor acceptor systems can open up the door to new technologies, such as modern molecular electronics or optoelectronic devices.
Therefore, three series of molecules consisting of a TAA electron donor, a TTC or ATC bridging unit and a PDI electron acceptor were studied. To investigate the influence of rotational restriction on 2J and the electronic coupling, a series of four rotationally hindered triads (chapter 6) was synthesised. The dihedral angle between the TAA and the TTC as well as between the TTC and the PDI was restricted by ortho methyl groups at the phenylene linkers of the connecting ends to the TTC bridge, producing a twist around the linking single bond which minimises the π overlap. The triads exhibit varying numbers of ortho methyl groups and therefore different degrees of rotational restriction. In order to shine light on the influence of varying electron density on 2J and the electronic coupling, a series of four substituted triptycene triads (chapter 7) was synthesised. The electron density in the TTC bridging unit was varied by electron donating and electron withdrawing groups in 12,13 position of the TTC bridging unit and thus varying its HOMO/LUMO energy. The last series of two anthracene bridge triads (chapter 8) connected both approaches by restricting the rotation with ortho methyl groups and simultaneously by varying the bridge energies.
In order to obtain the electronic properties, steady state absorption and emission spectra of all triads were investigated (chapter 4). Here, all triads show spectral features associated with the separate absorption bands of TAA and the PDI moiety. The reduced QYs, compared to the unsubstituted PDI acceptor, indicate a non radiative quenching mechanism in all triads. The CV data (chapter 5) were used to calculate the energies of possible CSSs and those results were used to assign the CR dynamics into the different Marcus regions. fs TA measurements reveal that all triads form a CSS upon excitation of the PDI moiety. The lifetimes of the involved states and the rate constants were determined by global exponential fits and global target analysis. The CR dynamics upon depopulation of the CSSs were investigated using external magnetic field dependent ns TA spectroscopy. The ns TA maps show that all triads recombine via CRT pathway populating the local 3PDI state in toluene and provided the respective lifetimes. The approximate QYs of triplet formation were determined using actinometry. The magnetic field dependent ns TA data reveal the exchange interaction 2J between singlet and triplet CSS for each triad. Those magnetic field dependent ns TA data in toluene were furthermore treated using a quantum mechanical simulation (done by U.E. Steiner) to extract the rate constants kT and kS for CRT and CRS, respectively. However, the error margins of kS were rather wide. Finally, the electronic couplings between the donor and the acceptor states were obtained by combining the aforementioned experimental results of the rate constants and applying the Bixon Jortner theoretical description of diabatic ET and Andersons perturbative theory of the exchange coupling. Therefore, the experimentally determined values of 2J and the calculated values of kCS and kT were used. The rate constant kS was calculated based on the electronic coupling V1CSS 1S0.
The rotationally hindered triads (chapter 6) show a strong influence of the degree of rotational restriction on the lifetimes and rate constants of the CS processes. The rate constants of CS are increasing with increasing rotational freedom. The magnetic field dependent decay data show that the exchange interactions increase with increasing rotational freedom. Based on the CR dynamics, the calculated electronic couplings of the ET processes reflect the same trend along the series. Here, only singlet couplings turned out to be strongly influenced while the triplet couplings are not. Therefore, this series shows that the ET dynamics of donor acceptor systems can strongly be influenced by restricting the rotational freedom.
In the substituted triptycene triads (chapter 7), decreasing electron density in the bridging unit causes a decrease of the CS rate constants. The magnetic field dependent decay data show that with decreasing electron density in the bridge the exchange interaction decreases. The CR dynamics-based rate constants and the electronic couplings follow the same trend as the exchange interaction. This series shows that varying the HOMO/LUMO levels of the connecting bridge between donor and acceptor strongly influences the ET processes.
In the anthracene bridge triads (chapter 8), the CS process is slow in both triads. The CR was fast in the anthracene triad and is slowed down in the methoxy substituted anthracene bridge triad. The increase of the exchange interaction with increasing electron density in the bridge was more pronounced than in the substituted triptycene triads. Thus, the variation of electron density in the bridge strongly influences the ET processes even though the rotation is restricted.
In this thesis, it was shown that the influence of the rotational hindrance as well as the electron density in a connecting bridge have strong influence on all ET processes and the electronic coupling in donor acceptor systems. These approaches can therefore be used to modify magnetic properties of new materials.
This work illustrates how the targeted tailoring of supramolecular cavities can not only accomplish high binding due to optimized stereoelectronic shape matches between host and guest but also how molecular engineering of the binding site by a refined substitution periphery of the cavity makes enantiospecific guest recognition and host mediated chirality transfer feasible. Moreover, an enzyme mimic, following the Pauling-Jencks model of enzyme catalysis was realized by the smart design of a PBI host composed of moderately twisted chromophores, which drives the substrate inversion according to the concepts of transition state stabilization and ground state destabilization. The results of this thesis contribute to a better understanding of structure-specific interactions in host-guest complexes as well as the corresponding thermodynamic and kinetic properties and represent an appealing blueprint for the design of new artificial complex structures of high stereoelectronic shape complementarity in order to achieve the goal of sophisticated supramolecular receptors and enzyme mimicry.
Dipolar merocyanines are very attractive supramolecular building blocks, as they combine interesting functional properties with strong, directional intermolecular interactions. The pyridine dioxocyano-pyridine (PYOP) chromophore (Chapter 2.2), used in this thesis, stands out because of its exceptionally high ground state dipole moment (g ~ 17 D), in combination with the option to retain good solubility also in unpolar solvents, by decoration with solubilizing groups.
The reliable binding motif of anti-parallel -stacking due to dipole-dipole interactions has allowed the design of molecular building blocks that form assemblies of predictable geometry. The intense unstructured charge transfer UV/Vis absorption band (eg ~ 10.7 D) is a result of the dominant contribution of the zwitterionic resonance structure which brings the PYOP chromophore just beyond the cyanine limit in solvents of low polarity (c2 = 0.60, 1,4 dioxane). The high sensitivity of the S0 – S1 UV/Vis absorption band to the environment manifests itself in a pronounced negative solvatochromism and strong H-type exciton coupling within -stacked PYOP assemblies. In accordance with the classical molecular exciton theory, an increasing hypsochromic shift of the dominant absorption band of these H aggregates can be observed as the stack size increases up to about six chromophores, where it levels out at about max ~ 440 nm (CHCl3). This allows a uniquely simple estimation of the number of interacting chromophores within the self-assembled structure from a single UV/Vis absorption spectrum of an aggregate.
The defined and well investigated PYOP dimer formation was employed in this thesis to probe the applicability and limitations of concentration-, temperature-, and solvent-dependent self-assembly studies (Chapter 3). Straightforward theoretical models to evaluate datasets of concentration-, temperature-, and solvent-dependent UV/Vis absorption by nonlinear regression analysis were derived for the case of dimer formation (Chapter 2.1). Although the dimer model is well known and widely applied in literature, this detailed derivation is helpful to understand assumptions and potential problems of the different approaches for the determination of thermodynamic parameters. This helps to decide on the most appropriate method to analyse a system of interest. In this regard it should be noted that covering a large portion of the self-assembly process with the experimental data is a prerequisite for the accuracy of the analysis. Additionally, many of the insights can also be transferred to other self-assembly systems like supramolecular polymerization or host-guest interactions.
The concentration-dependent analysis is the most straightforward method to investigate self-assembly equilibria. No additional assumptions, besides mass balance and mass action law, are required. Since it includes the least number of parameters (only K, if M/D are known), it is the most, or even only, reliable method, to elucidate the self-assembly mechanism of an unknown system by model comparison. To cover a large concentration range, however, the compound must be soluble enough and generally sample amounts at least in the low mg scale must be available.
The temperature-dependent analysis has the advantage that all thermodynamic parameters G0, H0 and S0 can be obtained from a single sample in one automated measurement. However, the accessible temperature-range is experimentally often quite limited and dependent on the solvent. For systems which do not show the transition from monomer to aggregate in a narrow temperature range, as given for, e.g., cooperative aggregation or processes with a high entropy contribution, often not the entire self-assembly process can be monitored. Furthermore, the assumptions of temperature-independent extinction coefficients of the individual species as well as temperature-independent H0 and S0 must be met. Monte Carlo simulations of data sets demonstrated that even minor changes in experimental data can significantly impact the optimized values for H0 and S0. This is due to the redundancy of these two parameters within the model framework and even small thermochromic effects can significantly influence the results. The G0 value, calculated from H0 and S0, is, however, still rather reliable.
Solvent-dependent studies can often cover the entire self-assembly process from monomeric (agg = 0) to the fully aggregated state (agg = 1). However, for dyes with strong solvatochromic effects, such as the dipolar merocyanines investigated in this thesis, the results are affected. Also, the assumption of a linear relation of the binding energy G0 and the fraction of denaturating solvent f, which is based on linear free energy relationships between G0 and the solvent polarity, can lead to errors. Especially when specific solvent effects are involved.
For the evaluation of experimental data by nonlinear regression, general data analysis software can be used, where user-defined fit models and known parameters can be implemented as desired. Alternatively, multiple specialized programs for analysing self-assembly data are available online. While the latter programs are usually more user-friendly, they have the disadvantage of being a “black box” where only pre-implemented models can be used without the option for the user to adapt models or parameters for a specific system.
In Chapter 3 comprehensive UV/Vis absorption datasets are presented for the dimerization of merocyanine derivative 1 in 1,4-dioxane, which allowed for the first time a direct comparison of the results derived from concentration-, temperature-, and solvent-dependent self-assembly studies.
The results for the binding constant K and corresponding G0 from the concentration- and temperature-dependent analysis were in very good agreement, also in comparison to the results from ITC. For the temperature-dependent analysis, though, multiple datasets of samples with different concentration had to be evaluated simultaneously to cover a meaningful part of the self-assembly process. Furthermore, a significant dependence of the optimized parameters H0 and S0 on the wavelength chosen for the analysis was observed. This can be rationalized by the small thermochromic shifts of both the monomer and the dimer UV/Vis absorption band. The results from the solvent-dependent evaluation showed the largest deviation, as expected for the highly solvatochromic merocyanine dye.
However, even here by evaluation at 491 and 549 nm the deviation for G0 was only 2.5 kJ mol1 (9%) with respect to the results from the concentration-dependent analysis (G0 = 29.1 kJ mol1). Thus, despite the strong solvatochromism of the dipolar chromophore, it can still be considered a reliable method for estimating the binding strength. Furthermore, multiple repetitions of the concentration-, temperature-, and solvent-dependent studies provided insight into the reproducibility of the results and possible sources of experimental errors. In all cases, the deviations of the results were small (G0 < 0.4 kJ mol1) and within the same range as the fit error from the nonlinear regression analysis.
The insights from these studies were an important basis for the in-depth investigation of a more complex supramolecular system in Chapter 4, as a single method is often not enough to capture the full picture of a more complicated self-assembly process. To elucidate the anti-cooperative self-assembly of the chiral merocyanine 2, a combination of multiple techniques had to be applied.
Solvent-dependent UV/Vis absorption studies in CH2Cl2/MCH mixtures showed the step-wise assembly of the merocyanine monomer (max(M) = 549 nm, CH2Cl2) to first a dimer (max(D) = 498 nm, CH2Cl2/MCH 15:85) by dipole-dipole interactions, and then a -stacked higher aggregate (max(H) = 477 nm, MCH), with pronounced H-type coupling.
The thermodynamic evaluation of this data, however, suffered from the severe solvatochromism, especially of the monomeric species (max(M, CH2Cl2) = 549 nm, max(M, MCH) = 596 nm). Therefore, concentration-dependent studies were performed at three different temperatures (298, 323, 353 K) to elucidate the self-assembly mechanism and determine reliable thermodynamic parameters. The studies at elevated temperatures were hereby necessary, to obtain experimental data over a larger agg--range. Due to the pronounced difference in the thermodynamic driving force for dimerization and higher aggregate formation (KD/K5 = 6500) a concentration range exists in MCH where almost exclusively the dimer species of 2 is present, before further self-assembly by dispersion interactions occurs. Therefore, the data could be evaluated independently for the two self-assembly steps. The self-assembly of dimers into the higher aggregate could not be described by the isodesmic model but was fitted satisfactorily to a pentamer model. This rather small size of about ten -stacked PYOP chromophores was, furthermore, consistently indicated by AFM, VPO and DOSY NMR measurements. Based on 1D and 2D NMR data as well as the strong bisignate CD signal of the higher aggregate in combination with TD-DFT calculations, a P-helical stack is proposed as its structure. The small size can be rationalized by the anti-cooperative self-assembly mechanism and the sterical demand of the solubilizing trialkoxyphenyl and the chiral tetralin substituents. Additionally, the aliphatic shell formed by the solubilizing chains around the polar chromophore stack, can account for the exceptionally high solubility of 2 in MCH (> 15 mg mL1). These combined studies of the self-assembly process enabled the identification of suitable conditions for the investigation of fluorescence properties of the individual aggregate species. Aggregation-induced emission enhancement was observed for the almost non-emissive monomer (Fl(M) = 0.23%), which can be rationalized by the increasing rigidification within the dimer (Fl(D) = 2.3%) and the higher aggregate (Fl(H) = 4.5%). The helical chirality of the PYOP decamer stack, furthermore, gave rise to a strong CPL signal with a large glum value of 0.011.
The important conclusion of this thesis is that the temperature- and solvent-dependent analyses are valid alternatives to the classical concentration-dependent analysis to determine thermodynamic parameters of self-assembly equilibria. Although, for a specific supramolecular system, one approach might be favourable over the others for a variety of reasons. The experimental limitations often demand a combination of techniques to fully elucidate a self-assembly process and to gain insights in the aggregate structure. The anti-cooperative merocyanine self-assembly, which was described here for the first time for the PYOP merocyanine 2, is no exception. Besides the interest in the merocyanine assemblies from a structural and functional point of view, the insights gained from the presented studies can also be transferred to other self-assembly systems and be a guide to find the most appropriate analysis technique.
In aqueous environment, hydrophobic interactions play an important role for DNA. The introduction of modifications based on hydrophobic aromatic moieties offers additional ways for controlling recognition and reactivity of functional groups in DNA. Modifications are introduced through an artificial backbone or in the form of an extension of the nucleobases, resulting in additional properties of the DNA.
This dissertation focuses on the use of hydrophobic units for the functionalization of DNA.
In the first part of the work, the tolane (i. e. diphenylacetylene) motif was used in combination with the acyclic backbone of GNA and BuNA to generate recognition units in the DNA context. Fluorination of the aromatic rings in the tolane moiety provided the basis for a supramolecular language based on arene-fluoroarene interactions. The specific recognition was investigated by thermodynamic, kinetic and NMR spectroscopic methods.
In the second part of the work, deoxyuridine derivatives with a hydrophobic aromatic modification were prepared and incorporated into DNA duplexes. The irradiation with UV light led to a [2+2] cycloaddition reaction between two modified nucleosides in the DNA. This reaction product was structurally characterized and the reaction was used in various biochemical and nanotechnological DNA applications.
In this thesis, the usage of onion-like carbon (OLC) for energy storage applications was researched regarding sustainability, performance and processability. This work targets to increase the scientific understanding regarding the role of OLC in electrodes and to facilitate a large-scale production, which is the foundation for commercial application. Research was devoted to increase the knowledge in the particular field, to yield synergistic approaches and a shared value regarding sustainability and performance.
The chirality of the interlocked bay-arylated perylene motif is investigated upon its material prospect and the enhancement of its chiroptical response to the NIR spectral region. A considerable molecular library of inherently chiral perylene bisimides (PBIs) was utilized as acceptors in organic solar cells to provide decent device performances and insights into the structure-property relationship of PBI materials within a polymer blend. For the first time in the family of core-twisted PBIs, the effects of enantiopurity on the device performance was thoroughly investigated. The extraordinary structural sensitivity of CD spectroscopy served as crucial analytical tool to bridge the highly challenging gap between molecular properties and device analytics by proving the excitonic chirality of a helical PBI dimer. The chirality of this perylene motif could be further enhanced on a molecular level by both the expansion and the enhanced twisting of the π-scaffold to achieve a desirable strong chiroptical NIR response introducing a new family of twisted QBI-based nanoribbons. These achievements could be substantially further developed by expanding this molecular concept to a supramolecular level. The geometrically demanding supramolecular arrangement necessary for the efficient excitonic coupling was carefully encoded into the molecular design. Accordingly, the QBIs could form the first J-type aggregate constituting a fourfold-stranded superhelix of a rylene bisimide with strong excitonic chirality. Therefore, this thesis has highlighted the mutual corroboration of experimental and theoretical data from the molecular to the supramolecular level. It has demonstrated that for rylene bisimide dyes, the excitonic contribution to the overall chiroptical response can be designed and rationalized. This can help to pave the way for new organic functional materials to be used for
chiral sensing or chiral organic light-emitting devices.
The focus of this work was the development and application of highly efficient RNA catalysts for the site-specific modification of RNA with special focus on methylation. In the course of this thesis, the first methyltransferase ribozyme (MTR1), which uses m6G as the methyl group donor was developed and further characterized. The RNA product was identified as the natural modification m1A. X-Ray crystallography was used to solve the 3D structure of the ribozyme, which directly suggested a plausible reaction meachnism. The MTR1 ribozyme was also successfully repurposed for a nucleobase transformation reaction of a purine nucleoside. This resulted in a formyl-imidazole moiety directly on the intact RNA, which was directly used for further bioconjugation reactions. Finally, additional selections and reselections led to the identification of highly active alkyltransferase ribozymes that can be used for the labeling of various RNA targets
The present thesis adress the synthesis and characterization of novel COFs that contain dye molecules as integral components of the organic backbone. These chromophore-containing frameworks open new research lines in the field and call for the exploration of applications such as catalysis, sensing, or in optoelectronic devices. Initially, the fabrication of organic-inorganic composites by the growth of DPP TAPP COF around functionalized iron oxide nanoparticles is reported. By varying the ratio between inorganic nanoparticles and organic COFs, optoelectronic properties of the materials are adjusted. The document also reports the synthesis of a novel boron dipyrromethene-containing (BODIPY) COF. Synthesis, full characterization and the scope of potential applications with a focus on environmental remediation are discussed in detail. Last, a novel diketopyrrolopyrrole-containing (DPP) DPP-Py-COF based on the combination of DDP and pyrene building blocks is presented. The very low bandgap of these materials and initial investigations on the photosensitizing properties are discussed.
In this thesis, intermolecular acceptor-acceptor interactions in organic solar cells based on new non-fullerene acceptors are addressed. For this purpose, first the reproducibility of organic electronic devices was tested on a new facility for their fabrication. This was followed by the screening for new acceptor materials. Based on this, three molecular systems were investigated with regard to their acceptor-acceptor interactions and their influence on solar cell efficiency.