@phdthesis{Merz2022,
  author    = {Merz, Viktor},
  title     = {Funktionalisierung und Untersuchung von Nanodiamanten f{\"u}r biomedizinische und sensorische Anwendungen},
  doi       = {10.25972/OPUS-24588},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-245888},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2022},
  abstract  = {Nanodiamant (ND) ist ein vielseitiges und vielversprechendes Material f{\"u}r Bio-Anwendungen. Trotz vieler Bem{\"u}hungen bleibt die Agglomeration von Nanodiamant und die unspezifische Adsorption von Proteinen an der ND-Oberfl{\"a}che bei Kontakt mit Biofl{\"u}ssigkeiten ein großes Hindernis f{\"u}r biomedizinische Anwendungen. Eine Auswahl verzweigter und linearer Molek{\"u}le mit {\"u}berlegener F{\"a}higkeit zur kolloidalen Stabilisierung von Nanopartikeln in Salz- und Zellmedienumgebung, f{\"u}r bis zu 30 Tage, wurde an die ND-Oberfl{\"a}che angebracht. Das Baukastensystem mit Azid als Außengruppen bietet eine große Vielfalt an Bindungen mit vielen Molek{\"u}len, wie z. B. Medikamenten, Farbstoffen oder Targeting-Molek{\"u}len. Das Anh{\"a}ngen von z. B. Zwitterionen an die Kette sch{\"u}tzt die ND-Oberfl{\"a}che vor der Bildung einer Proteinkorona, wenn die Partikel mit proteinhaltigen Biofl{\"u}ssigkeiten in Kontakt kommen. Die Ergebnisse der thermogravimetrischen Analyse der Beladung der ND-Oberfl{\"a}che zeigen eine signifikante Verhinderung der Proteinadsorption von bis zu 98 \% im Vergleich zu NDs ohne zwitterionische Kopfgruppen und eine lange kolloidale Stabilit{\"a}t, wenn Tetraethylenglykol (TEG) an die Oberfl{\"a}che gebunden wird. Die Vielseitigkeit des modularen Systems, um nicht nur zwitterionische Ketten, sondern auch klickbare funktionelle Molek{\"u}le an fluoreszierende Nanodiamanten (fNDs) zu binden, zeigt das Potenzial des Systems am Nanodiamanten. Unter Verwendung von Defektstrukturen, wie Stickstoff-Vakanz-Zentren (NV), k{\"o}nnen Diamantpartikel aufgrund ihres weitgehend ungiftigen Verhaltens als fluoreszierende Nanodiamanten (fNDs) f{\"u}r photostabile Markierung, Bioimaging und nanoskalige Sensorik in lebenden Zellen und Organismen verwendet werden. Um die fND-Oberfl{\"a}che zu funktionalisieren, wurde eine neuartige Mahltechnik mit Diazoniumsalzen etabliert, um ein Pfropfen auf wenig reaktive HPHT-fNDs durchzuf{\"u}hren, was zu einer hohen Oberfl{\"a}chenbeladung und einem hohen negativen Zetapotenzial f{\"u}hrt. Die Kombination der Vorteile von TEG und zwitterionhaltigen Gruppen mit der F{\"a}higkeit zum Targeting von Antik{\"o}rpern auf fND best{\"a}tigt zum ersten Mal die verbesserte kolloidale Stabilit{\"a}t in Experimenten mit lebenden Zellen. Dar{\"u}ber hinaus deuten die Ergebnisse auf eine verbesserte Corona-Abstoßung im Vergleich zu fND ohne zwitterionhaltige Kopfgruppen hin. Infolgedessen wurden die Zirkulationszeiten von 4 (fND ohne Zwitterionenkette, aber mit Antik{\"o}rper) auf 17 (mit Antik{\"o}rper und Zwitterionenketten) Stunden vergr{\"o}ßert. In nicht-biomedizinischen Anwendungen kann das modulare System als Sonde f{\"u}r Schwermetalle durch die Anbindung von Farbstoffen verwendet werden. Die Detektion von Metallen in verschiedenen Umgebungen mit hoher Selektivit{\"a}t und Spezifit{\"a}t ist eine der Voraussetzungen f{\"u}r den Kampf gegen die Umweltverschmutzung mit diesen Elementen. Pyrene sind gut geeignet und weit bekannt f{\"u}r die Fluoreszenzsensorik in verschiedenen Medien. Das angewandte Sensorprinzip beruht typischerweise auf der Bildung von intra- und intermolekularen Excimeren, was jedoch den Empfindlichkeitsbereich aufgrund der Maskierung von z.B. Quenching-Effekten durch die Excimer-Emission einschr{\"a}nkt. Diese Studie zeigt einen hochselektiven, strukturstabilen chemischen Sensor, der auf der monomeren Fluoreszenz von Pyrenanteilen mit Triazolgruppen basiert. Dieser Sensor kann Cu2+, Pb2+ und Hg2+ in organischen L{\"o}sungsmitteln {\"u}ber einen weiten Konzentrationsbereich quantitativ nachweisen, auch in Gegenwart von ubiquit{\"a}ren Ionen wie Na+, K+, Ca2+ und Mg2+. Die stark emittierende Fluoreszenz des Sensors mit einer langen Lebensdauer von 165 ns wird durch eine 1:1-Komplexbildung bei Zugabe von Metallionen in Acetonitril gel{\"o}scht. Bei Zugabe eines zehnfachen {\"U}berschusses des Metallions zum Sensor bilden sich Agglomerate mit einem Durchmesser von etwa 3 nm. Aufgrund der komplexen Wechselwirkungen im System werden konventionelle lineare Korrelationen nicht f{\"u}r alle Konzentrationen beobachtet. Daher wird ein kritischer Vergleich zwischen der konventionellen Job-Plot-Interpretation, der Methode von Benesi-Hildebrand und einem nicht-linearen Fit vorgestellt. Das vorgestellte System erm{\"o}glicht die spezifische und robuste Erfassung von medizinisch und {\"o}kologisch relevanten Ionen im gesundheitsrelevanten nM-Bereich und k{\"o}nnte z. B. zur {\"U}berwachung der entsprechenden Ionen in Abfallstr{\"o}men eingesetzt werden. Doch h{\"a}ufig landen diese Abfallstr{\"o}me in empfindlichen Aquakulturen, wo eine solche Sensortechnik nur funktioniert, wenn die Sonde wasserl{\"o}slich ist, um die Ausbreitung und Bildung von Umweltsch{\"a}den durch Schwermetalle zu {\"u}berwachen. Viele Chemosensoren arbeiten nur in bestimmten L{\"o}sungsmitteln und unter hochreinen Bedingungen quantitativ. In dieser Arbeit wird eine Methode zur Stabilisierung von wasserunl{\"o}slichen Chemosensoren auf Nanodiamanten in salzhaltigem Wasser unter Beibehaltung der Sensoreffektivit{\"a}t und -spezifit{\"a}t sowie der kolloidalen Stabilit{\"a}t vorgestellt. Zus{\"a}tzlich wird die Sensorf{\"a}higkeit in organischen L{\"o}sungsmitteln beibehalten. Diese Studie gibt Einblick in die Absorptionsf{\"a}higkeit von Pyren-Derivaten an der Nanodiamant-Oberfl{\"a}che und einen Weg, diese reversibel zu desorbieren. Außerdem beweist das System, dass in Anwesenheit von 95 \% Sauerstoffatmosph{\"a}re bei der Fluoreszenzmessung die Ergebnisse nicht von denen in Argonatmosph{\"a}re abweichen. Dar{\"u}ber hinaus st{\"o}rt das Vorhandensein g{\"a}ngiger Ionen im Wasser die kolloidale Stabilit{\"a}t der NDs nicht und hat auch keinen Einfluss auf die Sensorfunktionalit{\"a}t und ist somit ein vielversprechender Kandidat f{\"u}r Messungen ohne aufw{\"a}ndige Pr{\"a}parationsschritte.},
  language  = {en}
}
@phdthesis{Roos2021,
  author    = {Roos, Markus},
  title     = {Synthesis, Photophysics and Photocatalysis of [FeFe] Complex Containing Dyads and Bimolecular Systems},
  doi       = {10.25972/OPUS-23453},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-234537},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {In the course of this work, a total of three photocatalytically active dyads for proton reduction could be synthesized together with the associated individual components. Two of them, D1 and D2, comprised a [Ru(bpy)3]2+ photosensitizer and D3 an [Ir(ppy)2bpy]+ photosensitizer. A Ppyr3-substituted propyldithiolate [FeFe] complex was used as catalyst in all systems. The absorption spectroscopic and electrochemical investigations showed that an inner-dyadic electronic coupling is effectively prevented in the dyads due to conjugation blockers within the bridging units used. The photocatalytic investigations exhibited that all dyad containing two-component systems (2CS) showed a significantly worse performance than the corresponding bimolecular three-component systems (3CS). Transient absorption spectroscopy showed that the 2CS behave very similarly to the associated multicomponent systems during photocatalysis. The electron that was intended for the intramolecular transfer from the photosensitizer unit to the catalyst unit within the dyads remains at the photosensitizer for a relatively long time, analogous to the 3CS and despite the covalently bound catalyst. It is therefore assumed that this intramolecular electron transfer is likely to be hindered as a result of the weak electronic coupling caused by the bridge units used. Instead, the system bypasses this through an intermolecular transfer to other dyad molecules in the immediate vicinity. In addition, with the help of emission quenching experiments and electrochemical investigations, it could be clearly concluded that all investigated systems proceed via the reductive quenching mechanism during photocatalysis.},
  subject      = {Fotokatalyse},
  language  = {en}
}
@phdthesis{Roger2024,
  author    = {Roger, Chantal},
  title     = {Photophysics and Spin Chemistry of Triptycene Bridge Donor-Acceptor-Triads},
  doi       = {10.25972/OPUS-36303},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-363031},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {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.},
  subject      = {Rotation},
  language  = {en}
}
@phdthesis{Swain2024,
  author    = {Swain, Asim},
  title     = {Helically Twisted Graphene Nanoribbons: Bottom-up Stereospecific Synthesis and Characterization},
  doi       = {10.25972/OPUS-36016},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-360164},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {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.},
  subject      = {Helicene},
  language  = {en}
}
@phdthesis{Weh2024,
  author    = {Weh, Manuel},
  title     = {Chiral Perylene Bisimide Cyclophanes},
  doi       = {10.25972/OPUS-31529},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-315296},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {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.},
  language  = {en}
}