Unactivated Alkyl Chloride Reactivity in Excited-State Palladium Catalysis

Gimnkhan, Aidana

11 1900

In the last centuries, transition metal chemistry beсome one оf the mоst іmportant tооls for synthesis of valuable organic compounds and different chemical transformations. In particular, transition metal catalysis are capable of forming novel cross coupling bonds. In this background, photocatalysis was developed later to create new chemical transformations by the irradiation with visible light. In this regard, the combination of transition metal catalysis and photochemistry is a breakthrough in catalysis that has provided impossible transformations in organochemistry. One of the widely available reactants in synthesis are alkyl chlorides. However, it is hard to activate chemically stable C(sp3 )-Cl bond at room temperature. In this study, we overcome this limitation by excited-state palladium catalysis under mild conditions. The reaction goes through the hybrid alkyl-Pd radical as a key intermediate. The procedure provides the synthesis of oxindole and isoquinolinedione derivatives mainly from alkyl chlorides via annulation overcoming its chemical limitations. This work will focus on the generation of alkyl radicals from unactivated C(sp3 )-Cl using simple palladium catalysis

Photcatalysis

Cross coupling

Pd catalysis

Cerium Incorporation into ACM-1 Titanium Metal-Organic Framework for Visible-Light Driven Photocatalytic Hydrogen Production

Alfaraidi, Abdulrahman M.

07 1900

A serious challenge in photocatalytic solar fuel production lies in the design of efficient catalysts that are stable, have visible light response and are easy to make. In order to realize this goal, efforts should be focused on designing new photocatalysts that have such properties to drive the field forward towards commercialization. Metal-Organic Frameworks (MOFs) are a class of crystalline and porous materials that offer tunable and diverse structural and electronic properties that can be exploited for enhanced photocatalytic solar fuels production. This thesis focuses on the utilization and characterization of a 3-D MOF photocatalyst with metal-oxo chain and pyrene-based ligand as secondary building units. Specifically, through hydrothermal synthesis technique, we constructed a bimetallic cerium/titanium MOF that exhibits excellent and stable photoactivity for visible-light driven hydrogen generation. The incorporation of two redox active metals of CeIII /CeIV and TiIII/TiIV in an oxo-chain connected by a photosensitizing organic ligand resulted in a strong ligand-tometal charge transfer (LMTC), evident by EPR, for efficient reduction of water. A high hydrogen production rate of 49 μmol h-1 was achieved, which is attributed to energetic LMTC and better charge separation. This work expands on MOFs photocatalysis field and open new direction towards designing redox active heterometallic MOFs for solar fuels production.

MOFs

Titanium-MOFs

Cerium MOFs

Photcatalysis

Hydrogen Evolution

Text

Interfacing Biomolecules with Nanomaterials for Novel Applications

Lal, Nidhi

January 2014

This thesis deals with the research work carried out for the development of novel applications by integrating biomolecules with various nanostructures. The thesis is organized as follows: Chapter 1 reviews the properties of nanomaterials which are important to consider while developing them for various biological and other applications. It discusses the factors which affect the cytotoxicity of nanocrystals towards living cells, photocatalytic mechanisms of nanocrystals that work behind the inactivation of bacterial cells and gas sensing properties of nanocrystals. It also mentions about the integration of biomolecules with nanomaterials which is useful for the development of biosensors, materials that are presently used for fabricating biosensors and the challenges associated with designing successful biosensors. Chapter 2 presents the antibacterial and anticancer properties of ZnO/Ag nanohybids. In this study a simple route to synthesize ZnO/Ag nanohybrids by microwave synthesis has been established where ZnO/Ag nanohybrids have shown synergistic cytotoxicity towards mammalian cells. The observed synergism in the cytotoxicity of ZnO/Ag nanohybrids could lead to the development of low dose therapeutics for cancer treatment. Chapter 3 presents photocatalytic inactivation of bacterial cells by pentavalent bismuthates class of materials. AgBiO3 which was obtained from KBiO3 by ion-exchange method was investigated for its photocatalytic inactivation properties towards E.coli and S.aureus cells under dark and UV illumination conditions. Chapter 4 presents the integration of DNA molecules with ZnO nanorods for the observation of Mott-Gurney characteristics. In this study, ZnO nanorods were synthesized hydrothermally and were characterized by TEM and XRD analysis. DNA molecules were immobilized over ZnO nanorods which were confirmed by UV-Vis spectroscopy and confocal florescence microscopy. Solution processed devices were fabricated by using these DNA immobilized nanostructures and I-V characteristics of these devices were taken in dark and under illumination conditions at different wavelengths of light at fixed intensity. Interestingly, Mott-Gurney law was observed in the I-V characteristics of the devices fabricated using DNA immobilized ZnO nanorods. Chapter 5 presents the chemical synthesis of molecular scale ultrathin Au nanowires. These nanostructures were then used for fabricating electronic biosensors. In this study, the devices were fabricated over Au nanowires by e-beam lithography and a methodology to functionalize Au nanowires and then characterize them by florescence microscopy as well as AFM has been established. The fabricated biosensors were employed for the label free, electrical detection of DNA hybridization process. Chapter 6 presents a simple, cost effective and solution processed route to fabricate devices using ultrathin Au nanowires. The devices were then used for sensing ethanol, H2 and NH3. An important property of these devices is that they can sense these gases at room temperature which reduce their operation cost and makes them desirable to use under explosive conditions.

Biomolecules

Nanomaterials

ZnO/Ag Nanohybrids

DNA Functionalized ZnO Nanorods

Gold Nanowires

Nanomaterial based Biosensors

Biomolecule Nanomaterials Interface

Nanomedicine

Zinc Oxide (ZnO) Nanostructures

Bio-Organic Semiconductor Composites

Nanomaterials - Gas Sensing

Nanomaterials - Photcatalysis

Nanocrystals - Cytotoxicity

Bio-Nanotechnology

Biosensors

Au Nanowires

Materials Science