Dissertation Defense Announcements

Nucleic acid biopolymers are essential to all living organisms. The chemical makeup of deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) consist of sequences of only four monomers. However, they transmit and express genetic information for various biological functions based on stored blueprints. Along with communicating the flow of genetic information (DNA → RNA→ protein), nucleic acids have also become a preferred material for fabrication of objects and scaffolds at the nanoscale. Nucleic acid-based assemblies that interact with each other and communicate with the cellular machinery represent a new class of reconfigurable nanostructures that enable precise control over their formulation and physicochemical properties and activation of multiple biological functionalities. Therefore, the use of nucleic acids offers a unique platform for development of nanoparticles which consist of nanoscale-size oligonucleotides designed to fold into predicted three-dimentional structures. They can serve as scaffolds capable of carrying numerous functional moieties such as: RNA interference activators for gene silencing, aptamers for specific targeting of selected molecules, immunostimulatory sequences for modulating immune responses, and fluorescent entities for bioimaging. Programmable, controllable, biocompatible, rationally designed, and self-assembled nucleic acid nanoparticles have become attractive candidates for diverse therapeutic options. Despite profound advances in the field of therapeutic nucleic acids, their negative charges decrease membrane permeation capacity, thus hindering their translation from experimental research to clinical application. This dissertation focuses on the development of nucleic acid nanoparticles as therapeutics with defined immunostimulatory properties accompanied by rationally designed systems able to regulate the duration of therapeutic activity. Furthermore, a safe, efficient and stable intracellular delivery system for multi-functional nucleic acid nanoparticle platforms is investigated.

Climate change is one of the most pivotal issues for the world in which we live today.

The power grid transformation to become, smarter sustainable and carbon-free,

has been a primary emphasis in recent times. This includes the integration of Distributed

Energy Sources (DERs). In this work, innovative and novel techniques are

presented to facilitate and expedite the engineering, planning, and deployment of

high penetration levels of renewable and distributed energy resources to aggressively

attack climate change and move the industry to a new paradigm. Towards this end,

both traditional and non-traditional techniques and methodologies are leveraged to

enhance distribution planning methods such that more electric distribution feeders

can be analyzed more dynamically. Tried and true iterative mathematical techniques

and convergence algorithms are used to adhere to the Laws of Physics for the flow of

electricity.

Findings in the area of Control Theory and System Identification are used to develop

dynamic and predictive models of the electric distribution system that analyze

the impact of interconnecting high levels of renewable generation. These predictive

models are represented by parametric models or transfer functions developed from the

Laplace Transform technique, leveraging proven powerful tools of time-domain and

frequency domain analysis to evaluate system stability. Critical to this work is both

the validation of realized models wherein these models can accurately predict system

response at varying load levels, renewable energy penetration levels, all-around necessary

sensitivities. Such a dynamic model development process can be used and

applied to any electric distribution feeder to better optimize penetration levels and

provide the planning engineer with smart models to optimize system planning.

Ultra-precision manufacturing is a deterministic method of producing optical-grade components. Continuous and interruptive machine operations are the main focus of this research with the goal of improving the manufacturing communities knowledge. The original contributions of this research are: (a) a comprehensive analysis of the cutting mechanics of single-crystal germanium, specifically studying the effects of major crystal orientation in germanium and cutting speed; (b) methodology for producing
flat, damage-free test samples in single-crystal germanium; and (c) machine learning model for estimating surface finish parameters Sa, Sq, and Sz for SPDT of single-crystal germanium and oxygen-free high-conductivity copper. As a final product of this research, a pair of collimating lenses were produced. AFRL funded the research for development of these lenses.

Demand for clean and safe drinking water is a global challenge because of water scarcity, growth of human population, urbanization, and anthropogenic pollution. Purification of water involves removal of small molecules and ions from ground water addressed as “emerging contaminants” which are extremely mobile and toxic in nature, do not degrade or hydrolyze easily, and highly soluble in water resulting in bioaccumulation. Most of the current water treatment systems have complex deficiencies that affect their overall performance. We have synthesized carbon nanostructures assisted ion exchange resins in aqueous medium that help remove these emerging contaminants in a fast, easy, and high capacity manner while supporting less contact time and low transmembrane resistance primarily achieved using thin film assemblies. We have developed a novel sonochemistry assisted atom transfer radical polymerization (SONO-ATRP) process for synthesis of polyelectrolyte anion exchange resins in water without use of any external initiator or reducing agents while using only a few ppm of catalyst. We successfully performed high-density functionalization of polyelectrolyte anion exchange resin strands onto single walled carbon nanotubes sidewalls using the SONO-ATRP process while at low reaction temperatures thereby providing a less energy intensive alternative for green chemistry. We have developed green processes to defluorinate fluorographite in water and simultaneously perform covalent grafting of anionic short brushes of poly(vinyl benzyl trimethylammonium chloride) to its surface under mild reaction conditions without need of any external reactive reagents. Field Emission Scanning Electron microscopy of thin film of functionalized carbon nanotubes demonstrated pin-hole free mesoporous architecture illustrating scaffold robustness while thin films of functionalized fluorographite exhibited stacked arrangement of plate-like structures. Exfoliation and functionalization of fluorographite was revealed through Transmission Electron Microscopy. Both the resins demonstrated high water flux (>1500 L m^(-2) h^(-1) bar^(-1)) due to their intrinsic architecture and high percent removal (>90%) of contaminants due to the tortuous path length during molecular transport through the membrane. These properties enable adsorption of impurities at environmentally relevant concentrations. These materials exhibited facile regeneration and reusage of the thin films, thus supporting sustainability. In conclusion, these processes abide by the principles of green chemistry and their processability opens new avenues for smart point-of-use water purification systems.