Department of Chemistry

Understanding the chemistry and biology of peptides and proteins and developing new approaches for manipulating these properties with purposefully designed small organic molecules. Employing chemical synthesis and combinatorial chemistry as well as spectroscopic and biophysical methods to accomplish these aims. Projects include:

• Development of peptidomimetics for the treatment of Diabetes Mellitus
• Development of therapeutic agents for biodefense against bacterial infection

Nanoporous metal oxides, which includes zeolites and related molecular sieves as well as layered materials. Projects include the preparation, modification and application of molecular sieves in areas ranging from catalysis to chemical sensors. Zeolite supported catalysts and host/guest materials include immobilized enzymes. Pulsed laser deposition and electrostatic deposition are used to prepare molecular sieve films and fibers respectively as part of an effort in membranes for gas separation, photovoltaics and fuel cells.

Nanotechnology, photonic crystals, sensors and actuators, ferroelectrics, novel forms of carbon (especially carbon nanotubes), and conducting polymers; Solid-state reactions, electrochemical processes and devices; Materials with unusual mechanical properties; Design, synthesis, and application of materials with novel electrical, optical, or magnetic properties

Designing monolayers with specific intermolecular interactions within the monolayer structure; design of molecular level sensors and switches; in collaboration with the NanoTech Institute at UTD, we are attempting to prepare single walled carbon nanotubes through an organic synthesis approach.

Affiliated Faculty

Dr. Bulla's research interests are in the area of invertebrate and microbial molecular biology with particular focus on the biochemical and biophysical characterization of insecticidal toxin receptors in insects.

United Technologies Research Center

Chemical education, organic synthesis/NMR spectroscopy

Using an integrative approach, the Dieckmann Lab utilizes protein design to create simple model systems. These systems provide insights into the functioning of more complex biological systems, or yield new bio/nano hybrid materials.

molecular mechanisms of membrane trafficking in eukaryotic cells and applications of molecular and cell biology to the emerging field of bionanotechnology.

The main research thrusts of Prof. Ferraris' group are on electroactive polymers. In the past few years, Ferraris' group has contributed significantly to the scientific literature on various issues regarding electrochromics, electrochemical capacitors, light emitting polymers, membranes for gas separations, polymeric solar cells, and fuel cell membranes.

Associate Professor, UT Southwestern

Research specialization areas:

• Enzyme mechanisms
• Tissue metabolism

• electronic materials with an emphasis on dielectrics (low-K, high-K, and gate dielectrics other than SiO 2)
• field emission materials, thin-film getters, and spacer materials
• organic electronics

Neurofibrillary tangles (NFTs) are one of the two hallmark lesions of Alzheimer’s disease (AD) and their accumulation has been used to assess the severity of the disease. They are composed of paired helical filaments (PHF), a form of amyloid resulting from the aggregation of the microtubule-associated protein tau. Our laboratory has found that peptides as short as 3-6 amino acids are able to initiate the formation of twisted filaments, similar to PHF. We believe that these short amyloid-forming peptides provide an excellent model for studying the structural basis of PHF and amyloid, in general.

Development of advanced materials for organic electronics and medicine.  The research projects include:

• Novel semiconducting polymers  for organic electronics
• Tailoring of organic/inorganic interface in organic field effect transistors (OFETs) and photovoltaic devices
• Block-copolymers containing semiconducting polymers and liquid crystalline polymers as electronic materials with tunable opto-electronic properties
• Biodegradable polymers with tunable rates of degradation for applications in localized and controlled drug delivery

The listed research projects are interdisciplinary thus allowing the students to gain experience in organic/polymer chemistry and materials science.

Current research in the Musselman Group has 4 emphases with a microscopy theme in common. Projects include:

• Mechanisms of contrast and limits of contrast resolution in scanning tunneling microscopy (STM) images of molecular adsorbates
• Peptide/single-walled carbon nanotube interactions explored using STM and atomic force microscopy (AFM)
• Fabrication and testing of polymer-based mixed-matrix membranes for gas separations
• Development and testing of high temperature proton exchange membranes for fuel cells

The focus of the Nielsen Lab is on the study of self-assembly. We currently focus on computer simulations of peptide solubilization of single wall carbon nanotubes, on theory and simulations for colloidal nanoparticles, and on the calculation of surface tension at nano-interfaces.

The driving force of PantanoLABO is the development of elegant analytical techniques and methodologies to understand complex chemical systems. Areas of expertise include the characterization of single-walled carbon nanotube (SWNT)-containing powders, the reproducible preparation of purified SWNT dispersions, and the development of direct and label-free measurements of SWNTs inside living cells and tissue.

Our chemistry group at UT Dallas is involved in the design of novel MR imaging agents that are responsive to physiology and metabolism.

• High relaxivity Gd3+-based agents that respond to binding events in vivo.

• Slow water exchange paramagnetic complexes that introduce MR contrast by a novel mechanism called chemical exchange saturation transfer (CEST). Paramagnetic CEST agents are now widely referred to a PARACEST agents.

Research program is centered around the synthesis and coordination chemistry of novel classes of macrocyclic receptors with applications that range from catalysis to medicine to materials science. Specific research areas include:

• The "Wurster's" Crowns - Redox-Active Macrocyclic Receptors
• Novel Lipophilic Hosts/Oligomeric Metal Complexes for use in Cancer Therapy/Diagnosis
• Macrocycle Synthesis and Coordination Chemistry
• Supramolecular Chemistry: Organic Host-Guest Systems
• Bioinorganic Chemistry

• Conductive transparent coating research and their applications for displays and transparent electronics circuits
• Novel synthesis study of nano size particles and their applications study for use in electronics or energy devices
• Atmospheric, continuous growth of carbon nanotubes (CNTs) using PECVD
• Bio and chemical sensor research: DNA and Methanol detection utilizing carbon nanotubes (CNTs)
• High temperature membrane research for hydrogen and methanol fuel cells
• Hydrogen storage research using catalytic dehydrogenation/hydrogenation of organic molecules
• Imprint mask study using less than 30nm design rule

• Advanced Carbon Nanomaterials: Nanotubes, Fullerenes,
• Photonic Crystals and Negative index materials
• Conjugated polymers and Molecular Organic solids
• Organic Light Emitting Devices
• Plastic solar cells

• investigating fundamental structure-property relationships of nanomaterials at bulk and single molecular level
• exploring their applications in:
  • bioimaging
  • catalysis
  • energy conversion