First name,Last name,Preferred title,Overview,Position,Department,Individual
Emile,Schweikert,Professor,"Our research explores the extreme limits of analytical chemistry: the characterization of atto to zeptomole quantities of molecules. The aim is to detect such amounts of analyte within nanometric surface volumes. The goal is chemical imaging of surfaces with exquisite spatial resolution. The first challenge is to conceive methods and instrumentation for the accurate identification of as little as a few thousand molecules. The second challenge is to convert a measurement into analytical information. A measurement by itself, even a spectacular one such as detection of a single atom or molecule, is not sufficient. Measurements must be related to the physico-chemical system sampled in terms of concentration and/or spatiotemporal localization.
Our experimental procedure is based on the desorption of atomic and molecular species when a solid is bombarded with energetic massive projectiles such as, for example, C60+ or Au4004+ . Their impact causes abundant emission of neutral and ionized atoms, molecules and molecular fragments. The desorbed ions are detected by time-of-flight mass spectrometry. The experimental procedure is that of secondary ion mass spectrometry with two innovations: the massive nature of the projectile and the mode of bombardment which is in a sequence of individual massive cluster impacts each isolated in time and space. Multiple ions can be ejected from a single impact. Given the size of the projectile (<= 3 nm in diameter), the co-ejected ions must originate from molecules colocated within nanometric dimensions.
The new capabilities for detecting, localizing and tracking small numbers of molecules (10-18 to 10-21 moles) are tested on surfaces, membranes, and nano-objects selected for their relevance in catalysis, microelectronics, environmental and biomedical research.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n233d0627
Patricio,Santander,Senior Lecturer,,Senior Lecturer,Chemistry,https://scholars.library.tamu.edu/vivo/display/n3c7257b3
Abigael,Songok,Lecturer,,Lecturer,Chemistry,https://scholars.library.tamu.edu/vivo/display/n727cf4ef
Joanna Maria,San Pedro,Senior Lecturer,,Senior Lecturer,Chemistry,https://scholars.library.tamu.edu/vivo/display/n8e0874ec
Daniel,Singleton,Professor,"The central focus of the Singleton research group is the study of organic, organometallic, and bioorganic reaction mechanisms, and the key tool that we use in these studies is the determination o kinetic isotope effects (KIEs). In the mid-1990's, we developed a method for the high precision combinatorial determination of small KIEs at natural abundance by NMR. Its direct applicability to complex unlabeled reactants makes this methodology 1-2 orders of magnitude faster than studies requiring labeling. At the same time, it is much more versatile - our technique can look at a great number of reactions that would have been impractical or impossible to study by labeling or mass spectral methods, and the choice of reactants can be readily changed in response to each new experimental result. The simultaneous determination of a complete set of 13C, 2H, and 17O isotope effects possible with our methodology provides a much greater level of information than available from conventional methods. In addition, substantial evidence has accumulated supporting the reliable accuracy of our results.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/na0239851
Amber,Schaefer,Lecturer,,Lecturer,Chemistry,https://scholars.library.tamu.edu/vivo/display/na83fb6e4
Matthew,Sheldon,Assistant Professor,"Our research considers fundamental questions of optical energy conversion relating to plasmonic and inorganic nanoscale materials. Our experiments are principally designed to identify and optimize unique nanoscale phenomena useful for solar energy conversion, as well as related opportunities at the intersection of nanophotonics and chemistry. We employ optical and electrical characterization techniques with high spatial and energy resolution to probe optical excitation and relaxation mechanisms in nanostructured metals and semiconductors.
The current world record solar cell operates at 44.4% power conversion efficiency. Thermodynamic analyses indicate that much higher efficiency is theoretically possible. Indeed, technical challenges, rather than laws of nature, limit current solar power convertors from achieving the maximum thermodynamic efficiency of 95%.
We seek to better understand how nanofabricated optoelectronic and plasmonic materials provide a route to achieve the maximum possible conversion efficiency with solid state and photoelectrochemical systems. We explore how nanostructuring materials enables systematic control of the thermodynamic parameters governing optical power conversion, enabling optimization that can shape, confine, and interconvert the energy and entropy of a radiation field. Additionally, the remarkable nanoscale tailorability of a variety of structural properties, such as electrochemical potential, can further enable novel photochemical systems with broad application beyond the scope solar energy conversion.
We seek students who are interested to gain expertise in inorganic synthesis of nanocrystals with tunable electrochemical and optical structures, nanofabrication, and comprehensive characterization and modeling of optoelectronic structures. Particular emphases are optical absorption and fluorescence spectroscopy, photovoltaic device physics, nanoscale electrical characterization, scanning probe techniques, and optical simula",Faculty Affiliate||Assistant Professor,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/nb887f9b0
Dong,Son,Professor,"The main focus area of the research in our laboratory is (i) chemical synthesis of nanoscale hetero-structures of semiconducting and magnetic materials and (ii) real-time laser spectroscopic investigation of the dynamic electronic and magnetic properties of the nanostructures prepared from (i). Ultimately, we would like to obtain fundamental understanding of how the dynamic optical, electronic and magnetic properties in structurally complex nanoscale materials can be controlled by tuning their chemical and structural parameters. The knowledge obtained from these researches lays fundamental background essential in many practical applications, such as designing nanoscale electronic devices and light energy-harvesting materials.",Faculty Affiliate||Professor,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/nbddedc3d
Jonathan,Sczepanski,Assistant Professor,"Our primary research goals are to develop and apply novel tools for studying DNA damage in the context of chromatin and to explore new avenues for RNA-based therapeutics and diagnostics. By combining expertise in chemical biology, molecular biology, and molecular evolution, our lab addresses challenges associated with studying and targeting noncoding RNAs from a unique perspective. In addition, we utilize modern chemical biology techniques to develop designer chromatin systems for studying DNA damage. We are seeking motivated individuals who wish to gain experience in chemical biology, molecular biology, and in vitro evolution techniques.",Assistant Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/ncc157d6e
Catherine,Serrano,Lecturer,,Lecturer,Chemistry,https://scholars.library.tamu.edu/vivo/display/nea72b519