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In Memoriam
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John Margrave
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Richard E. Smalley
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Anthropology
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Christopher Kelty
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comparative
study of ethics and politics in science and technology including computer
science and nanotechnology
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Hannah Landecker
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anthropology
of biotechnology and biomedicine;
science and representation; the
relationship of social sciences to biological sciences
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Baker
Institute for Public Policy
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Amy Myers Jaffe
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oil geopolitics; strategic
energy policy including energy science policy; energy economics
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Biochemistry and
Cell Biology
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Kathleen Beckingham
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SWCNTs
in the intact organism; detection and biocompatibility studies in Drosophila
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Janet Braam
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regulation
and functions of genes encoding calmodulin-related proteins and cell wall
modifying enzymes of plants; control of gene expression in response to
environmental stimuli
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Richard Gomer
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toxicity
of nanomaterials; magnetic resonance imaging contrast agents; fibrosing
diseases; fibrocytes; pulmonary fibrosis
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Kevin MacKenzie
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structure,
stability and folding of integral membrane proteins; transmembrane helix
associations in signal transduction
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Kathleen Matthews
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protein-DNA
interactions involved in regulating gene expression; molecular and energetic
basis of DNA recognition, assembly, and allosteric changes of regulatory
proteins; protein-nanoparticle interactions
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James McNew
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molecular
mechanism of biological membrane fusion; membrane protein expression and
reconstitution; intracellular vesicular transport; functional reconstitution
of exocytosis in the yeast Saccharomyces cerevisiae
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John Olson
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fundamental
processes of oxygen transport and storage in mammalian circulatory systems
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Yizhi Jane Tao
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semiconductors
for next generation solar cells; structural analysis of chemical complexes
involved in virus replication and transcription
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Bill Wilson
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regulation
of cellular processes by sterols; trace analysis of sterols; biosynthesis and
metabolism of sterols; NMR of steroids and sphingolipids; Smith-Lemli-Opitz
syndrome; conformational analysis of sterols; synthetic transformations of
sterols
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Bioengineering
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Bahman Anvari
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cell
membrane electromechanics; site specific, diagnostic-guided optical therapy
using metallic nanoparticles; biological nano-electromechanical systems
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John W. Clark, Jr.
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electrophysiology
(neural, cardiac); mathematical modeling of biological systems; signal
processing methods applied to biological systems; nonlinear system dynamics;
electromagnetic field theory
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Michael R. Diehl
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physical
biology; intracellular trafficking and transport; macromolecular
self-assembly; biomotor mechanics; drug delivery; macromolecular systems
bioengineering; super-resolution microscopy
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Rebekah Anna Drezek
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optical
spectroscopy and imaging instrumentation for tissue diagnosis; metal
nanoshells for cancer detection and therapy, drug delivery, and tissue
welding; nanoshells for optical coherence tomography; surface enhanced Raman
scattering sensing with nanoshells; quantum dots for biomedical imaging
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Ariel Fernandez
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direct
nanoscale dehydration of hydrogen bonds; nanotubes as modulators of ion
gradients; continuum equations for dielectric response to macromolecular
assemblies at the nanoscale; bottom-up engineering of peptide cell
translocators based on environmentally modulated quadrupole switches
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Fathi H. Ghorbel
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nanoscale
dynamic systems and control, robotics, and biomedical engineering systems;
atomic force microscopy nanomanipulation: modeling and simulation;
vision-based force sensing and multi-rate haptic controller design for
nanorobotic manipulation
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K. Jane Grande-Allen
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integrative
biomechanics, biochemistry, pathology, and therapies of heart valve disease;
extracellular matrix; proteoglycans, organ cultured and tissue engineered
surrogates for studies of soft tissue biology and disease
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J. David Hellums
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applications
of fluid mechanical transport phenomena methods in medicine and biology
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Lydia Kavraki
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robotics
in microelectromechanical system; bioinformatics
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Michael A. K.
Liebschner
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computational
and experimental methods for biomechanical research; spine/bone biomechanics;
computational biomechanics; tissue engineering; tissue fracture mechanics;
minimally invasive fracture treatment; computer aided tissue engineering
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Jianpeng Ma
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molecular
dynamics simulation of supermolecular complexes
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Antonios Mikos
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bone
regeneration; biomaterials; drug delivery; gene therapy; tissue engineering.;
biodegradable polymers; scaffolds for cells; guided tissue growth; specific
substrates for targeted cell adhesion; stimulants for a desired cellular
response; controlled drug delivery; non-viral vectors for gene therapy
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Robert Raphael
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examination
of membrane mechanics; effect of salicylate and other Aspirin like molecules
on lipid membranes; liposomal mediated delivery methods
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Rebecca Richards-Kortum
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non-invasive
cancer detection technologies that use high-resolution, optical imaging;
biophysical studies of the light-scattering properties of cells and tissues;
use of fiber-optic sensors for in vivo detection of cancer
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Ka-Yiu San
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new
concepts and novel approaches of designing and manipulating metabolic routes
using recombinant DNA technology; development of a framework for the
systematic analysis of the cellular responses in regulating its metabolic
activities upon precise genetic perturbations
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Ann Saterbak
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undergraduate
bioengineering education; coordinating science and engineering education
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Junghae Suh
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engineered
bio-inspired nanodevices for the detection and treatment of human diseases
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Tomasz Tkaczyk
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development
of modern optical instruments for bioengineering; novel imaging instruments
and systems for the early detection and treatment of cancer incorporating
optics, opto-mechanics, electronics, software, bio-chemical materials
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Jennifer West
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biomaterials
and tissue engineering; synthesis, development and application of novel
biofunctional materials; biomaterials and engineering approaches to study
biological problems; nanoshells applied in cancer therapy, drug delivery, and
tissue welding; tissue engineered vascular grafts
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Brown
School of Engineering
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Sallie Keller-McNulty
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statistical
modeling
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Chemical and
Biomolecular Engineering
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Sibani Lisa Biswal
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self-assembling
systems in nano and microfluidic systems; colloidal fluids; understanding and
designing interactions among nanoparticles, biomolecules, and surfaces to
achieve new types of functionality; interfacing biological molecules with
inorganic substrates
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Walter Chapman
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molecular
simulation, computer visualization, statistical mechanics, and NMR to
discover how material properties and structure depend on molecular forces;
polymer solutions and blends, associating fluids, confined fluids, and
natural gas hydrates; assembly of nano-materials, bio-sensors, and membrane
separations; self-assembled gas hydrate nano-structures
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Ken Cox
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phase
equilibria for advanced separations design; sustainability analysis of energy
resources; molecular selection and informatics
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Ramon Gonzalez
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microbial
catalysis in an effort to understand how microbial cells function and how
they can be manipulated to produce valuable chemicals; metabolic engineering;
functional genomics and systems biology; microbial fermentations
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Joe W. Hightower
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chemical
and physical properties of heterogeneous catalysts in energy production,
chemicals manufacturing, and pollution control
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George Hirasaki
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interfaces
of fluid transport processes; surfactant/foam transport
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Nikos Mantzaris
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mathematical
modeling of biological systems
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Clarence Miller
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interfacial
phenomena, especially with surfactants; emulsions, microemulsions, and foams;
enhanced oil recovery; detergency; environmental remediation
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Matteo Pasquali
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interfacial
and biological flows; multiscale modeling of complex flows of fluids; carbon
nanotubes in liquids; visualization of single DNA molecules in process flows
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Marc Robert
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theoretical,
experimental and computer simulation studies of the properties of matter;
magnetic nanoclusters and carbon nanotubes; DNA and protein; ferroelectrics;
disordered systems; magnetic nanoclusters embedded in metallic or
semiconducting solids
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Howard Schmidt
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armchair
quantum wire; solar energy; nanotechnology in upstream oil and gas
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Laura Segatori
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biotechnology
and protein engineering; cell and tissue engineering; protein folding;
neurodegenerative diseases
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Michael Wong
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nanostructured
materials, heterogeneous catalysis, and bioengineering applications; chemical
approaches to assembling nanoparticles into functional macrostructures; solar
cells; nanoparticle assembly; heat transfer fluids in quantum dot synthesis;
catalytic processes of nanoparticles; surfactants in nanoparticle synthesis
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Kyriacos Zygourakis
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dynamic
behavior of cell populations growing under mass transport limitations;
gas-solid and liquid-solid reactions; design of catalytic reactors for air
pollution control
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Chemistry
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Lawrence Alemany
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solid
state NMR applied to the characterization of nanotubes, fullerenes, graphite,
and charcoals before and after chemical modification
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Zachary Ball
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transition-metal
catalysis; new methodology reaction design
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Andrew Barron
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seeded
growth of SWCNTs; development of rational molecular design approach to
materials synthesis emphasizing the leap from synthesis to application of
nano-based materials; functionalization
of fullerenes and SWCNTs; biological applications and interactions; catalysis
and materials applications; nanotube structures for energy applications
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Ed Billups
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nanoparticle
fuel additives; synthesis and properties of small ring alkenes and bicycloalkenes,
fullerenes, SWCNTs, and products formed at low temperature from the reactions
of transition metal atoms and small organic molecules; 3He NMR spectroscopy;
sidewall functionalization of SWCNTs by free radicals; reactions of carbon
nanotubes in oleum and sulfuric acid
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Paul Cherukuri (adjunct)
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* at MD Anderson* targeted, radiofrequency therapy of cancer
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Cecilia Clementi
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model
and characterize protein systems on a realistic time scale; dynamics of
polymer translocation through nanopores; statistical mechanics techniques,
molecular modeling and simulations to the study of protein systems, with a
particular interest in protein folding and dynamics
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Vicki Colvin
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confined
liquids and glasses; porous solids; size-exclusion chromatography;
nanopurification of water; uniform nanocrystals; virus crystals as
nanocomposite scaffolds; synthesis of monodisperse iron oxide nanocrystals by
thermal decomposition of iron carboxylate salts; recycling size-exclusion
chromatography for the analysis and separation of nanocrystalline gold
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Bob Curl
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infrared
laser spectroscopy and dinetics of free radicals; mid-infrared quantum
cascade laser based off-axis integrated cavity output spectroscopy for
biogenic nitric oxide detection; monitoring of ethylene by pulsed quantum
cascade laser; formaldehyde sensor using interband cascade laser based
quartz-enhanced photoacoustic spectroscopy
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Paul Engel
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chemistry
of free radical initiators and inhibitors of polymerization; single electron
transfer mechanism in the functionalization of SWCNTs; SWCNT in biocompatible
shell-crosslinked micelles
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Jeff Hartgerink
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supramolecular
chemistry; synthetic collagen mimics; amphiphilic peptides; tissue
engineering and regeneration; drug delivery; controlled mineralization of
inorganics; self-assembly of nanofibrous alpha-helical coiled-coils; surface
enhanced Raman and infrared spectra of peptide conjugated nanoshells; design
and synthesis of peptides that bind CNTs; self-assembly of peptide-amphiphile
nanofiber scaffolds for dental stem cells
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Robert Hauge
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high-pressure
carbon monoxide process (HiPco) process for making carbon nanotubes;
nucleation and growth of vertically-arrayed single walled nanotubes;
semiconductor properties of CNT; armchair quantum wire; nanofibers; SWCNT
coated polyacrylonitrile based carbon fiber
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John Hutchinson
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nanotechnology
education
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Bruce Johnson
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quantum
mechanical investigation of the molecular near-field response for molecules
adsorbed on silver nanoshells, to understand molecule-metal nanostructure
interactions, especially in the context of surface enhanced Raman scattering
(SERS); applications of wavelets to quantum dynamics; dissociative resonance
Raman spectroscopy; development of pulsed multiline excitation DNA
fluorescence technology
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Valery N. Khabashesku
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fluorination
and derivatization of fullerenes, polyfullerenes, CNTs and nanodiamonds for
bio-medical and materials engineering applications; synthesis and
characterization of carbo-nitride nano- and microscale materials; design and
manufacturing of integrated polymer composites, hydrogen storage materials,
nanolubricants, and surface coatings
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James L. Kinsey
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dynamics
of simple chemical reactions or molecular collisions; dynamics of
decomposition of photoexcited molecules; photoemission during
photodissociation
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Carter Kittrell
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spectroscopy
and metrology of pristine and functionalized SWCNTs suspended in liquid
ammonia, super acids, and surfactant/aqueous media; continued growth of
SWCNTs; neat SWCNT fibers; ultrathin "bed-of-nails" membranes of
SWCNTs; electronic structure control of SWCNT functionalization;
self-assembly of single crystals of SWCNTs
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Anatoly B. Kolomeisky
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complex
chemical and biophysical processes using statistical mechanics; polymer
translocation through nanopores
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Kristen Kulinowski
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nanotechnology
education and policy; environmental impact of engineered nanomaterials
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Stephan Link
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absorption
and scattering spectroscopy of single metallic nanoparticles and nanowires,
plasmon coupling in 1-D assemblies of nanostructures, diffusion of
nanoparticles probed by fluorescence correlation spectroscopy, anisotropic
solvation of rod-shaped nanostructures in liquid crystalline solvents, and
single molecule imaging of molecular machines
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Angel Marti
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photochemistry of fullerene; quantum dots in
biomedical applications; supramolecular chemistry; inclusion compounds in
fullerenes; proteins self-assembly
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Seiichi Matsuda
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recombinant
biosynthetic approaches to natural product biosynthesis; directed evolution
and DNA shuffling to generate new oxidosqualene cyclases; metabolic
engineering to produce terpenes
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Mary E. R. McHale
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nanotechnology
in undergraduate laboratory curriculum
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Ronald Parry
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biosynthesis
of secondary metabolites, otherwise known as natural products; biochemical
reactions associated with specific biosynthetic pathways; biosynthetic gene
clusters to produce new compounds with desirable biological activity
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Gustavo Scuseria
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theoretical
chemistry; ab initio computational quantum chemistry; density functional
theory; development of new methods for molecular electronic structure;
applications to nanostructures
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James Tour
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molecular
electronics; nanotubes for health applications; chemical self-assembly;
conjugated oligomers; electroactive polymers; combinatorial routes to precise
oligomers; polymeric sensors; flame retarding polymer additives; carbon
nanotube growth; synthetic modifications and composite formation; hydrogen
storage on carbon nanotubes; synthesis of molecular motors and nanocars; use
of the NanoKids concept for K-12 education in nanoscale science; methods for
retarding chemical terrorist attacks
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R. Bruce Weisman
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nanotube
electronic structure; near-infrared fluorescence spectroscopy; SWCNT
spectroscopy; biomedical imaging
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Ken Whitmire
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inorganic
and organometallic chemistry; clusters of the heavy main group elements and
transition metals; metal alkoxides, carboxylates and their conversion to
metal oxides
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Lon Wilson
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fullerene,
metallofullerene and carbon nanotube nanotechnology for medical applications;
metal ions in medicine and biology; coordination chemistry; radiochemistry of
the lanthanides and actinides
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Eugene Zubarev
|
functional
organic-inorganic nanostructures; mechanisms of molecular self-assembly;
taxol-functionalized gold nanoparticles; amphiphilic gold, platinum, and
palladium nanoparticles; optical properties and fluorescence of CdS quantum
wires and nanorods
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Civil and
Environmental Engineering
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Pedro Alvarez
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environmental
applications and implications of biotechnology and nanotechnology;
bioremediation of contaminated aquifers, phytoremediation, fate and transport
of hazardous substances; nanomaterial-bacterial interactions and related
disinfection approaches
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Joseph
Hughes
(adjunct)
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*Georgia
Tech* environmental biotechnology and in particular, determining how novel
metabolic capabilities of living organisms can be harnessed to improve
environmental quality; nanotechnology in environmental systems
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Qilin Li
|
advanced
technologies for drinking water purification and wastewater reuse including
membrane processes, advanced oxidation, and desalination; fate and transport
of environmental colloids and macromolecules; environmental application and
implication of nanotechnology
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Satish Nagarajaiah
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vibrations;
dynamic systems, smart structures and sensors; system identification; fault
and damage detection; structural health monitoring
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Jerome Claude Rose
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adsorbents,
the ability to tailor surfaces for reactivity; environmental implications of
nanotechnology
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Mason B. Tomson
|
fate
and transport of organic chemicals and heavy metals in sediments and ground
water; environmental impact of nano-particles; inhibition of mineral scale
formation
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Herb Ward
|
environmental
microbiology; microbiology of subsurface systems; factors affecting the
transport of microbes in the subsurface; in situ production of
biosurfactants; hydrogen peroxide as a source of oxygen for in situ
biorestoration of contaminated ground water
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Mark
Wiesner
(adjunct)
|
*Duke
University* water, resources and treatment; nanomaterial manufacturing and
characterization; environmental impacts of nanoscience
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Computational and Applied Mathematics
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Steve Cox
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biomathematics;
theoretical and computational neuroscience
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Computer Science
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Krishna
V. Palem
|
low
energy computing and nanoelectronics; analysis of energy of nanometer CMOS
circuits
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Scott Rixner
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embedded
computing; computer architecture; high-performance computing systems
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Earth
Science
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Andreas Luttge
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fluid/mineral
or fluid/rock interactions; dynamics and kinetics of nanoparticles in the
environment
|
|
Carrie A. Masiello
|
carbon
cycling; carbon sequestration; climate change; black carbon;
terrestrial-river-ocean biosphere interactions
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Economics
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Dagobert Brito
|
optimal
tax theory; economics of defense, energy and law; political economy of solar
energy and the implications of nanotechnology
|
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Suchan Chae
|
commercialization
prospect of nanotechnology
|
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Malcolm Gillis
|
public
finance, economic development, natural resources; challenges and
opportunities in nano, bio and information technology
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Peter R. Hartley
|
applied
microeconomics, with a particular focus on energy markets, risky behavior,
money, credit and banking
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Electrical and
Computer Engineering
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Richard Baraniuk
|
compressive
sensing, sensor networks and distributed signal processing; manifold-based
image processing; multiscale geometric analysis
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C. Sidney Burrus
|
signal
processing, digital signal processing (DSP) algorithms, filter design,
wavelets and wavelet-based DSP, and technology in education
|
|
Naomi Halas
|
optically
active nanostructures; nanofabrication strategies to build, orient, and
pattern nanostructures into materials and devices; characterize and
understand the physical properties of optically active nanostructures,
devices, and materials
|
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Kevin F. Kelly
|
plasmonic
near field optical microscopy tip for surface enhanced spectroscopy; surface
enhanced Raman spectroscopy and microscopy; atomic force microscopy; scanning
tunneling microscopy; scanning probe microscopy; single-pixel camera imaging;
nanomachines; polymer nanostructures; carbon nanotubes; novel imaging
instruments
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Junichiro Kono
|
optical
terahertz in semiconductor nanostructures and devices; high operating
temperature infrared detectors; high magnetic field phenomena in CNTs;
coherence in SWCNTs; vibrational dynamics of nanostructures;
magneto-photoluminescence spectroscopy; time-resolved far-infrared
spectroscopy; infrared photoluminescence spectroscopy; time-dependent
photoluminescence spectroscopy
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Farinaz Koushanfar
|
novel
statistical modeling and optimization of embedded systems in data integrity,
hardware security, digital rights management, and sensor-based embedded
computations and systems
|
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Yehia Massoud
|
modeling
and variability-aware design of mixed signal circuits, systems, and
interconnect based on both carbon nanotubes and nanophotonic structures;
numerical and analytical modeling techniques of emerging nanophotonic
structures such as metallic nanoshells and photonic crystals
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Daniel Mittleman
|
colloidal
photonic crystals; sources, detectors, spectroscopy, waveguides, imaging, and
sensing with terahertz radiation; near-field terahertz imaging and
spectroscopy; terahertz plasmonics and metamaterials
|
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Gennady Shvets
|
interactions
between electromagnetic waves and matter; high-gradient accelerators of
charged particles; novel ignition concepts in inertial confinement fusion;
novel nanostructures for nanoscale optical imaging and spectroscopy of
chemicals and biomolecules; design of non-reciprocal electromagnetics
structures in the microwave and optical regimes
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Frank Tittel
|
quantum
electronic devices; laser spectroscopy; nonlinear optics; laser-materials;
interactions with applications in medicine and microelectronics
|
|
William L. Wilson
|
semiconductor
materials growth and characterization; electro-optic devices; semiconductor
device characterization
|
|
James Young
|
optical/photonic
devices and their application to solving scientific and technical problems;
physical layer of optical fiber communications and optical sensing
|
|
Lin Zhong
|
mobile
and embedded system design; human-computer interaction; computer-aided design
for nanotechnology-based computing; power analysis & optimization of IC
& systems
|
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History
|
|
Cyrus Mody
|
history
of science, technology and engineering
|
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|
Jones Graduate
School of Management
|
|
Steve Currall
|
management
and psychology; interpersonal and interorganizational trust; conflict, power,
and group decision making processes within corporate boards of directors;
emerging technology companies; negotiation
|
|
Doug Schuler
|
business
and government relations – general, corporate political activity, trade
policy, and politics; socially responsible management
|
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|
|
Kennedy
Institute for Information Technology
|
|
Jan Odegrad
|
signal
and image processing; wavelet theory; filter banks and time-frequency
analysis with applications to geophysics; multimedia and telecommunication
|
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Mechanical
Engineering and Materials Science
|
|
Pulickel Ajayan
|
nanomaterials
in energy generation and storage; multifunctional composites; nano-enabled
bio-mimetic systems; nanoelectronics; nanosensors; active nanosystems
|
|
J. E. Akin
|
heat
transport behavior in nanoparticle composites; computational nanocomposites
|
|
Enrique Barrera
|
thermoset
nanocomposites with nanotubes; metal matrix nanocomposites; ceramic
nanocomposites; nanotube shielding materials for space applications;
materials for radiation protection; ceramic nanocomposites with nanotubes and
nanofibers
|
|
Yildiz Bayazitoglu
|
solution
to electromagnetic radiation equation; molecular dynamics studies for nano
heat transfer; micro-channel fluid and heat transfer; bio heat transfer; heat
transfer and fluid flow; manufacturing and processing of materials
|
|
Franz Brotzen
|
dynamical
mechanical study of single wall nanotube reinforced acrylonitrile butadiene
styrene (ABS) composite
|
|
Brent Houchens
|
fluid
mechanics, heat transfer and magnetohydrodynamics modeling; spectral methods
and linear stability analysis with regular and singular perturbation theory
(asymptotics) to bridge numerical and analytical models; surface tension
effects including thermocapillary driving, and electromagnetic effects
including magnetic stirring and damping
|
|
Peter Loos
|
thermal
conductivity and interfacial effects of thin dielectric films; kinetics of
diffusion
|
|
Jun Lou
|
materials
related issues and device developments for MEMS/NEMS applications; size
effects in mechanical integrity and electrical properties of metallic
nanostructures; interfacial behavior of NT/NW reinforced nanocomposites;
novel nano-fabrication methods with implications for bio-nano interactions
and sensing applications
|
|
Andrew Meade
|
experimental
and numerical aerodynamics; neurocomputing applied to experimental fluid
dynamics
|
|
Ronald Nordgren
|
mechanics
of solids; offshore engineering; petroleum production engineering
|
|
Marcia K. O’Malley
|
force
feedback for nanorobotic manipulation; haptic interfaces; telemanipulation;
human-robot interactions, vision-based force sensing and multi-rate haptic
controller design for nanorobotic manipulation
|
|
Pol Spanos
|
dynamics
and vibrations of structural and mechanical systems under a variety of loads;
fatigue and fracture issues of modern composite materials; signal processing
algorithims for dynamic effects in biomedical applications
|
|
Tayfun Tezduyar
|
computational
fluid mechanics; fluid-structure interactions; computer modeling in
cardiovascular fluid mechanics; computer modeling of parachutes, moving
boundaries and interfaces, finite element methods, stabilized formulations,
multiscale methods, air circulation and contaminant dispersion, and
fluid-particle interactions
|
|
Boris Yakobson
|
fullerene
nanocage for hydrogen storage; electron transport of nanotube-based gas
sensors; dislocation dynamics in multi-walled carbon nanotubes; real time
microscopy of fullerene evaporation
|
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Philosophy
|
|
Baruch Brody
|
medical
ethics; intellectual property and biotechnology
|
|
|
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Physics and
Astronomy
|
|
Carlos Jose Bolech Gret
|
complex
quantum impurity models and their connections with correlated lattice systems
and mesoscopic systems at the nanometer scale
|
|
Michael Deem
|
physical
theories of pathogen evolution; vaccine design; Newton's laws of biology;
structure, nucleation, and function of zeolites
|
|
Rui-Rui Du
|
quantum
mechanical properties of electrons in low dimensional and nanoscale
semiconductor structures and devices; ultracold electrons in low-D
semiconductors and nanostructures; wavefunction engineering of individual
donors for Si-based quantum computers; quantum transport measurement of the
Si-nanostructures produced by atom-scale scanning tunneling microscopy
patterning technique
|
|
Barry Dunning
|
using
Rydberg atoms as a nanoscale laboratory to examine electron-molecule
collisions at ultra-low electron energies; new generation of spin-sensitive
spectroscopies for investigating geometric, electronic and magnetic
properties of bulk surfaces and thin epitaxial films; surface chemistry to
thin film magnetism
|
|
Giovanni Fossati
|
active
galactic nuclei from a multifrequency point of view focusing on the high
energy properties
|
|
Jason Hafner
|
single
particle spectroscopy of gold nanoparticles; development of a new tip
technology for recognition AFM to enhance the ability to probe specific
biomolecular interactions; fluid electric force microscopy; biosensing;
biomembranes; optical properties in biomedical materials; shape-dependent
plasmon resonances of gold nanoparticles; biomedical applications of plasmon
resonant metal nanoparticles
|
|
Huey Huang
|
nanoscale
structures formed in membranes; micromanipulator studies of vesicles to
peptides; application of membranes and peptides in nanotechnologies
|
|
Randy Hulet
|
physics
of atoms at ultra-low temperatures; Bose-Einstein condensation and quantum
degenerate Fermi gases; realization of model condensed matter systems with
ultra-cold atoms; superfluidity/superconductivity
|
|
Ching-Hwa Kiang
|
single-molecule dynamic force spectroscopy.; statistical
Physics; protein folding; free energy reconstruction using Jarzynski's
equality; DNA mechanics; protein-nucleic acid interactions
|
|
Thomas C. Killian
|
ultracold
plasmas and fundamental questions about matter at extremely low temperatures;
manipulating biological systems with electric and magnetic fields
|
|
Neal Lane
|
policy
perspective on nanotechnology
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Emilia Morosan
|
discovery,
synthesis, and characterization of new materials with delicately balanced
ground states; itinerant magnets; heavy fermions (HF); charge density wave
(CDW) systems; superconductors (SC)
|
|
Douglas Natelson
|
nanoscale physics, in particular the electrical and magnetic
properties of systems with characteristic dimensions approaching the
single-nm scale; nanostructures for
single-molecule sensing; nanoscale magnetic sensing; nanophysics of solid
state systems; electrical properties of nanowires; transport and electronic
correlations in nanodevices; electrically-driven phase transition in
magnetite nanostructures; electronic conduction and coherence in
nanostructures with molecules; quantum effects in nanoscale electronics
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Peter Norlander
|
theoretical
investigation of the electronic structure, transport, and optical properties
of nanostructures using analytical methods such as Plasmon Hydridization
theory and numerical methods such as Finite Difference Time Domain (FDTD)
studies
|
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Han Pu
|
theoretical
ultracold atomic physics - interesting behavior that atoms and molecules
display when cooled at very, very, very low tempertures, a regime ruled by the
laws of Quantum Mechanics
|
|
Carl Rau
|
surface
science; nanomagnetism; nanomagnetic devices; non-volatile, nanomagnetic
random access memory (RAM) cells; nano-magnetic microscopy; nano-magnetic
logic devices; nano-magnetic classical and quantum computing
|
|
Alex
Rimberg
(adjunct)
|
*Dartmouth
College* electrical transport measurements of nanostructures: quantum
information science and quantum measurements; controlled physical
realizations of open quantum systems; quantum noise and non-equilibrium
effects
|
|
Qimiao Si
|
theoretical
condensed matter physics; strongly correlated electron systems, including
magnetic heavy fermion metals, high temperature superconductors, and
mesoscopic and disordered electronic systems
|
|
King Walters
|
experimental
atomic and molecular physics; physics of surfaces; manifestations of electron
spin; spin-sensitive surface probes
|
|
|
|
|
Smalley Institute of
Nanoscale Science and Technology
|
|
Wade
Adams
|
nanotechnology
for aerospace and energy applications; polymer physics; structure-property relations
in high-performance organic materials; rigid-rod polymer fibers; X-ray
scattering studies of fibers and liquid crystalline films; polymer dispersed
liquid crystals
|
|
Jack Agee
|
aerospace
applications of nanotechnology; international cooperative nanotechnology
research; bioelectrics as applied to cancer treatment; low temperature
physics; high power microwaves; pulsed power; electromagnetics; electronic
warfare; acoustics; radiation effects; nuclear physics
|
|
Alice Chow
|
thin
film processing and characterization; nanotechnology for aerospace
applications
|
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Statistics
|
|
Marina Vannucci
|
theory
and practice of Bayesian variable selection techniques; wavelet-based
statistical models and their application; bioinformatics; chemometrics;
engineering
|
|
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TX-UK Collaboration
|
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Denis Robert Headon
|
nano-
and bio-research collaboration with other universities
|