Participants

I am doing research in EPR imaging of oxygen and other physiologic parameters in the area of cancer research and tissue engeneering

I work in the Stoll Lab at UW developing computational tools to quantify uncertainty in DEER spectroscopy. I am interested in finding robust methods to maximize the utility of spectroscopic data in the realm of structural biophysics.

The Eaton group develops new electron paramagnetic resonance (EPR) methods and instrumentation to address significant biochemical and chemical problems. A major current emphasis is on EPR methods to improve sensitivity and solve biomedical problems. The conventional approach to detection of signals from unpaired electrons detected only a small fraction of the intensity on each slow pass through the spectrum. By scanning much faster and changing the detection hardware we have achieved dramatic

The Eaton group develops new electron paramagnetic resonance (EPR) methods and instrumentation to address significant biochemical and chemical problems. A major current emphasis is on EPR methods to improve sensitivity and solve biomedical problems. The conventional approach to detection of signals from unpaired electrons detected only a small fraction of the intensity on each slow pass through the spectrum. By scanning much faster and changing the detection hardware we have achieved dramatic

My research interests focus on instrumentation development for high field EPR with specific applications in nitroxide spectroscopy. My theoretical work forcuses on generalizations of the Stochastic Liouville Equation for high field and the non-linear response regime.

EPR spectroscopy is essential for the understanding of reaction mechanism of metalloenzymes. It is important to promote this technique and open up my lab to anybody that needs access to this technique.

My research activities focus on the instrumental development of high field DNP. Field of 14T and above. Magic Angle Spinning and Overhauser DNP.

My research interests lie in the advanced EPR spectroscopic characterization of inorganic and bioinorganic systems and their role in fundamental chemical energy reactions.

My research interests include instrumentation and methods development for high-field EPR at 240 GHz, with a focus on application of Gd(III) based spin labels for structure studies of membrane proteins.

I began a postdoctoral fellowship in the ACERT laboratory in Jack Freed's group and I actually work on different projects:
1) I'm elucidating electron transfer mechanism by ESR spectroscopy different photochemical systems.
2) I'm studying by spin label ESR spectroscopy the interaction of Tau protein with microtubule (Alzheimer Disease).
I would like to have more knowledge in instrumentation development especially in time-resolved ESR spectroscopy and rapid-freeze quenching device.

I am interested in studying the dynamics of lipids and proteins in the cell membranes. Currently as a graduate student at ACERT and the Freed group, I have been developing two dimensional and high field epr experiments to study biomembranes.

XBand ODNP

My group is interested in using DNP for studying interactions between nanomaterials and biologically-relevant molecules.

I am in the Stoll group at the University of Washington, looking at spin label contributions to DEER.

We utilize a variety of home built CW spectrometers to perform ESR and EDMR on a wide variety of samples. I am most interested in new instrument development for biochemical and solid state studies.

Our research efforts have been directed at the use of spectroscopic methods, such as EPR spectroscopy, to determine the structures and structural transitions in membrane transport proteins and proteins involved in neuronal exocytosis. We have also made extensive use of EPR based methods to characterize the mechanisms of reversible protein-membrane interactions, and to examine the dynamics and conformational equilibria in membrane proteins.

I have been a leading developer of experimental EPR spectroscopy, particularly high-resolution, high-field applications based on quasioptical technology. I have also contributed significantly to the development and dissemination of software for quantitative analysis of EPR line shapes based on both diffusion equations and molecular dynamics calculations. I have broad experience applying these methods to study structure and dynamics in a wide range of systems, including protein and nucleic acids,

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To increase the sensitivity and distance range of DEER/PELDOR is the aim of my PhD project. In this respect, I am working with shaped pulses generated by an Arbitrary Waveform Generator (AWG) and DEER pulse sequences involving more than 4 pulses.

To increase opportunities for interdisciplinary applications of EPR.

My research is focused on spin-selection rules and other spin-dependent electronic transitions in condensed matter with low spin-orbit coupled electron states which can potentially be utilized for spin-to-charge conversion in spin-based technologies (spintronics, quantum computing). Materials of interest are organic and other carbon based semiconductors, silicon based materials such as mono-, poly, micro, and nano-crystalline as well as amorphous silicon and silicon nitride.

need to update

My background is in relaxation measurements (T1,T2) of organic radicals in aqueous phase (250 MHz - 34 GHz) and development of rapid scan EPR imaging at 250 MHz. As a post doc I gained experience constructing my own instrumentation for low-field solution DNP. I am now at a contract R&D firm and am championing low-field electromagnetics as an answer to many materials characterization problems. I have an interest in expansion and development of in-situ EPR.

I am Graduate Student working at National High Magnetic Field laboratory. My interest lies in investigating the transition metal ions with giant magnetic anisotropy using high field EPR. I am also developing a high pressure cell/cavity to study the effect of structure on these materials.

I work with Tau Protein and aquire distance measurements using DEER