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Welcome to the University of Delaware's Ultrafast Wiki
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About CSB
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| Center for Spintronics and Biodetection conducts research on the frontiers of the second-generation spintronics involving electron spin transport, pure spin currents, coherent spin dynamics, and spin-dependent noise phenomena in multilayered nanostructures consisting of ferromagnets, metals, insulators, and semiconductors. In addition, spintronic devices are also investigated as elements of sensors for biomolecules (nucleic acids and proteins). CSB research facilities are located at the University of Delaware and Brown University, while its funding comes from the Department of Energy and the State of Delaware.
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CSB Director
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CSB Advisory Board
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Upcoming Ultrafast Talks
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- Matthew DeCamp, Department of Physics and Astronomy "Ultrafast spectroscopy across the electromagnetic spectrum" Department of Physics and Astronomy Colloquium September 12, 2012 4pm Gore 104
- Noureddine Melikechi, Delaware State University “Detection and classification of disease biomarkers in complex media using laser induced breakdown spectroscopy: the case of epithelial ovarian cancer” Mechanical Engineering Seminar October 24, 2012 10 AM Brown Lab 219
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News
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- 4/4/2013 Congratulations to Yuan Gao on the successful defense of his thesis, "Probing and Reconstructing Transient One-Dimensional Acoustic Strains using Time-Resolved X-Ray Diffraction"!
- 5/10/2013 Congratulations to Matthew Doty and Matthew DeCamp on their successful promotion to Associate Professor
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Publications Highlight
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In this work we study theoretically the joint spectral properties of photon-pairs produced through spontaneous four-wave mixing (SFWM) with two spectrally distinct pump pulses in optical fibers. We show that, due to the group velocity difference between the pulses, the signature of the interaction can be significantly different from spontaneous parametric down-conversion or SFWM with a single pump pulse.
This work studied the generation of picosecond acoustic pulses generated by ultrafast optical excitation of a photo-acoustic transducer using time-resolved x-ray diffraction. The resulting pump-probe spectra reveal that the spatiotemporal structure of the acoustic pulse is bipolar with acoustic wavevectors up to inverse of the film thickness.
Spins confined in quantum dots are a leading candidate for solid-state quantum bits that can be coherently controlled by optical pulses. The use of hole spins allows the suppression of decoherence via hyperfine interactions and enables coherent spin rotations using Raman transitions mediated by a hole-spin-mixed optically excited state. Because the spin mixing is present only in the optically excited state, dephasing and decoherence are strongly suppressed in the ground states that define the qubits and nondestructive readout is possible. We present the qubit and device designs and analyze the wavelength tunability and fidelity of gate operations that can be implemented using this strategy. We then present experimental and theoretical progress toward implementing this design.
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The University of Delaware has developed a research core in the field of ultrafast science. The research interests range from studying electron dynamics in quantum systems to ultrastrong light-matter interactions. Currently this research core consists of five faculty members over three departments
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