FY 2017 LDRD Projects
FY20 Important Dates
- New project kickoff session
October 23, 2019
- Open House
Late February, 2020
- FY21 call for proposals
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New LDRD Projects for FY17
Development Of Combined XAFS/FTIR In Situ Cell For Insight Into Catalyst Function
Lead Scientist: Simon Bare
The proposed research will initiate the development of new catalysis research infrastructure at SSRL consistent with both the SLAC and SSRL Strategic Plans. Specifically, we will design and implement a combined transmission Fourier transform infra-red (FTIR) and X-ray absorption fine structure spectroscopy (XAFS) in situ catalysis cell that is compatible with both the advanced spectroscopy beamline, 6-2/15-2, and the more traditional spectroscopy beamlines at SSRL.
Stimulated X-Ray Emission Spectroscopy – A Powerful New Tool To Study Metal Centers At Xfels
Lead Scientist: Uwe Bergmann
Transition metal complexes are at the center of a wide variety of catalytic reactions involved in biological systems and many important industrial processes. X-ray spectroscopy is a unique and powerful tool to study such catalytic centers and their reaction intermediates, because of its elemental selectivity and sensitivity to changes in the electronic and atomic structure of the metal complexes.
Charged Particle Beam Manipulation Using Cep-Stable Coherently Combined Discretely Polarized Laser Pulses
Lead Scientist: Sergio Carbajo
We propose an ultrafast laser source with programmable optical fields capable of driving novel photon-particle interactions. The baseline technology is coherent combination of carrier-envelope phase (CEP)-stable ultrafast fiber technology with individual polarization, phase, delay, and intensity control. The ability to govern the entire 4‑dimensional space of synthesized laser pulses opens a wide range of on-demand laser beam properties using a single source, such as programmable polarization and orbital momentum distribution, transverse mode profile, and pulse-front tilt, among many others.
Emergent Spintronics In Complex Oxide Heterostructures
Lead Scientist: Harold Hwang
Over the past decade, harnessing both spin and charge for spintronics has led to several breakthrough observations, including giant spin currents via spin pumping, the spin Hall effect, quantum spin/anomalous Hall effect, and long spin lifetimes in superconductors. These results are exciting both due to their fundamental new insights into transport processes in solids, and their potential for application in low-dissipation electronics. The majority of these spin-dependent phenomena rely on interactions at interfaces between diverse materials, where couplings often occur on the atomic scale. However, much of this work has used relatively simple materials components, with little command over their assembly.
Lead-Free Double Perovskites As Solar-Cell Absorbers
Lead Scientist: Hemamala Karunadasa
Despite the remarkable rise in efficiencies of solar cells containing the lead-halide perovskite absorber (CH3NH3)PbI3, the toxicity of lead remains a primary concern for the large-scale implementation of this technology, particularly in light of the material’s water solubility. A nontoxic and stable material with similar photophysical properties to the lead-halide perovskites will constitute a major breakthrough in the solar-cell industry.
Lead Scientist: Chris Kenney
Most of the science performed at SLAC, throughout the DOE complex, and beyond is enabled by sophisticated electronic systems. Almost all of these electrical systems require interconnections among components and with the outside world for information and energy exchange. This proposal would develop the next generation of interconnects and assembly technology at SLAC by making use of the edges of semiconductor chips to extend systems into the third dimension.
All Active Projects for FY17
|Akerib, Daniel & Shutt, Tom||LUX/LZ Dark Matter Search|
|Bare, Simon||Development Of Combined Xafs/Ftir In Situ Cell For Insight Into Catalyst Function|
|Bargar, John||Molecular Basis of Ecosystems N Cycling: A strategic SLAC Biosciences Program|
|Bargar, John & Brown, Gordon||Real Time Control of Subsurface Fractures and Fluid Flow|
|Bergmann, Uwe||Stimulated X-Ray Emmission Spectroscopy-A Powerful New Tool To Study Metal Centers at Xfels|
|Carbajo, Sergio||Charged Particle Beam Manipulation Using Cep-Stable Coherently Combined Discretely Polarized Laser Pulses|
|Chueh, William||Electrochemical Heat Harvesting & Cooling|
|Fiuza, Frederico||Modeling Acceleration in Laser-Driven Shocks|
|Goldhaber-Gordon, David||Structural Characterization of Electrolyte and Polymer Gated Electronics to Better Control Device Properties|
|Hwang, Harold||Emergent Spintronics In Complex Oxide Heterostructures|
|Irwin, Kent||A Radio For Hidden Photon Dark Matter|
|Jaramillo, Tom||CO2 to MEOH Conversion|
|Karunadasa, Hemamala||Lead-Free Double Perovskites As Solar-Cell Absorbers|
|Kenney, Chris||Multidimensional Interconnects|
|Lee, Wei-Sheng||Exploring the Scientific Capability of Momemtum-Resolved Resonant Inelastic Soft X-ray Scattering for Material Science Research|
|Lee, Young||Scattering Studies and Crystal Growth of Quantum Materials|
|Nanni, Emilio||Megawatt THz Optical Parametric Amplifier|
|Nordlund, Dennis||New Initiative for Pioneering Research in Biology, Chemistry, and Material Science with State-of-the-Art Soft X-ray Spectroscopy|
|Norskov, Jens||Beyond the Current Limitations of Water Spitting Catalysts|
|Spormann, Alfred||Integrated Electrochemical-Biological System for the Production of Fuels and Chemicals from CO2|
|Tassone, Christopher||Accelerating Nanocrystal Synthetic Development|
|Vuckovic, Jelena||Quantum Optics and Biological Probes with Silicon Vacancies in CVD Grown Diamond|