Transcript PPTX
More than a decade ago: Accelerator development enabled visionary science probe-before-destroy Haidu et al. soft x-ray magnetic holography Wang, et al. PRL (2013) Today: We need the complementarity of x-rays & electrons to access to the “Ultrafast” & “Ultrasmall” Goal: understand & control materials processes FePt heat sink probes electrons & spins probes lattice G. Bertero (WD Corp.) soft x-ray magnetic holography Wang, et al. PRL (2013) nano-UED Xiang, et al. SLAC report (2014) X-rays or electrons? We need both! Electrons: can be manipulated by electric & magnetic fields (microscopy) but have <10nm coherence lengths. X-rays: Fully coherent beams offer new opportunities for holographic imaging. Soft x-ray resonant inelastic cross sections are comparable to those of electrons, elastic cross sections are much lower. R. Henderson, Quarterly Reviews of Biophysics 28 (1995) 171-193. The Future of Electron Scattering & Diffraction Opportunities for Ultrafast Science Key Breakthrough Science Opportunities and Challenges - Atomic Scale Molecular Processes - Photonic Control of Quantum Materials - Energy Transport at the Nanoscale - Mesoscale Materials and Phenomena - Evolving Interfaces, Nucleation, and Mass Transport DOE Basic Energy Sciences Needs Workshop Report (2014) The Future of Electron Scattering & Diffraction How do we get there? UEM User Facility Nano-UED User Facility Ultrafast Electron Diffraction Ultrafast Electron Microscopy DOE Basic Energy Sciences Needs Workshop Report (2014) Ben-Nun and Martinez, Chem. Phys. 259, 237(2000) Controlling processes on the level of electrons: Non-Born-Oppenheimer dynamics in molecules •requires sub-100 fs with unfocused electron beam at high repetition rates (UED) • Absorption triggers coupled ultrafast motion of nuclei and electrons, hard to model • Born-Oppenheimer violation provides fast funnels for steering energy into particular channel M. Centurion Lab U. Nebraska Aligned CF3I Guehr, et al. Opportunities for Ultrafast Materials Science • nanoscale energy transport •requires sub-100 fs with focused electron beam at high repetition rates (nano-UED) • photonic control of quantum materials • nanoscale mechanisms of phase transitions Imaging of Nanoscale Processes • Phase transitions: diffusionless vs. mass transport •requires single-shot imaging (10ps - 10 nm UEM) • Biological processes Carbon fixation by bacterial carboxysomes Early Science Opportunities with UED UEM User Facility Nano-UED User Facility Ultrafast Electron Diffraction Ultrafast Electron Microscopy Gas phase chemistry (sub-100fs & 100μm beam size): Experimental setup is still under development (requires isolation of gun and sample vacuum). Materials science will initially be limited by available samples: etching, exfoliation, sample growth of ~ 100μm free standing films needs to be developed) Development of laser-electron cross correlation schemes: - use laser-induced space charge - electron beam induced dynamics - photo-induced electron-lattice coupling in wide-bandgap oxides Early Science Opportunities with UED First results (A. Reid, R. Li, P. Musumeci) Gas phase chemistry (sub-100fs & 100μm beam size): Experimental setup is still under development (requires isolation of gun and sample vacuum). Materials science will initially be limited by available samples: etching, exfoliation, sample growth of ~ 100μm free standing films needs to be developed) Measurement of single-shot electron diffraction from a 40nm FeRh film epitaxially grown on 10 nm MgO IBAD deposited on 100nm SiN. Development of laser-electron cross correlation schemes: - use laser-induced space charge - electron beam induced dynamics - photo-induced electron-lattice coupling in wide-bandgap oxides