Mapping atomic motions with ultrabright electrons: towards fundamental limits in space-time resolution.

The long held objective of directly observing atomic motions during the defining moments of chemistry has been achieved based on ultrabright electron sources that have given rise to a new field of atomically resolved structural dynamics. This class of experiments requires not only simultaneous sub-atomic spatial resolution with temporal resolution on the 100 femtosecond time scale but also has brightness requirements approaching single shot atomic resolution conditions. The brightness condition is in recognition that chemistry leads generally to irreversible changes in structure during the experimental conditions and that the nanoscale thin samples needed for electron structural probes pose upper limits to the available sample or "film" for atomic movies. Even in the case of reversible systems, the degree of excitation and thermal effects require the brightest sources possible for a given space-time resolution to observe the structural changes above background. Further progress in the field, particularly to the study of biological systems and solution reaction chemistry, requires increased brightness and spatial coherence, as well as an ability to tune the electron scattering cross-section to meet sample constraints. The electron bunch density or intensity depends directly on the magnitude of the extraction field for photoemitted electron sources and electron energy distribution in the transverse and longitudinal planes of electron propagation. This work examines the fundamental limits to optimizing these parameters based on relativistic electron sources using re-bunching cavity concepts that are now capable of achieving 10 femtosecond time scale resolution to capture the fastest nuclear motions. This analysis is given for both diffraction and real space imaging of structural dynamics in which there are several orders of magnitude higher space-time resolution with diffraction methods. The first experimental results from the Relativistic Electron Gun for Atomic Exploration (REGAE) are given that show the significantly reduced multiple electron scattering problem in this regime, which opens up micron scale systems, notably solution phase chemistry, to atomically resolved structural dynamics.

[1]  P. Musumeci,et al.  Single-shot MeV transmission electron microscopy with picosecond temporal resolution , 2014, 1405.5969.

[2]  Marco Garavelli,et al.  Aborted double bicycle-pedal isomerization with hydrogen bond breaking is the primary event of bacteriorhodopsin proton pumping , 2010, Proceedings of the National Academy of Sciences.

[3]  P. Musumeci,et al.  Laser-induced melting of a single crystal gold sample by time-resolved ultrafast relativistic electron diffraction , 2010 .

[4]  R. Miller,et al.  Single shot time stamping of ultrabright radio frequency compressed electron pulses , 2013 .

[5]  L. Wang,et al.  Accelerator-based single-shot ultrafast transmission electron microscope with picosecond temporal resolution and nanometer spatial resolution , 2014, 1405.6445.

[6]  Renkai Li,et al.  Capturing ultrafast structural evolutions with a single pulse of MeV electrons: Radio frequency streak camera based electron diffraction , 2010 .

[7]  R. Miller,et al.  Nanofluidic Cells with Controlled Pathlength and Liquid Flow for Rapid, High-Resolution In Situ Imaging with Electrons , 2013 .

[8]  S. Johnson,et al.  Nonthermal melting of a charge density wave in TiSe2. , 2011, Physical review letters.

[9]  Anton Barty,et al.  Molecular imaging using X-ray free-electron lasers. , 2018, Annual review of physical chemistry.

[10]  Jason R. Dwyer,et al.  Ultrafast electron optics: Propagation dynamics of femtosecond electron packets , 2002 .

[11]  R. J. Dwayne Miller,et al.  The Formation of Warm Dense Matter: Experimental Evidence for Electronic Bond Hardening in Gold , 2009, Science.

[12]  Jason R. Dwyer,et al.  An Atomic-Level View of Melting Using Femtosecond Electron Diffraction , 2003, Science.

[13]  V. Prokhorenko,et al.  Coherent control of the isomerization of retinal in bacteriorhodopsin in the high intensity regime. , 2011, The Journal of chemical physics.

[14]  R. R. Cooney,et al.  Mapping molecular motions leading to charge delocalization with ultrabright electrons , 2013, Nature.

[15]  J. A. Crowther Reports on Progress in Physics , 1941, Nature.

[16]  Jinfeng Yang,et al.  Transmission-electron diffraction by MeV electron pulses , 2011 .

[17]  Self-localizing stabilized mega-pixel picoliter arrays with size-exclusion sorting capabilities. , 2011, Analytical chemistry.

[18]  O. J. Luiten,et al.  High-coherence electron bunches produced by femtosecond photoionization , 2013, Nature Communications.

[19]  P. Hänggi,et al.  Reaction-rate theory: fifty years after Kramers , 1990 .

[20]  Y. Yeh,et al.  Enhancement of laser action in ZnO nanorods assisted by surface plasmon resonance of reduced graphene oxide nanoflakes. , 2012, Optics express.

[21]  D. Ratner,et al.  First lasing and operation of an ångstrom-wavelength free-electron laser , 2010 .

[22]  T. Elsaesser,et al.  Concerted electron and proton transfer in ionic crystals mapped by femtosecond x-ray powder diffraction. , 2010, The Journal of chemical physics.

[23]  Canada.,et al.  Electron source concept for single-shot sub-100 fs electron diffraction in the 100 keV range , 2007, physics/0702018.

[24]  J. Sipe,et al.  Theory of ultrafast electron diffraction: The role of the electron bunch properties , 2008 .

[25]  K. Perez Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment , 2014 .

[26]  J. Dwyer,et al.  Femtosecond electron diffraction: ‘making the molecular movie’ , 2006, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[27]  R. Miller,et al.  Mapping atomic motions with ultrabright electrons: the chemists' gedanken experiment enters the lab frame. , 2014, Annual review of physical chemistry.

[28]  Germán Sciaini,et al.  Femtosecond electron diffraction: heralding the era of atomically resolved dynamics , 2011 .

[29]  Qiang Du,et al.  Note: Single-shot continuously time-resolved MeV ultrafast electron diffraction. , 2010, The Review of scientific instruments.

[30]  B. Siwick,et al.  Ultrafast electron diffraction with radio-frequency compressed electron pulses , 2012 .

[31]  A. Bartnik,et al.  Thermal emittance and response time of a cesium antimonide photocathode , 2011 .

[32]  D. Dlott Ultrafast vibrational energy transfer in the real world: laser ablation, energetic solids, and hemeproteins , 1990 .

[33]  Relativistic effects in elastic scattering of electrons in TEM. , 2009, Ultramicroscopy.

[34]  R. Miller,et al.  Femtosecond Crystallography with Ultrabright Electrons and X-rays: Capturing Chemistry in Action , 2014, Science.

[35]  P. Musumeci,et al.  Electro-optic sampling at 90 degree interaction geometry for time-of-arrival stamping of ultrafast relativistic electron diffraction , 2010 .

[36]  T. Elsaesser,et al.  Field-driven dynamics of correlated electrons in LiH and NaBH4 revealed by femtosecond x-ray diffraction. , 2013, Physical review letters.

[37]  A. Zewail 4D ultrafast electron diffraction, crystallography, and microscopy. , 2006, Annual review of physical chemistry.

[38]  T. Elsaesser,et al.  X-rays inspire electron movies , 2012, Nature Photonics.

[39]  R. Miller,et al.  Vibrational energy relaxation and structural dynamics of heme proteins. , 1991, Annual review of physical chemistry.

[40]  Georg Weidenspointner,et al.  Time-resolved protein nanocrystallography using an X-ray free-electron laser , 2012, Optics express.

[41]  R. Coffee,et al.  Achieving few-femtosecond time-sorting at hard X-ray free-electron lasers , 2013, Nature Photonics.

[42]  Jerome B. Hastings,et al.  Ultrafast Time-Resolved Electron Diffraction with Megavolt Electron Beams , 2006 .

[43]  T. Elsaesser,et al.  Photoinduced structural dynamics of polar solids studied by femtosecond X-ray diffraction. , 2010, Acta crystallographica. Section A, Foundations of crystallography.

[44]  L. Veisz,et al.  Hybrid dc–ac electron gun for fs-electron pulse generation , 2007 .

[45]  Peter Hartel,et al.  First application of Cc-corrected imaging for high-resolution and energy-filtered TEM. , 2009, Journal of electron microscopy.

[46]  P. Musumeci,et al.  Effect of an ultrafast laser induced plasma on a relativistic electron beam to determine temporal overlap in pump-probe experiments. , 2013, Ultramicroscopy.

[47]  R. Egerton Measurement of inelastic/elastic scattering ratio for fast electrons and its use in the study of radiation damage , 1976 .

[48]  A. Zewail,et al.  Breaking resolution limits in ultrafast electron diffraction and microscopy , 2006, Proceedings of the National Academy of Sciences.

[49]  V. Paramonov,et al.  Beam dynamics in transverse deflecting rf structures , 2014 .

[50]  B. Siwick,et al.  Space-charge effects in ultrafast electron diffraction patterns from single crystals , 2012 .

[51]  A. Zarrine-Afsar,et al.  Crystallography on a chip. , 2012, Acta crystallographica. Section D, Biological crystallography.

[52]  Ahmed H. Zewail,et al.  Direct Observation of the Transition State , 1995 .