Temporal lenses for attosecond and femtosecond electron pulses

Abstract: Here, we describe the ''temporal lens'' concept that can be used for the focus and magnification of ultrashort electron packets in the time domain. The temporal lenses are created by appropriately synthesizing optical pulses that interact with electrons through the ponderomotive force. With such an arrangement, a temporal lens equation with a form identical to that of conventional light optics is derived. The analog of ray diagrams, but for electrons, are constructed to help the visualization of the process of… Show more

“…The temporal widths of these electron pulses, however, range from femtosecond to picosecond, which is inadequate for studying electronic motion in atoms and molecules. Recently, methods have been proposed for producing single-electron, attosecond pulses [14][15][16]. The attosecond temporal and subangstrom spatial resolutions of such short keV electron pulses (at the target location) would make the four-dimensional (4D) study of electronic motion feasible.…”

“…The few-femtosecond laser pulse creates a superposition of electronic states which is then probed by a time-delayed, 10 keV single-electron attosecond pulse. The electron pulse may be generated by photoemission [15,17] and then compressed to an attosecond duration by a spatially dependent ponderomotive potential [15,16]. By adjusting the time delay between the pump and the probe pulses, the 4D motion of the oscillating charge distribution is manifested in the time-resolved diffraction images of the scattered electrons.…”

Detecting Electron Motion in Atoms and Molecules

“…The temporal widths of these electron pulses, however, range from femtosecond to picosecond, which is inadequate for studying electronic motion in atoms and molecules. Recently, methods have been proposed for producing single-electron, attosecond pulses [14][15][16]. The attosecond temporal and subangstrom spatial resolutions of such short keV electron pulses (at the target location) would make the four-dimensional (4D) study of electronic motion feasible.…”

“…The few-femtosecond laser pulse creates a superposition of electronic states which is then probed by a time-delayed, 10 keV single-electron attosecond pulse. The electron pulse may be generated by photoemission [15,17] and then compressed to an attosecond duration by a spatially dependent ponderomotive potential [15,16]. By adjusting the time delay between the pump and the probe pulses, the 4D motion of the oscillating charge distribution is manifested in the time-resolved diffraction images of the scattered electrons.…”

Detecting Electron Motion in Atoms and Molecules

“…85 A novel "all-optical" method for compression directly to the attosecond domain involves the creation of "temporal lenses" made by ultrashort laser pulses. 86,87 The technique relies on the ponderomotive FIG. 9.…”

Perspective: 4D ultrafast electron microscopy—Evolutions and revolutions

“…Doughnut modes correspond to a first order Laguerre-Gaussian laser mode with a profile depicted in Fig.9d. This result is important for application like doughnut mode creation for the temporally focusing of electron pulses (Hilbert et al,2009), (Helseth, 2004).…”

Laser Beam Shaping by Interference: Desirable Pattern