By Thomas Schultz, Marc Vrakking
This ebook presents basic wisdom within the fields of attosecond technological know-how and loose electron lasers, in keeping with the perception that the additional improvement of either disciplines can drastically reap the benefits of mutual publicity and interplay among the 2 groups. With recognize to the interplay of excessive depth lasers with topic, it covers ultrafast lasers, high-harmonic iteration, attosecond pulse iteration and characterization. different chapters assessment strong-field physics, unfastened electron lasers and experimental instrumentation. Written in a simple obtainable kind, the e-book is geared toward graduate and postgraduate scholars as a way to help the medical education of early degree researchers during this rising box. precise emphasis is put on the sensible strategy of establishing experiments, permitting younger researchers to boost quite a lot of clinical talents in an effort to speed up the advance of spectroscopic strategies and their implementation in medical experiments. The editors are managers of a study community dedicated to the schooling of younger scientists, and this publication concept relies on a summer season college prepared by means of the ATTOFEL community.
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Extra info for Attosecond and XUV Spectroscopy: Ultrafast Dynamics and Spectroscopy
Nature, 493, 75. F. et al. (2006) Control of electron localization in molecular dissociation. Science, 312, 246. 52 Zherebtsov, S. et al. (2011) Controlled near-ﬁeld enhanced electron acceleration from dielectric nanospheres with intense few-cycle laser ﬁelds. Nat. , 7, 656. , Hommelhoff, P. (2011) Attosecond control of electrons emitted from a nanoscale metal tip. Nature, 475, 78. 54 Schiffrin, A. et al. (2013) Optical-ﬁeldinduced current in dielectrics. Nature, 493, 70. 55 Uphues, T. et al. (2008) Ion-charge-state chronoscopy of cascaded atomic Auger decay.
As parametric ampliﬁcation is a nonresonant χ (2) effect, the upper state lifetime is practically zero. 12c). Ampliﬁcation occurs only within the duration of the pump pulse, imposing strict requirements on the temporal overlap between the pump and the signal pulses. The ampliﬁcation bandwidth is determined by the phase matching of the three interacting waves. 13 gives a typical example of phase-matched signal wavelength versus crystal angle in BBO. 4ı between incident pump and signal. 12b). Employing the second or third harmonic of the abovementioned directly pumped solid-state pump sources, noncollinear parametric ampliﬁcation is ideally suited for the generation of few-cycle pulses with high energies and high repetition rates.
F. (2004) The physics of attosecond light pulses. Rep. Progr. , 67, 813. 8 Klünder, K. et al. (2011) Probing singlephoton ionization on the attosecond time scale. Phys. Rev. , 106, 143002. 9 Krausz, F. and Ivanov, M. (2009) Attosecond physics. Rev. Mod. , 81, 163. A. et al. (2012) Attosecond lighthouses from plasma mirrors. Nat. Photonics, 6, 828. 11 Kienberger, R. et al. (2002) Steering attosecond electron wave packets with light. Science, 297, 1144. 12 Baltuska, A. et al. (2003) Attosecond control of electronic processes by intense light ﬁelds.
Attosecond and XUV Spectroscopy: Ultrafast Dynamics and Spectroscopy by Thomas Schultz, Marc Vrakking