Subcycle-resolved probe retardation in strong-field pumped dielectrics

The response of a bulk dielectric to an intense few-cycle laser pulse is not solely determined by the pulse envelope, but also by ultrafast processes occuring during each optical cycle. Here, a method is presented for measuring the retardation of a probe pulse in a strong-field pumped, bulk dielectr...

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Veröffentlicht in:	Nature communications 2015-07, Vol.6 (1), p.7746-7746, Article 7746
Hauptverfasser:	Pati, Aseem Prakash, Wahyutama, Imam Setiawan, Pfeiffer, Adrian Nikolaus
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creator	Pati, Aseem Prakash Wahyutama, Imam Setiawan Pfeiffer, Adrian Nikolaus
description	The response of a bulk dielectric to an intense few-cycle laser pulse is not solely determined by the pulse envelope, but also by ultrafast processes occuring during each optical cycle. Here, a method is presented for measuring the retardation of a probe pulse in a strong-field pumped, bulk dielectric with subcycle resolution in the pump–probe delay. Comparisons to model calculations show that the measurement is sensitive to the timing of the electronic Kerr response. When conduction band states are transiently populated at the crests of the laser field, the measurement is also sensitive to the interband dephasing time. At the ultrafast timescale the propagation of light pulses through a dielectric material is not only determined by the envelope, but also by nonlinear interactions that evolve within one optical cycle. Here, the authors demonstrate a method to determine the subcycle-resolved delay to a probe pulse in ultrafast, high-field pump–probe experiments.
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subjects	140/125 639/301/119/995 639/766/400 Humanities and Social Sciences multidisciplinary Science Science (multidisciplinary)
title	Subcycle-resolved probe retardation in strong-field pumped dielectrics
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