Controlling dielectrics with the electric field of light

Schultze, Martin; Bothschafter, Elisabeth M.; Sommer, Annkatrin Madlen; Holzner, Simon; Schweinberger, Wolfgang; Fieß, Markus; Hofstetter, Michael; Kienberger, Reinhard; Apalkov, Vadym; Yakovlev, Vladislav S.; Stockman, Mark I.; Krausz, Ferenc

doi:10.1038/nature11720

Cited by 535 publications

(439 citation statements)

References 21 publications

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“…Thus, we find a Maxwell field defined by Eq. (86). At this level of approximation, our starting point coincides with that adopted in [40].…”

Section: Appendix A: Conventionsmentioning

confidence: 99%

“…When restricting the photons to a cavity, the Kohn-Sham current is then responsible to couple the different photon modes. The coupling terms in the Kohn-Sham current are specifically relevant in the context of, e.g., nanoplasmonics, where the electromagnetic fields are enhanced due to the presence of the plasmons, or in the optical control of currents in solids [86].…”

Section: Appendix A: Conventionsmentioning

confidence: 99%

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Quantum-electrodynamical density-functional theory: Bridging quantum optics and electronic-structure theory

et al. 2014

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In this work, we give a comprehensive derivation of an exact and numerically feasible method to perform ab initio calculations of quantum particles interacting with a quantized electromagnetic field. We present a hierarchy of density-functional-type theories that describe the interaction of charged particles with photons and introduce the appropriate Kohn-Sham schemes. We show how the evolution of a system described by quantum electrodynamics in Coulomb gauge is uniquely determined by its initial state and two reduced quantities. These two fundamental observables, the polarization of the Dirac field and the vector potential of the photon field, can be calculated by solving two coupled, nonlinear evolution equations without the need to explicitly determine the (numerically infeasible) many-body wave function of the coupled quantum system. To find reliable approximations to the implicit functionals, we present the appropriate Kohn-Sham construction. In the nonrelativistic limit, this density-functional-type theory of quantum electrodynamics reduces to the densityfunctional reformulation of the Pauli-Fierz Hamiltonian, which is based on the current density of the electrons and the vector potential of the photon field. By making further approximations, e.g., restricting the allowed modes of the photon field, we derive further density-functional-type theories of coupled matter-photon systems for the corresponding approximate Hamiltonians. In the limit of only two sites and one mode we deduce the appropriate effective theory for the two-site Hubbard model coupled to one photonic mode. This model system is used to illustrate the basic ideas of a density-functional reformulation in great detail and we present the exact Kohn-Sham potentials for our coupled matter-photon model system.

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“…Thus, we find a Maxwell field defined by Eq. (86). At this level of approximation, our starting point coincides with that adopted in [40].…”

Section: Appendix A: Conventionsmentioning

confidence: 99%

Section: Appendix A: Conventionsmentioning

confidence: 99%

Quantum-electrodynamical density-functional theory: Bridging quantum optics and electronic-structure theory

et al. 2014

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“…Bragg-like scattering of electrons was found to contribute to the generation of nonperturbative high-order harmonics in solid samples [7,8]. The reversible field-induced change of absorption in the extreme ultraviolet spectral range was observed by probing the effect of an intense near-infrared field on a thin silica plate using an attosecond pulse of extreme ultra-violet radiation as a probe [9]. A subcycle turn-on of electric current in a dielectric and its manipulation with CEP-stabilized pulses was demonstrated by measuring the residual polarization induced by the laser light [10].…”

Section: A Numerical Examplementioning

confidence: 99%

“…However, new experiments put these phenomena in a new context, which often leads to nontrivial observations, such as the generation of nonperturbative high-order harmonics in a solid due to Bragg-like scattering at the edges of the Brillouin zone [7,8], a nearly instantaneous change in extreme-ultraviolet absorptivity and nearinfrared reflectivity of a dielectric in the presence of a laser field as strong as several volts perångström [9], or the induction of electric current in an unbiased dielectric by similarly intense laser pulses [10]. Several decades of research on strong-field phenomena in solids and mesoscopic structures provide a solid ground for developing new theoretical models adapted for new experimental conditions.…”

Section: Introductionmentioning

confidence: 99%

Ultrafast Control of Strong-Field Electron Dynamics in Solids

Yakovlev

Kruchinin

Paasch-Colberg

et al. 2015

Ultrafast Dynamics Driven by Intense Light Pulses

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We review theoretical foundations and some recent progress related to the quest of controlling the motion of charge carriers with intense laser pulses and optical waveforms. The tools and techniques of attosecond science enable detailed investigations of a relatively unexplored regime of nondestructive strong-field effects. Such extremely nonlinear effects may be utilized to steer electron motion with precisely controlled optical fields and switch electric currents at a rate that is far beyond the capabilities of conventional electronics. IntroductionIt has long been realized that intense few-cycle laser pulses provide unique conditions for exploring extremely nonlinear phenomena in solids [1,2], the key idea being that a sample can withstand a stronger electric field if the duration of the interaction is shortened. Ultimately, a single-cycle laser pulse provides the best conditions for studying nonperturbative strong-field effects, especially those where the properties of a sample change within a fraction of a laser cycle. The recent rapid development of the tools and techniques of attosecond science [3] not only creates new opportunities for detailed investigations of ultrafast electron dynamics in solids, but it also opens exciting opportunities for controlling electron motion in solids with unprecedented speed and accuracy. Conventional nonlinear phenomena that accompany the interaction of intense laser pulses with solids have already found a vast number of applications in spectroscopy, imaging, laser technology, transmitting and processing information [4]. It can be expected that the less conventional nonpertur-

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“…Attosecond science holds the promise to unravel the fastest electronic processes in solid-state materials [4,5]. Attosecond transient absorption of nanometer-thick films in particular combines the highest temporal resolution with a good energy resolution.…”

Section: Introductionmentioning

confidence: 99%