Aspectos Microbiológicos e Demanda de Cloro de Amostras de Água de Dessedentação de Frangos de Corte Coletadas em Bebedouros Pendulares

Attosecond spectroscopic techniques have made it possible to measure differences in transport times for photoelectrons from localized core levels and delocalized valence bands in solids. We report the application of attosecond pulse trains to directly and unambiguously measure the difference in lifetimes between photoelectrons born into free electron-like states and those excited into unoccupied excited states in the band structure of nickel (111). An enormous increase in lifetime of 212 ± 30 attoseconds occurs when the final state coincides with a short-lived excited state. Moreover, a strong dependence of this lifetime on emission angle is directly related to the final-state band dispersion as a function of electron transverse momentum. This finding underscores the importance of the material band structure in determining photoelectron lifetimes and corresponding electron escape depths.

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Critical behavior within 20 fs drives the out-of-equilibrium laser-induced magnetic phase transition in nickel

Tengdin

et al. 2018

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Band structure evolution during the ultrafast ferromagnetic-paramagnetic phase transition in cobalt

et al. 2017

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Self-amplified photo-induced gap quenching in a correlated electron material

et al. 2016

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Capturing the dynamic electronic band structure of a correlated material presents a powerful capability for uncovering the complex couplings between the electronic and structural degrees of freedom. When combined with ultrafast laser excitation, new phases of matter can result, since far-from-equilibrium excited states are instantaneously populated. Here, we elucidate a general relation between ultrafast non-equilibrium electron dynamics and the size of the characteristic energy gap in a correlated electron material. We show that carrier multiplication via impact ionization can be one of the most important processes in a gapped material, and that the speed of carrier multiplication critically depends on the size of the energy gap. In the case of the charge-density wave material 1T-TiSe2, our data indicate that carrier multiplication and gap dynamics mutually amplify each other, which explains—on a microscopic level—the extremely fast response of this material to ultrafast optical excitation.

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Time- and angle-resolved photoemission spectroscopy with optimized high-harmonic pulses using frequency-doubled Ti:Sapphire lasers

Eich

Stange

Carr

et al. 2014

Journal of Electron Spectroscopy and Related Phenomena

114

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Cong Chen

Direct time-domain observation of attosecond final-state lifetimes in photoemission from solids

Critical behavior within 20 fs drives the out-of-equilibrium laser-induced magnetic phase transition in nickel

Band structure evolution during the ultrafast ferromagnetic-paramagnetic phase transition in cobalt

Self-amplified photo-induced gap quenching in a correlated electron material

Time- and angle-resolved photoemission spectroscopy with optimized high-harmonic pulses using frequency-doubled Ti:Sapphire lasers

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