Response theory for time-resolved second-harmonic generation and two-photon photoemission

Timm, Carsten

doi:10.1088/0953-8984/16/4/015

Cited by 40 publications

(56 citation statements)

References 102 publications

(450 reference statements)

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“…Photoionization can be described classically for times where the coherence has decayed prior to the arrival of the probe pulse. 66 The contributions of the consecutive spatial positions in the escape process to the 2PPE signal were weighted by i factors, thereby modeling Lambert-Beer's law and also the escape depth of photoelectrons. Thus, the parameters ␥ i and i model the escape of electrons and the detection probability, respectively, in a phenomenological way.…”

Section: Resultsmentioning

confidence: 99%

Escape dynamics of photoexcited electrons at catechol:TiO2(110)

2006

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Ultrafast electron escape dynamics following excitation of the interfacial charge transfer complex of catechol prepared on the rutile TiO 2 ͑110͒ surface was investigated with femtosecond two-photon photoemission ͑2PPE͒. Laser pulses were generated with two noncollinear optical parametric amplifiers operated simultaneously at a repetition rate of 150 kHz delivering a cross-correlation function with 35 fs full width at half maximum. Catechol was absorbed from the solution. The experimental data were not depending on the choice between three different solvents. Photoinduced interfacial charge transfer was instantaneous and thus the rise of the signal was controlled by the cross-correlation function. The energy distribution of the hot electrons generated at the surface was measured as 2PPE spectrum. The decay of the 2PPE signal was nonexponential with a first time constant below 10 fs, a dip in the 50 fs to 100 fs range, and a tail lasting for picoseconds. It was attributed to the release of the electrons from the surface and their escape into the bulk of the semiconductor.

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Section: Resultsmentioning

confidence: 99%

Escape dynamics of photoexcited electrons at catechol:TiO2(110)

2006

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“…The thus obtained quasiparticle Green's functions are prerequisites for the calculations of PE, IPE, and 2PPE spectra and rates [9][10][11][12][13]. In the case of electron injection into an empty band, GK; n; t can be expressed as [14 -16]:…”

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confidence: 99%

Extreme Ultrafast Dynamics of Quasiparticles Excited in Surface Electronic Bands

et al. 2006

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We develop a many-body description of the nonadiabatic dynamics of quasiparticles in surface bands valid on an extremely ultrashort time scale by combining the formalism for the calculation of quasiparticle survival probabilities with the self-consistent treatment of the electronic response of the system. Applying this approach to the benchmark Cu(111) surface, we assess the behavior and intervals of preasymptotic electron and hole dynamics in surface bands and locate the transition to the asymptotic regime of the exponential quasiparticle decay characterized by the corrected Fermi golden rule-type of transition rate. The general validity of these findings enables distinguishing the various regimes of ultrafast electron dynamics that may be revealed in time resolved experiments. DOI: 10.1103/PhysRevLett.97.086801 PACS numbers: 73.20.ÿr, 71.10.ÿw, 78.47.+p, 79.60.ÿi The development of time resolved electron spectroscopies has enabled measurements of the surface electronic processes in the real time domain [1][2][3][4][5]. Such experiments provide direct insight into the temporal evolution of the studied systems from which information on the various relaxation processes that govern the dynamics of excited quasiparticles can be deduced. Experiments in which the time scales of relaxation are much shorter than the duration of measurement provide information on the asymptotic steady state dynamics of the excited system in its passage towards thermodynamic equilibrium. Descriptions of these processes are commonly given in terms of the rate constants that characterize asymptotic relaxation of quasiparticle states.Methods for probing the dynamics of electronic states in confined systems are usually based on electron excitation from or injection into the system, either in the one-step processes, as in direct photoemission (PE) or inverse photoemission (IPE) spectroscopy, or in the two-step laser pump-probe induced transitions, as in two-photon photoemission (2PPE) experiments. Common to all these experiments is a sudden promotion of electrons (holes) in the initially unoccupied (occupied) states after which their motion is subjected to final state (PE and IPE) or intermediate state interactions (2PPE) with the remainder of the system. These interactions give rise to relaxation and decoherence of the excited quasiparticles [6] and produce effects in the measured spectra from which the dynamics of the excited system is assessed. Energies and lifetimes of quasiparticles in surface bands have been experimentally determined dominantly in the regimes of separated time scales of relaxation and measurement and interpreted in the framework of asymptotic decay of excited states [5].However, if the act of measurement proceeds on the time scale comparable to or shorter than that of relaxation and decoherence processes, as in recent employments of laser pulse spectroscopies [7] or novel applications of x-ray techniques [8] with extreme temporal precision, the thus probed quasiparticle evolution may considerably differ from asympto...

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“…A non-Markovian evolution of the survival probability decaying faster than Eq. ͑38͒ will manifest itself through the modifications of relative intensities of direct and indirect transitions in 2PPE and of the peak shapes in PE, IPE, and 2PPE spectra from surface bands relative to the ones deduced from the asymptotic approaches 18,46,47 utilizing Eq. ͑38͒.…”

Section: Discussionmentioning

confidence: 99%

“…Note also that since we are interested in the response of the system to pulsed photon fields, the relevant quantities to study are the populations of final photoelectron states ͉f͘ above the vacuum level rather than the steady state photoelectron currents as is the case in standard formulation of photoemission in terms of current-current correlation functions. 41,42,47 The required population of a final state ͉f͘ is obtained from the absolute square of the sum of all 2PPE transition amplitudes of the kind shown in Fig. 6, and this is equivalent to the population formulated in the density matrix approach utilizing the Keldysh nonequilibrium Green's function method developed in Ref.…”

Section: Dynamics Of Quasiparticles Injected Into Surface Bandsmentioning

confidence: 99%

Ultrafast dynamics and decoherence of quasiparticles in surface bands: Preasymptotic decay and dephasing of quasiparticle states

et al. 2007

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We develop a many-body description of ultrafast electron dynamics in surface bands appropriate for studying relaxation of hot electrons and holes excited in the processes of one-and two-photon photoemission and inverse photoemission from surfaces. The description is based on the formalism for calculation of quasiparticle survival probabilities combined with self-consistent treatment of the electronic response of the system. We show that the calculation of survival amplitudes which carry information on the quasiparticle decay and decoherence can be conveniently mapped onto the problem of renormalization of quasiparticles by the interactions with bosonized excitations constituting the system heatbath. Applying this approach to the benchmark Cu͑111͒ surface we are able to assess the regimes of preasymptotic non-Markovian quasiparticle dynamics in surface bands and locate transitions to the regime of exponential decay governed by the modified Fermi golden rule-type of transition rates. The general validity of these findings enables us to establish borderlines between different regimes of ultrafast electronic relaxation and on that basis to introduce a simple interpolation scheme for modeling of quasiparticle decay in the course of spectroscopic measurements.

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Response theory for time-resolved second-harmonic generation and two-photon photoemission

Cited by 40 publications

References 102 publications

Escape dynamics of photoexcited electrons at catechol:TiO2(110)

Escape dynamics of photoexcited electrons at catechol:TiO2(110)

Extreme Ultrafast Dynamics of Quasiparticles Excited in Surface Electronic Bands

Ultrafast dynamics and decoherence of quasiparticles in surface bands: Preasymptotic decay and dephasing of quasiparticle states

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