Direct measurements of multi-photon induced nonlinear lattice dynamics in semiconductors via time-resolved x-ray scattering

Williams, G. J.; Lee, Sooheyong; Walko, Donald A.; Watson, Michael A.; Jo, Wonhyuk; Lee, Dong Ryeol; Landahl, Eric C.

doi:10.1038/srep39506

Cited by 12 publications

(12 citation statements)

References 52 publications

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“…However, the stresses by hot phonons often prevail [13]. In GaAs a nonlinear contribution to the fluence dependence of the strain adds to the saturating one-photon absorption [14]. Various time-resolved magneto-optical experiments in metallic magnets demonstrate the possibility to trigger and control magnetization precession [15][16][17][18], using laser-induced strain pulses.…”

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confidence: 99%

Measurement of transient strain induced by two-photon excitation

Zeuschner

Pudell

Reppert

et al. 2020

Phys. Rev. Research

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By ultrafast x-ray diffraction we quantify the strain from coherent and incoherent phonons generated by one-and two-photon absorption. We investigated the ferrimagnetic insulator bismuth-doped yttrium iron garnet, which is a workhorse for laser-induced spin dynamics that may be excited indirectly via phonons. We identify the two-photon absorption by the quadratic intensity dependence of the transient strain and confirm a short lifetime of the intermediate state via the inverse proportional dependence on the pump-pulse duration. We determine the two-photon absorption coefficient using the linear relation between strain and absorbed energy density. For large intensities of about 1 TW/cm 2 considerable strain amplitudes of 0.1% are driven exclusively by two-photon absorption.

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Measurement of transient strain induced by two-photon excitation

Zeuschner

Pudell

Reppert

et al. 2020

Phys. Rev. Research

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“…In crystal Silicon S el is negative (contractile), whereas in crystal Gallium Arsenide S el is positive (tensile) [6] and therefore also results in expansion similar to thermal strain. In the past two decades, it has become recognized that the deformation potential often plays a dominant role in the lattice dynamics of semiconductor materials following ultrafast laser excitation [7][8][9][10][11]. In many of these studies, such as the one presented here, small transient changes in lattice spacing can be resolved by high-resolution synchrotron X-ray diffraction, and the logarithmic range of timescales probed can be exploited along with depth or material sensitivity to disentangle the transport of heat, sound, and charge in bulk or heterostructure crystals.…”

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confidence: 99%

Probing Electronic Strain Generation by Separated Electron-Hole Pairs Using Time-Resolved X-ray Scattering

Lee

DiChiara

et al. 2019

Applied Sciences

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Photogeneration of excess charge carriers in semiconductors produces electronic strain. Under transient conditions, electron-hole pairs may be separated across a potential barrier. Using time-resolved X-ray diffraction measurements across an intrinsic AlGaAs/n-doped GaAs interface, we find that the electronic strain is only produced by holes, and that electrons are not directly observable by strain measurements. The presence of photoinduced charge carriers in the n-doped GaAs is indirectly confirmed by delayed heat generation via recombination.

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“…1,2 The resulting change in interatomic spacing is proportional to the number of free carriers generated at low intensities below the onset of nonlinear absorption. 3 Excess energy from the light can be transferred to the lattice and increases the lattice spacing by creating a thermoelastic stress. In the field of optoelectronic applications, understanding the extent to which the structure or morphology of the material influences carrier and thermal transport is crucial for improving device performance.…”

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“…8 Similarly, the onset of twophoton absorption in n-doped GaAs manifests structurally as a one-millidegree rocking curve sideband. 3 For this purpose, improvements to the TRXS method have included increasing the sensitivity (e.g., grazing incidence to improve the x-ray/ laser overlap 9 ), improving the angular resolution (e.g., tripleaxis diffractometry 10 ), and extending the detector dynamic range (e.g., proportional mode detectors used with deep memory oscilloscopes 11 ). However, most practical optoelectronic devices, such as photodetectors, saturable absorbers, high-speed transistors, photovoltaics, and light emitting diodes, are made of polycrystalline semiconductors comprised of micro-to-nanoscale grains.…”

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Measuring femtometer lattice displacements driven by free carrier diffusion in a polycrystalline semiconductor using time-resolved x-ray scattering

Landahl

DiChiara

et al. 2018

Applied Physics Letters

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We show that time-resolved x-ray scattering can be applied to polycrystalline materials for the measurement of carrier diffusion. A polycrystalline indium antimonide sample is prepared by high-intensity ultrafast laser surface melting and re-solidification under vacuum to create randomly oriented grains with an average size of 13 nm. Two static diffraction rings are simultaneously observed on a gated pixel array detector. Their centroids move following lower-intensity laser excitation, and utilizing an in-situ angular calibration, the transient lattice spacing is determined with femtometer accuracy, thereby allowing the measurement of charge carrier dynamics. Compared to bulk calculations, we find that carrier diffusion slows by more than one order of magnitude. This result provides evidence for the formation of potential energy barriers at the grain boundaries and demonstrates the capability of time-resolved x-ray scattering to probe nanoscale charge transport in materials other than near-perfect crystals.

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Direct measurements of multi-photon induced nonlinear lattice dynamics in semiconductors via time-resolved x-ray scattering

Cited by 12 publications

References 52 publications

Measurement of transient strain induced by two-photon excitation

Measurement of transient strain induced by two-photon excitation

Probing Electronic Strain Generation by Separated Electron-Hole Pairs Using Time-Resolved X-ray Scattering

Measuring femtometer lattice displacements driven by free carrier diffusion in a polycrystalline semiconductor using time-resolved x-ray scattering

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