Ultrafast electron diffraction from a Bi(111) surface: Impulsive lattice excitation and Debye–Waller analysis at large momentum transfer

Tinnemann, V; Streubühr, C.; Hafke, B.; Kalus, Annika; Hanisch-Blicharski, Anja; Ligges, Manuel; Zhou, Ping; Linde, D. von der; Bovensiepen, Uwe; Hoegen, M. Horn‐von

doi:10.1063/1.5093637

Cited by 12 publications

(12 citation statements)

References 49 publications

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“…The relation between ln(I/I 0 ) and Q 2 for a00 at 2.5 mJ/cm 2 pump fluence is shown in Figure 5 d. ln(I/I 0 ) is linear with Q 2 which is consistent with what is expected from the Debye–Waller effect. 36 …”

Section: Resultsmentioning

confidence: 99%

Manipulation of Stacking Order in Td-WTe₂ by Ultrafast Optical Excitation

Grånäs

Weissenrieder

2021

ACS Nano

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Subtle changes in stacking order of layered transition metal dichalcogenides may have profound influence on the electronic and optical properties. The intriguing electronic properties of Td -WTe 2 can be traced to the break of inversion symmetry resulting from the ground-state stacking sequence. Strategies for perturbation of the stacking order are actively pursued for intentional tuning of material properties, where optical excitation is of specific interest since it holds the potential for integration of ultrafast switches in future device designs. Here we investigate the structural response in Td -WTe 2 following ultrafast photoexcitation by time-resolved electron diffraction. A 0.23 THz shear phonon, involving layer displacement along the b axis, was excited by a 515 nm laser pulse. Pump fluences in excess of a threshold of ∼1 mJ/cm 2 result in formation, with an ∼5 ps time constant, of a new stacking order by layer displacement along the b axis in the direction toward the centrosymmetric 1 T * phase. The shear displacement of the layers increases with pump fluence until saturation at ∼8 pm. We demonstrate that the excitation of the shear phonon and the stabilization of the metastable phase are decoupled when using an optical pump as evidenced by observation of a transition also in samples with a pinned shear phonon. The results are compared to dynamic first-principles simulations and the transition is interpreted in terms of a mechanism where transient local disorder is prominent before settling at the atomic positions of the metastable phase. This interpretation is corroborated by results from diffuse scattering. The correlation between excitation of intralayer vibrations and interlayer interaction demonstrates the importance of including both short- and long-range interactions in an accurate description of how optical fields can be employed to manipulate the stacking order in 2-dimensional transition metal dichalcogenides.

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Section: Resultsmentioning

confidence: 99%

Manipulation of Stacking Order in Td-WTe₂ by Ultrafast Optical Excitation

Grånäs

Weissenrieder

2021

ACS Nano

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“…Variants of FED have recently been used to study lattice dynamics in several other systems, including metals [38,39], semiconductors [34,40], heterostructures [41,42], and systems involving structural phase transitions [43,44]. We present an approach to characterize the transient lattice state, by converting Bragg reflection intensities into units of Kelvin, producing a series of temperatures associated with each scattering vector of the probe electrons (Q).…”

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confidence: 99%

Exchange-Striction Driven Ultrafast Nonthermal Lattice Dynamics in NiO

et al. 2021

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We use femtosecond electron diffraction to study ultrafast lattice dynamics in the highly correlated antiferromagnetic (AF) semiconductor NiO. Using the scattering vector (Q) dependence of Bragg diffraction, we introduce a Q-resolved effective lattice temperature, and identify a nonthermal lattice state with preferential displacement of O compared to Ni ions, which occurs within ~0.3 ps and persists for 25 ps. We associate this with transient changes to the AF exchange striction-induced lattice distortion, supported by the observation of a transient Q-asymmetry of Friedel pairs. Our observation highlights the role of spin-lattice coupling in routes towards ultrafast control of spin order.

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“…All of this could be explained by the inherent nonlinearity of the exponential function: for large momentum transfers, the spot intensity decreased more than 90%, which then is associated with an apparently faster excitation. The consideration of this effect—for all spots—resulted in a consistent time constant of 12 ps for the vibrational excitation of the surface atoms 36 . Thus, the excitation of the surface phonons is slow compared to the excitation of the bulk phonon system, which occurs within 4 ps or less 11,19 .…”

Section: Resultsmentioning

confidence: 94%

Decelerated lattice excitation and absence of bulk phonon modes at surfaces: Ultra-fast electron diffraction from Bi(111) surface upon fs-laser excitation

Tinnemann

Streubühr

Hafke

et al. 2019

Structural Dynamics

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Ultrafast reflection high-energy electron diffraction is employed to follow the lattice excitation of a Bi(111) surface upon irradiation with a femtosecond laser pulse. The thermal motion of the atoms is analyzed through the Debye–Waller effect. While the Bi bulk is heated on time scales of 2 to 4 ps, we observe that the excitation of vibrational motion of the surface atoms occurs much slower with a time constant of 12 ps. This transient nonequilibrium situation is attributed to the weak coupling between bulk and surface phonon modes which hampers the energy flow between the two subsystems. From the absence of a fast component in the transient diffraction intensity, it is in addition concluded that truncated bulk phonon modes are absent at the surface.

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Ultrafast electron diffraction from a Bi(111) surface: Impulsive lattice excitation and Debye–Waller analysis at large momentum transfer

Cited by 12 publications

References 49 publications

Manipulation of Stacking Order in Td-WTe₂ by Ultrafast Optical Excitation

Manipulation of Stacking Order in Td-WTe₂ by Ultrafast Optical Excitation

Exchange-Striction Driven Ultrafast Nonthermal Lattice Dynamics in NiO

Decelerated lattice excitation and absence of bulk phonon modes at surfaces: Ultra-fast electron diffraction from Bi(111) surface upon fs-laser excitation

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Ultrafast electron diffraction from a Bi(111) surface: Impulsive lattice excitation and Debye–Waller analysis at large momentum transfer

Cited by 12 publications

References 49 publications

Manipulation of Stacking Order in Td-WTe2 by Ultrafast Optical Excitation

Manipulation of Stacking Order in Td-WTe2 by Ultrafast Optical Excitation

Exchange-Striction Driven Ultrafast Nonthermal Lattice Dynamics in NiO

Decelerated lattice excitation and absence of bulk phonon modes at surfaces: Ultra-fast electron diffraction from Bi(111) surface upon fs-laser excitation

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Manipulation of Stacking Order in Td-WTe₂ by Ultrafast Optical Excitation

Manipulation of Stacking Order in Td-WTe₂ by Ultrafast Optical Excitation