Collapse of layer dimerization in the photo-induced hidden state of 1T-TaS2

Stahl, Quirin; Kusch, Maximilian; Heinsch, Florian; Garbarino, Gastón; Kretzschmar, Norman; Hanff, K.; Roßnagel, Kai; Geck, J.; Ritschel, Tobias

doi:10.1038/s41467-020-15079-1

“…Also, the suppression of the CDW diffraction peaks is in agreement with the decrease of the AM peak intensity in the transient optical spectroscopy data reported here 27,32 . Finally, we note that the H state boundaries on long timescales are also consistent with the recent XRD measurements 37 . Comparing the appearance of the H state on short and long timescales we see that the H state immediately appears at low uences, but it takes much longer to stabilize at higher uences.…”

Section: Resultssupporting

confidence: 90%

“…TrED measurements 32 revealed a number of transient phases on the picosecond timescale dependent on photon density, with a semi-continuous rotation of the CDW ordering wavevector with respect to the crystal axes as a function of laser uence. The ordering wavevector angles observed in TrED are consistent with the angles obtained from the Fourier transformed STM images 19 and with recent static Xray measurements of the H state 37 . X-ray diffraction showed electronic domain fusion dynamics associated with the formation of the IC phase, described in terms of coherent domain formation on the picosecond timescale 35 followed by diffusive processes on a time-scale of ps 31 .…”

Section: Introductionsupporting

confidence: 88%

A time-domain phase diagram of metastable states in a charge ordered quantum material

Ravnik

¹

,

Diego

²

,

Gerasimenko

³

et al. 2020

Preprint

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Metastable self-organized electronic states in quantum materials are of fundamental importance, displaying emergent dynamical properties that may be used in new generations of sensors and memory devices. Such states are typically formed through phase transitions under non-equilibrium conditions and the final state is reached through processes that span a large range of timescales. By using time-resolved optical techniques and femtosecond-pulse-excited scanning tunneling microscopy (STM), the evolution of the metastable states in the quasi-two-dimensional dichalcogenide 1T-TaS2 is mapped out on a temporal phase diagram using the photon density and temperature as control parameters on timescales ranging from 10-12 to 103 s. The introduction of a time-domain axis in the phase diagram enables us to follow the evolution of metastable emergent states created by different phase transition mechanisms on different timescales, thus enabling comparison with theoretical predictions of the phase diagram and opening the way to understanding of the complex ordering processes in metastable materials.

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“…TrED measurements 35 revealed a number of transient phases on the picosecond timescale dependent on photon density, with a semicontinuous rotation of the CDW ordering wavevector with respect to the crystal axes as a function of laser fluence. The ordering wavevector angles observed in TrED are consistent with the angles obtained from the Fourier transformed STM images 16 and with recent static X-ray measurements of the H state 40 . X-ray diffraction showed electronic domain fusion dynamics associated with the formation of the IC phase, described in terms of coherent domain formation on the picosecond timescale 38 followed by diffusive processes on a time-scale of~100 ps 34 .…”

supporting

confidence: 88%

A time-domain phase diagram of metastable states in a charge ordered quantum material

Ravnik

¹

,

Diego

²

,

Gerasimenko

³

et al. 2021

View full text Add to dashboard Cite

Metastable self-organized electronic states in quantum materials are of fundamental importance, displaying emergent dynamical properties that may be used in new generations of sensors and memory devices. Such states are typically formed through phase transitions under non-equilibrium conditions and the final state is reached through processes that span a large range of timescales. Conventionally, phase diagrams of materials are thought of as static, without temporal evolution. However, many functional properties of materials arise as a result of complex temporal changes in the material occurring on different timescales. Hitherto, such properties were not considered within the context of a temporally-evolving phase diagram, even though, under non-equilibrium conditions, different phases typically evolve on different timescales. Here, by using time-resolved optical techniques and femtosecond-pulse-excited scanning tunneling microscopy (STM), we track the evolution of the metastable states in a material that has been of wide recent interest, the quasi-two-dimensional dichalcogenide 1T-TaS2. We map out its temporal phase diagram using the photon density and temperature as control parameters on timescales ranging from 10−12 to 103 s. The introduction of a time-domain axis in the phase diagram enables us to follow the evolution of metastable emergent states created by different phase transition mechanisms on different timescales, thus enabling comparison with theoretical predictions of the phase diagram, and opening the way to understanding of the complex ordering processes in metastable materials.

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“…that the bulk stacking structure likely alternates between T A and a vector drawn randomly from three versions of T C related by rotations of 120 ∘ , in a partially disordered patternsee Supplementary Note 1. The dimerisation of the stacking structure into bilayers, and the disorder, have also been discussed in the interpretation of recent experimental works 21,22 ). Put simply, if the electronic unit-cell contains two SDs, the total number of electrons per cell is even, leaving the highest occupied band filled and allowing an insulator without invoking Mott.…”

mentioning

confidence: 94%

Mottness versus unit-cell doubling as the driver of the insulating state in 1T-TaS2

Butler

¹

,

Yoshida

²

,

Hanaguri

³

et al. 2020

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If a material with an odd number of electrons per unit-cell is insulating, Mott localisation may be invoked as an explanation. This is widely accepted for the layered compound 1T-TaS 2 , which has a low-temperature insulating phase comprising charge order clusters with 13 unpaired orbitals each. But if the stacking of layers doubles the unit-cell to include an even number of orbitals, the nature of the insulating state is ambiguous. Here, scanning tunnelling microscopy reveals two distinct terminations of the charge order in 1T-TaS 2 , the sign of such a double-layer stacking pattern. However, spectroscopy at both terminations allows us to disentangle unit-cell doubling effects and determine that Mott localisation alone can drive gap formation. We also observe the collapse of Mottness at an extrinsically re-stacked termination, demonstrating that the microscopic mechanism of insulator-metal transitions lies in degrees of freedom of inter-layer stacking.

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Collapse of layer dimerization in the photo-induced hidden state of 1T-TaS2

Cited by 90 publications

References 37 publications

A time-domain phase diagram of metastable states in a charge ordered quantum material

A time-domain phase diagram of metastable states in a charge ordered quantum material

A time-domain phase diagram of metastable states in a charge ordered quantum material

Mottness versus unit-cell doubling as the driver of the insulating state in 1T-TaS2

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