Quantitative hyperspectral coherent diffractive imaging spectroscopy of a solid-state phase transition in vanadium dioxide

Johnson, Allan S.; Conesa, Jordi Valls; Vidas, Luciana; Perez-Salinas, Daniel; Günther, C.; Pfau, Bastian; Hallman, Kent A.; Haglund, Richard F.; Eisebitt, Stefan; Wall, Simon

doi:10.1126/sciadv.abf1386

Cited by 13 publications

(21 citation statements)

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“…To address the role of nanoscale heterogeneity and phase separation, we use time-and spectrally resolved resonant soft X-ray coherent imaging at the Pohang Accelerator Laboratory X-ray Free Electron Laser (PAL-XFEL) [28][29][30][31] to image the light-induced phase transition on the ultrafast timescale with nanometre spatial resolution. The power of this technique lies in the fact that it is a wide-field imaging technique that can exploit resonant X-ray spectroscopy both to provide a contrast mechanism between phases 32 and to enable the extraction of quantitative spectral information to aid phase identification on the nanoscale 33 . We report time-resolved imaging using two modes of operation, Fourier transform holography (FTH) and coherent diffractive imaging (CDI).…”

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Ultrafast X-ray imaging of the light-induced phase transition in VO2

et al. 2022

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Using light to control transient phases in quantum materials is an emerging route to engineer new properties and functionality, with both thermal and non-thermal phases observed out of equilibrium. Transient phases are expected to be heterogeneous, either through photo-generated domain growth or by generating topological defects, and this impacts the dynamics of the system. However, this nanoscale heterogeneity has not been directly observed. Here we use time- and spectrally resolved coherent X-ray imaging to track the prototypical light-induced insulator-to-metal phase transition in vanadium dioxide on the nanoscale with femtosecond time resolution. We show that the early-time dynamics are independent of the initial spatial heterogeneity and observe a 200 fs switch to the metallic phase. A heterogeneous response emerges only after hundreds of picoseconds. Through spectroscopic imaging, we reveal that the transient metallic phase is a highly orthorhombically strained rutile metallic phase, an interpretation that is in contrast to those based on spatially averaged probes. Our results demonstrate the critical importance of spatially and spectrally resolved measurements for understanding and interpreting the transient phases of quantum materials.

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Ultrafast X-ray imaging of the light-induced phase transition in VO2

et al. 2022

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“…Key to resolving this issue will be to understand how inhomogeneity both before 35 and after excitation could impact interpretations based on TDGL theory. To this end, the need for techniques that can image the initial inhomogeneity as well as their dynamics 36 , 37 will be increasingly important 38 – 41 . Alternatively, disorder and fluctuations may stabilize the equilibrium high temperature phase in both VO 2 42 and LSMO 22 as both systems show large fluctuations above T c , and systems that are stabilized by entropy may show fundamentally different dynamics to those driven by soft modes.…”

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Multi-mode excitation drives disorder during the ultrafast melting of a C4-symmetry-broken phase

et al. 2022

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Spontaneous C4-symmetry breaking phases are ubiquitous in layered quantum materials, and often compete with other phases such as superconductivity. Preferential suppression of the symmetry broken phases by light has been used to explain non-equilibrium light induced superconductivity, metallicity, and the creation of metastable states. Key to understanding how these phases emerge is understanding how C4 symmetry is restored. A leading approach is based on time-dependent Ginzburg-Landau theory, which explains the coherence response seen in many systems. However, we show that, for the case of the single layered manganite La0.5Sr1.5MnO4, the theory fails. Instead, we find an ultrafast inhomogeneous disordering transition in which the mean-field order parameter no longer reflects the atomic-scale state of the system. Our results suggest that disorder may be common to light-induced phase transitions, and methods beyond the mean-field are necessary for understanding and manipulating photoinduced phases.

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“…The reversible semiconductor-to-metal transition, often referred to as metal–insulator transition (MIT), can be triggered by various stimuli, such as heat, light, mechanical pressure, and electric and magnetic fields, which opens the possibility for realizing switching devices between well-defined off (insulating) and on (metallic) states. In order to better understand the microscopic origin of the MIT, VO 2 has been investigated with state-of-the-art (pump–probe) spectroscopy techniques employing radiation all across the electromagnetic spectrum from hard and soft X-rays, to XUV, infrared, THz, microwave, and radio frequency, as well as electron microscopy. , The interested reader is referred to the review by Shao et al Our current understanding is that the electronic phase transition of VO 2 is inherently coupled to an accompanying structural phase transition from a monoclinic crystal structure at low temperature to a tetragonal structure at high temperature. The monoclinic phase is defined by a characteristic dimerization and tilt motif of the vanadium ions, whereas the tetragonal phase is isostructural to rutile TiO 2 .…”

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High-Strain-Induced Local Modification of the Electronic Properties of VO₂ Thin Films

Birkhölzer

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Gauquelin

et al. 2022

ACS Appl. Electron. Mater.

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Vanadium dioxide (VO2) is a popular candidate for electronic and optical switching applications due to its well-known semiconductor–metal transition. Its study is notoriously challenging due to the interplay of long- and short-range elastic distortions, as well as the symmetry change and the electronic structure changes. The inherent coupling of lattice and electronic degrees of freedom opens the avenue toward mechanical actuation of single domains. In this work, we show that we can manipulate and monitor the reversible semiconductor-to-metal transition of VO2 while applying a controlled amount of mechanical pressure by a nanosized metallic probe using an atomic force microscope. At a critical pressure, we can reversibly actuate the phase transition with a large modulation of the conductivity. Direct tunneling through the VO2–metal contact is observed as the main charge carrier injection mechanism before and after the phase transition of VO2. The tunneling barrier is formed by a very thin but persistently insulating surface layer of the VO2. The necessary pressure to induce the transition decreases with temperature. In addition, we measured the phase coexistence line in a hitherto unexplored regime. Our study provides valuable information on pressure-induced electronic modifications of the VO2 properties, as well as on nanoscale metal-oxide contacts, which can help in the future design of oxide electronics.

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Quantitative hyperspectral coherent diffractive imaging spectroscopy of a solid-state phase transition in vanadium dioxide

Cited by 13 publications

References 73 publications

Ultrafast X-ray imaging of the light-induced phase transition in VO2

Ultrafast X-ray imaging of the light-induced phase transition in VO2

Multi-mode excitation drives disorder during the ultrafast melting of a C4-symmetry-broken phase

High-Strain-Induced Local Modification of the Electronic Properties of VO₂ Thin Films

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Quantitative hyperspectral coherent diffractive imaging spectroscopy of a solid-state phase transition in vanadium dioxide

Cited by 13 publications

References 73 publications

Ultrafast X-ray imaging of the light-induced phase transition in VO2

Ultrafast X-ray imaging of the light-induced phase transition in VO2

Multi-mode excitation drives disorder during the ultrafast melting of a C4-symmetry-broken phase

High-Strain-Induced Local Modification of the Electronic Properties of VO2 Thin Films

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High-Strain-Induced Local Modification of the Electronic Properties of VO₂ Thin Films