A new laser-based technique reveals hidden phase changes in quantum materials, helping scientists better understand and control them for future technologies

In condensed matter physics, topological phase transitions are a key area of research because they lead to unusual and potentially useful states of matter. One example is the Floquet topological insulator, which can switch from a non-topological to a topological phase when exposed to a laser pulse. However, detecting these transitions is difficult due to the extremely fast timescales involved and interference from infrared fields, which can distort the photoelectron signals.
A Chern insulator is a unique material that acts as an insulator in its bulk but conducts electricity along its edges. These edge states arise from the material’s crystal structure of the bulk. Unlike other topological materials, Chern insulators do not require magnetic fields. Their edge conduction is topologically protected, meaning it is highly resistant to defects and noise. This makes them promising candidates for quantum technologies, spintronics, and energy-efficient electronics.
In this study, researchers developed a new method to detect phase changes in Chern insulators. Using numerical simulations, they demonstrated that attosecond x-ray absorption spectroscopy, combined with polarization-dependent dichroism, can effectively reveal these transitions. Their semi-classical approach isolates the intra-band Berry connection, providing deeper insight into how topological edge states form and how electrons behave in these systems.
This work represents a significant advance in topological materials research. It offers a new way to observe changes in quantum materials in real time, expands the use of attosecond spectroscopy from simple atoms and molecules to complex solids, and opens the door to studying dynamic systems like Floquet topological insulators.
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Topological phase transitions via attosecond x-ray absorption spectroscopy
Juan F P Mosquera et al 2024 Rep. Prog. Phys. 87 117901
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Strong–laser–field physics, non–classical light states and quantum information science by U Bhattacharya, Th Lamprou, A S Maxwell, A Ordóñez, E Pisanty, J Rivera-Dean, P Stammer, M F Ciappina, M Lewenstein and P Tzallas (2023)