Using ultrafast THz nanoscopy, we resolved the interplay between surface morphology, crystallographic phase, and vertical carrier dynamics in metal halide perovskites. Fantastic collaboration with Michael Johnston's group @UniofOxford. @NaturePhotonics https://t.co/Kpksic3JBB

We have discovered a quantum-mechanical contrast mechanism that enables all-optical microscopy to achieve atomic resolution while retaining subcycle precision. This new concept allows us to trace electrons on their intrinsic length and time scales. https://t.co/lpCedsdxf3

I am excited to share that I have been selected for the upcoming Lindau Nobel Laureate Meeting @lindaunobel! I look forward to this incredible opportunity to engage with Nobel Laureates and fellow young scientists. Special thanks to @uni_regensburg and @Huber_Group😊 #LINO24

Quantum dance to the beat of a drum: physicists at the University of Regensburg choreograph the shift of a quantized electronic energy level with atomic oscillations faster than a trillionth of a second. Read the full story in @NaturePhotonics. https://t.co/JUUApETCwI

We develop ultrafast lightwave-driven scanning tunnelling spectroscopy to investigate how the spin-orbit-split energy levels of an isolated Se vacancy within a WSe2 monolayer shift under phonon displacement. Read the full story in @NaturePhotonics. https://t.co/JUUApETCwI

Do not miss the chance to read our Review paper on lightwave electronics in condensed matter for free 🤩 Thanks to @Thorlabs for sponsoring 😊

@NaturePortfolio listed our Review on Lightwave electronics in condensed matter among the articles related to the Nobel Prize in Physics 2023🤩 Article: https://t.co/oPwQQ9uLcW Paper collection:

Lightwave electronics could enable the control of interactions in quantum materials and provide access to the quantum phases & quantum information of condensed-matter systems: read the Review by Mackillo Kira, Rupert Huber & collaborators: https://t.co/6CxQBxCneM @Huber_Group

We had the opportunity to write a Review on "Lightwave electronics in condensed matter" in @NatRevMater together with our long-standing friends @UMich @UMichECE: https://t.co/oPwQQ9uLcW

You can access it here: https://t.co/wlawSl4UqW

Our Review on "Lightwave electronics in condensed matter" has just been published in @NatRevMater! https://t.co/FUz4DjNoPJ

If you want to take a break from superconductivity, I wrote a commentary on one of the coolest papers I've encountered lately. In abstraction, it tries to (experimentally!) answer the question - what is the meaning of 'periodicity' in a quantum system?

I wrote a brief bit on a cool paper that came out last month in Nature. https://t.co/SrwetzNtLD

Nature research paper: Build-up and dephasing of Floquet–Bloch bands on subcycle timescales

Very impressive work - congratulations!

Build-up and dephasing of Floquet–Bloch bands on subcycle timescales. @Nature Their joint experiment and theory study provides a direct time-domain view of Floquet physics and explores the fundamental frontiers of ultrafast band-structure engineering. https://t.co/j7PMiqZwVP

Floquetbänder entstehen innerhalb eines einzigen optischen Zyklus! @Nature-Veröffentlichung von S. Ito @ et al. @Uni_MR, @Uni_Regensburg, mit theor. Modellierungen von M. Schüler @psich_de & unserem ehem. Gruppenleiter M. Sentef @sentefmi (@UniBremen): https://t.co/U33Rkqdzdg

Wie sich Elektronen mit Licht einkleiden: Forscher der @Uni_MR @Uni_Regensburg @psich_en @MPSDHamburg und @sentefmi berichten in @Nature über ihre Ergebnisse zur optischen Beeinflussung von Materialeigenschaften.@physicsMarburg https://t.co/X9A0Qoh3CH

MPSD news release: https://t.co/XjtQqq7zx5 #floquet #bands #emergence #lightmatter #interaction #quantum #phases #topological #insulators #bandstructure #engineering #physics #theory #simulations

Floquet bands form after a single optical cycle! New study just published @Nature - by S. Ito @ et al. @Uni_MR, @Uni_Regensburg, with theoretical modelling by M. Schüler @psich_en and our former group leader Michael Sentef @sentefmi (now @UniBremen). https://t.co/U33Rkqdzdg