It is here! The result of years of hard work together with a great team.🥳🥳 Check out how we were able to bring optical microscopy to the atomic scale and use this to sample subcycle tunnelling currents directly in the time domain: nature.com/articles/s4158…

Some work from my time in Regensburg, in the Huber Group. We worked out how to measure the coherent emission from tunnelling electrons, this lets us do ultrafast optical microscopy now at the atomic scale! nature.com/articles/s4158…

As well, we wrote a little briefing which gives a bit of an overview! nature.com/articles/d4158…

Our latest results have just been published 🥳 Please check out how we have brought all-optical microscopy to the atomic scale. nature.com/articles/s4158…

Unlocking the power of tunnelling electrons for ultrafast optical microscopy, now zooming in at the atomic scale! See for yourself: nature.com/articles/s4158…

It is a great pleasure to see the hard work of my colleagues and friends finally published! If you have ever wondered what the subcycle structure of atomically confined tunnel currents looks like, you should take a look at this amazing work: nature.com/articles/s4158…

New #openaccess article online: Ultrafast atomic-scale scanning tunnelling spectroscopy of a single vacancy in a monolayer crystal. go.nature.com/3wiyoQ1

Nature research paper: All-optical subcycle microscopy on atomic length scales go.nature.com/3y7sh1f

Ever imagined capturing chemical reactions with atomic resolution on video?🧬⌬🎥 We take a step closer to this vision with near-field optical tunneling emission (NOTE) microscopy💥nature.com/articles/s4158… Huber Group NOTE mechanism validated by real-time TDDFT💻! CP2K

Physiker der Universität Regensburg haben erstmals beobachtet, wie ein winziger #Lichtfunke von einem #Atom zum anderen überspringt. Damit ist es ihnen gelungen, eine Quantenversion des Funkenexperiments von Heinrich Hertz nachzuweisen, berichtet scinexx.de: scinexx.de/news/physik/ph…

Kleine Schritte für Elektronen – große Schritte für die Solarzellen der Zukunft? Physikerinnen und Physiker an der Universität Regensburg und der Universität Oxford enthüllen mit einem ultraschnellen Mikroskop, wie sich Elektronen in einem ne... nachrichten.idw-online.de/2024/07/17/kle…

🚀 Physiker der Uni Regensburg und Uni Oxford zeigen mit ultraschnellen Mikroskop gezeigt, wie Elektronen sich in Metall-Halogenid-Perowskiten bewegen. Diese Erkenntnisse könnten die Effizienz von Solarzellen revolutionieren! sohub.io/9oxj

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 University of Oxford. Nature Photonics nature.com/articles/s4156…

Excited to share that our results on diffusion in metal halide perovskites have been published in Nature Photonics 🥳

Do you want to fight climate change? Then you should build better solar cells! For this, perovskites are setting new records, but why? Happy to see my colleagues investigate that question with nanoscale spatial and subcycle temporal resolution: nature.com/articles/s4156…

My dear colleagues from Huber Group at Universität Regensburg have recently explored diffusion in metal halide perovskites! Their results have been published today in Nature Photonics! 🥳 Congratulations on a fantastic paper! 🔗Links: nature.com/articles/s4156… or rdcu.be/dN4ME

Great news! Our latest results have been published in Nature Photonics. We developed an approach based on ultrafast near-field microscopy to simultaneously probe the nanoscale structure and ultrafast carrier dynamics in metal halide perovskites nature.com/articles/s4156…

Happy to announce our latest work has been published in Nature Photonics. We have developed a method based on ultrafast near-field microscopy to study the interplay between the nanoscale structure and ultrafast carrier dynamics in metal halide perovskites. nature.com/articles/s4156…

A paper on metal halide perovskites from time in Huber Group and in Oxford, just published in Nature Photonics We use ultrafast nanoscopy to see structural modes on the nanoscale as well as ultrafast charge carrier motion! nature.com/articles/s4156…

A story about resonantly enhancing near-fields to measure the conductivity of single nanowires - enjoyable collaboration with Ultrafast Photonics UCL, Department of Physics at University of Oxford, Joyce Group and more! pubs.acs.org/doi/10.1021/ac…