Contact

Dr. rer. nat. Jan Vogelsang

Institute of Physics  (» Postal address)

W2 2-201 (» Adress and map)

+49 441 798-3515  (F&P

Publications

2024

  • Vogelsang, J. et al. Time-Resolved Photoemission Electron Microscopy on a ZnO Surface Using an Extreme Ultraviolet Attosecond Pulse Pair. Advanced Physics Research 3, 2300122 (2024).
  • Altenburg, J., Bauer, C., Meier, K. & Vogelsang, J. Non-collinear bipulse reconstruction via dispersion scan. Opt. Express, OE 32, 38275–38284 (2024).
  • Meier, K., Klösgen, A., Hansen, L., Harland, K. & Vogelsang, J. Compact laser system delivering 2-um few-cycle pulses for strong-field experiments at 200 kHz repetition rate. Preprint at https://doi.org/10.48550/arXiv.2410.10734 (2024).

2023

  • Vogelsang, J. Attosekunden-Spektroskopie: Von Atomen zu nanoskaligen Festkörpern. Bunsen-Magazin 5, 157–159 (2023) [not peer-reviewed!].

2022

  • Sytcevich, I. et al. Few-cycle short-wave-infrared light source for strong-field experiments at 200 kHz repetition rate. Opt. Express 30, 27858–27867 (2022).

2021

  • Hergert, G. et al. Probing Transient Localized Electromagnetic Fields Using Low-Energy Point-Projection Electron Microscopy. ACS Photonics 8, 2573–2580 (2021).
  • Krauth, J. J. et al. Measuring the α-particle charge radius with muonic helium-4 ions. Nature 589, 527–531 (2021).
  • Sytcevich, I. et al. Characterizing ultrashort laser pulses with second harmonic dispersion scans. J. Opt. Soc. Am. B, JOSAB 38, 1546–1555 (2021).
  • Vogelsang, J. et al. Coherent Excitation and Control of Plasmons on Gold Using Two-Dimensional Transition Metal Dichalcogenides. ACS Photonics 8, 1607–1615 (2021).
  • Wittenbecher, L. et al. Unraveling the Ultrafast Hot Electron Dynamics in Semiconductor Nanowires. ACS Nano 15, 1133–1144 (2021).

2020

  • Cheng, Y.-C. et al. Controlling photoionization using attosecond time-slit interferences. PNAS 117, 10727–10732 (2020).
  • Dombi, P. et al. Strong-field nano-optics. Rev. Mod. Phys. 92, 025003 (2020).
  • Langer, F. et al. Few-cycle lightwave-driven currents in a semiconductor at high repetition rate. Optica 7, 276–279 (2020).
  • Mikaelsson, S. et al. A high-repetition rate attosecond light source for time-resolved coincidence spectroscopy. Nanophotonics 10, 117–128 (2020).
  • Zhong, J.-H. et al. Nonlinear plasmon-exciton coupling enhances sum-frequency generation from a hybrid metal/semiconductor nanostructure. Nat Commun 11, 1464 (2020).

2019

  • Wikmark, H. et al. Spatiotemporal coupling of attosecond pulses. Proceedings of the National Academy of Sciences 116, 4779–4787 (2019).

2018

  • Vogelsang, J., Hergert, G., Wang, D., Groß, P. & Lienau, C. Observing charge separation in nanoantennas via ultrafast point-projection electron microscopy. Light: Science & Applications 7, 55 (2018).
  • Vogelsang, J. et al. Plasmonic-nanofocusing-based electron holography. ACS Photonics 5, 3584–3593 (2018).

2017

  • Hergert, G. et al. Long-lived electron emission reveals localized plasmon modes in disordered nanosponge antennas. Light: Science & Applications 6, e17075 (2017).

2016

  • Groß, P. et al. Plasmonic nanofocusing – grey holes for light. Advances in Physics: X 1, 297–330 (2016).

2015

  • Vogelsang, J. et al. Ultrafast Electron Emission from a Sharp Metal Nanotaper Driven by Adiabatic Nanofocusing of Surface Plasmons. Nano Lett. 15, 4685–4691 (2015).

2014

  • Piglosiewicz, B. et al. Carrier-envelope phase effects on the strong-field photoemission of electrons from metallic nanostructures. Nat Photon 8, 37–42 (2014).
  • Piglosiewicz, B. et al. Electron Photoemission and Acceleration from Sharp Gold Nanotapers in the Strong-Field, Few-Cycle Regime. Quantum Matter 3, 297–306 (2014).
  • Vogelsang, J. et al. Multipass laser cavity for efficient transverse illumination of an elongated volume. Optics Express 22, 13050 (2014).
  • Vogelsang, J. et al. High passive CEP stability from a few-cycle, tunable NOPA-DFG system for observation of CEP-effects in photoemission. Optics Express 22, 25295 (2014).

2013

  • Antognini, A. et al. Proton Structure from the Measurement of 2S-2P Transition Frequencies of Muonic Hydrogen. Science 339, 417–420 (2013).
  • Diepold, M. et al. Lifetime and population of the 2S state in muonic hydrogen and deuterium. Phys. Rev. A 88, 042520 (2013).
  • Pohl, R. et al. Laser spectroscopy of muonic hydrogen. Annalen der Physik 525, 647–651 (2013).

We are grateful for the support of

Jan Vogelsang (Changed: 15 Oct 2024)  | 
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