Lightwave electronics for quantum precision
ORAL · Invited
Abstract
Lightwave electronics (LWE) [1,2] is set to revolutionize classical and quantum information processing by utilizing the exceptional speed of nature’s fastest processes, impacting all quantum applications beyond just quantum computing. This talk highlights several theory–experiment breakthroughs: the introduction of a quasiparticle collider [3], developments in attoclocked multi-electron quantum information [4], the ultrafast flipping of quantum states within a few femtoseconds [5], and the exploration of quantum phase transitions [6] in quantum materials. Additionally, I will discuss how LWE enhances the precision of both quantum-field and quantum-state [7] detection.
[1] M. Borsch, M. Meierhofer, R. Huber, M. Kira, Lightwave electronics in condensed matter, Nat. Rev. Mater. 8, 668 (2023).
[2] M. Kira and R. Huber, Unlocking Lightwave Electronics, Optics and Photonics News 36, 28 (2025).
[3] F. Langer, M. Hohenleutner, C. Schmid, C. Poellmann, P. Nagler, T. Korn, C. Schüller, M. S. Sherwin, U. Huttner, J. T. Steiner, S. W. Koch, M. Kira, and R. Huber, Lightwave-driven quasiparticle collisions on a sub-cycle timescale, Nature 533, 225 (2016).
[4] J. Freudenstein, M. Borsch, M. Meierhofer, D. Afanasiev, C. P. Schmid, F. Sandner, M. Liebich, A. Girnghuber, M. Knorr, M. Kira, R. Huber, Attosecond clocking of correlations between Bloch electrons, Nature 610, 290 (2022).
[5] F. Langer, C.P. Schmid, S. Schlauderer, M. Gmitra, J. Fabian, P. Nagler, C. Schüller, T. Korn, P.G. Hawkins, J.T. Steiner, U. Huttner, S. W. Koch, M. Kira, and R. Huber, Lightwave valleytronics in a monolayer of tungsten diselenide, Nature 557, 76 (2018).
[6] M. Liebich, M. Florian, N. Nilforoushan, F. Mooshammer, A. D. Koulouklidis, L. Wittmann, K. Mosina, Z. Sofer, F. Dirnberger, M. Kira, and R. Huber, Controlling Coulomb correlations and fine structure of quasi-1D excitons by magnetic order, Nature Materials, accepted (2025).
[7] M. Borsch, C. P. Schmid, L. Weigl, S. Schlauderer, N. Hofmann, C. Lange, J. T. Steiner, S. W. Koch, R. Huber, M. Kira, Super-resolution lightwave tomography of electronic bands in quantum materials, Science 370, 1204 (2020).
[1] M. Borsch, M. Meierhofer, R. Huber, M. Kira, Lightwave electronics in condensed matter, Nat. Rev. Mater. 8, 668 (2023).
[2] M. Kira and R. Huber, Unlocking Lightwave Electronics, Optics and Photonics News 36, 28 (2025).
[3] F. Langer, M. Hohenleutner, C. Schmid, C. Poellmann, P. Nagler, T. Korn, C. Schüller, M. S. Sherwin, U. Huttner, J. T. Steiner, S. W. Koch, M. Kira, and R. Huber, Lightwave-driven quasiparticle collisions on a sub-cycle timescale, Nature 533, 225 (2016).
[4] J. Freudenstein, M. Borsch, M. Meierhofer, D. Afanasiev, C. P. Schmid, F. Sandner, M. Liebich, A. Girnghuber, M. Knorr, M. Kira, R. Huber, Attosecond clocking of correlations between Bloch electrons, Nature 610, 290 (2022).
[5] F. Langer, C.P. Schmid, S. Schlauderer, M. Gmitra, J. Fabian, P. Nagler, C. Schüller, T. Korn, P.G. Hawkins, J.T. Steiner, U. Huttner, S. W. Koch, M. Kira, and R. Huber, Lightwave valleytronics in a monolayer of tungsten diselenide, Nature 557, 76 (2018).
[6] M. Liebich, M. Florian, N. Nilforoushan, F. Mooshammer, A. D. Koulouklidis, L. Wittmann, K. Mosina, Z. Sofer, F. Dirnberger, M. Kira, and R. Huber, Controlling Coulomb correlations and fine structure of quasi-1D excitons by magnetic order, Nature Materials, accepted (2025).
[7] M. Borsch, C. P. Schmid, L. Weigl, S. Schlauderer, N. Hofmann, C. Lange, J. T. Steiner, S. W. Koch, R. Huber, M. Kira, Super-resolution lightwave tomography of electronic bands in quantum materials, Science 370, 1204 (2020).
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Presenters
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Mackillo Kira
University of Michigan
Authors
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Mackillo Kira
University of Michigan