Subcycle contact-free nanoscopy of ultrafast interlayer transport in atomically thin heterostructures

M. Plankl; P.E. Faria Junior; F. Mooshammer; T. Siday; M. Zizlsperger; F. Sandner; F. Schiegl; S. Maier; M.A. Huber; M. Gmitra; J. Fabian; J.L. Boland; T.L. Cocker; Rupert Huber

doi:10.1038/s41566-021-00813-y

Subcycle contact-free nanoscopy of ultrafast interlayer transport in atomically thin heterostructures

M. Plankl, P.E. Faria Junior, F. Mooshammer, T. Siday, M. Zizlsperger, F. Sandner, F. Schiegl, S. Maier, M.A. Huber, M. Gmitra, J. Fabian, J.L. Boland, T.L. Cocker, Rupert Huber (Corresponding)

EEE - Academic & Research

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Abstract

Tunnelling is one of the most fundamental manifestations of quantum mechanics. The recent advent of lightwave-driven scanning tunnelling microscopy has revolutionized ultrafast nanoscience by directly resolving electron tunnelling in electrically conducting samples on the relevant ultrashort length- and timescales. Here, we introduce a complementary approach based on terahertz near-field microscopy to perform ultrafast nano-videography of tunnelling processes even in insulators. The central idea is to probe the evolution of the local polarizability of electron–hole pairs with evanescent terahertz fields, which we detect with subcycle temporal resolution. In a proof of concept, we resolve femtosecond interlayer transport in van der Waals heterobilayers and reveal pronounced variations of the local formation and annihilation of interlayer excitons on deeply subwavelength, nanometre scales. Such contact-free nanoscopy of tunnelling-induced dynamics should be universally applicable to conducting and non-conducting samples and reveal how ultrafast transport processes shape functionalities in a wide range of condensed matter systems.

Original language	English
Pages (from-to)	594-600
Number of pages	7
Journal	Nat Photon
Volume	15
Issue number	8
Early online date	13 May 2021
DOIs	https://doi.org/10.1038/s41566-021-00813-y
Publication status	Published - 13 May 2021

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1 Finished
1 Active

Terahertz, Topology, Technology: Realising the potential of nanoscale Dirac materials using near-field terahertz spectroscopy
Boland, J. (PI)
1/07/20 → 31/07/25
Project: Research
Terahertz lights up the nanoscale: Exposing the ultrafast dynamics of Dirac systems via near-field terahertz spectroscopy
Boland, J. (PI)
1/09/19 → 28/02/22
Project: Research

2 Abstract
1 Conference contribution

Near-field nanoscopy of excitons and ultrafast interlayer dynamics in van der Waals crystals
Mooshammer, F., Plankl, M., Junior, P. E. F., Chae, S., Siday, T., Zizlsperger, M., Sandner, F., Schiegl, F., Zhang, S., Shao, Y., Sternbach, A., Rizzo, D. J., Maier, S., Huber, M. A., Gmitra, M., Fabian, J., Boland, J. L., Zhu, X., Schuck, P. J. & Hone, J. & 3 others, Cocker, T. L., Basov, D. N. & Huber, R., 5 Mar 2022.
Research output: Contribution to conference › Abstract › peer-review
Ultrafast interlayer charge transfer probed by subcycle contact-free THz nanoscopy
Boland, J. L., 2022.
Research output: Contribution to conference › Abstract › peer-review
Mapping the ultrafast charge transfer in van der Waals heterostructures
Plankl, M., Zizlsperger, M., Mooshammer, F., Schiegl, F., Sandner, F., Siday, T., Huber, M. A., Boland, J. L., Cocker, T. L. & Huber, R., 8 Nov 2020, 2020 45th International Conference on Infrared, Millimeter, and Terahertz Waves, IRMMW-THz 2020. IEEE, p. 474-475 2 p. (2020 45TH INTERNATIONAL CONFERENCE ON INFRARED, MILLIMETER, AND TERAHERTZ WAVES (IRMMW-THZ)).
Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Humboldt Research Fellowship
Boland, J. (Recipient), Nov 2017
Prize: Fellowship awarded competitively

3 Invited talk

A journey in physics
Boland, J. (Keynote speaker)
7 Mar 2023
Activity: Talk or presentation › Invited talk › Research
Impurity characterisation on nanometre length scales via near-field terahertz spectroscopy
Boland, J. (Invited speaker)
7 Sept 2022 → 8 Sept 2022
Activity: Talk or presentation › Invited talk › Research
Non-destructive 3D imaging and spectroscopy of surfaces via near-field optical microscopy
Boland, J. (Invited speaker)
13 Jul 2022 → 14 Jul 2022
Activity: Talk or presentation › Invited talk › Research

Cite this

Plankl, M., Faria Junior, P. E., Mooshammer, F., Siday, T., Zizlsperger, M., Sandner, F., Schiegl, F., Maier, S., Huber, M. A., Gmitra, M., Fabian, J., Boland, J. L., Cocker, T. L., & Huber, R. (2021). Subcycle contact-free nanoscopy of ultrafast interlayer transport in atomically thin heterostructures. Nat Photon, 15(8), 594-600. https://doi.org/10.1038/s41566-021-00813-y

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title = "Subcycle contact-free nanoscopy of ultrafast interlayer transport in atomically thin heterostructures",

abstract = "Tunnelling is one of the most fundamental manifestations of quantum mechanics. The recent advent of lightwave-driven scanning tunnelling microscopy has revolutionized ultrafast nanoscience by directly resolving electron tunnelling in electrically conducting samples on the relevant ultrashort length- and timescales. Here, we introduce a complementary approach based on terahertz near-field microscopy to perform ultrafast nano-videography of tunnelling processes even in insulators. The central idea is to probe the evolution of the local polarizability of electron–hole pairs with evanescent terahertz fields, which we detect with subcycle temporal resolution. In a proof of concept, we resolve femtosecond interlayer transport in van der Waals heterobilayers and reveal pronounced variations of the local formation and annihilation of interlayer excitons on deeply subwavelength, nanometre scales. Such contact-free nanoscopy of tunnelling-induced dynamics should be universally applicable to conducting and non-conducting samples and reveal how ultrafast transport processes shape functionalities in a wide range of condensed matter systems.",

author = "M. Plankl and {Faria Junior}, P.E. and F. Mooshammer and T. Siday and M. Zizlsperger and F. Sandner and F. Schiegl and S. Maier and M.A. Huber and M. Gmitra and J. Fabian and J.L. Boland and T.L. Cocker and Rupert Huber",

note = "Funding Information: We thank M. Furthmeier for technical assistance and T. F. Heinz for fruitful discussions. This work was supported by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)—Project-ID, 314695032—SFB 1277 (Subprojects A05 and B05) and through research grants HU1598/3, HU1598/8 and CO1492/1. P.E.F.J. acknowledges funding by the A. v. Humboldt Foundation and by Capes (Grant No. 99999.000420/2016-06). M.A.H. was supported in part by the US Department of Energy, Office of Science, Basic Energy Sciences (BES), Chemical Sciences, Geosciences, and Biosciences Division, AMOS Program. M.G. acknowledges support by the Ministry of Education, Science, Research and Sport of the Slovak Republic (Grant No. VEGA 1/0105/20). J.L.B. acknowledges support by the A. v. Humboldt Foundation and EPSRC (UK) via project EP/S037438/1. Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive licence to Springer Nature Limited.",

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doi = "10.1038/s41566-021-00813-y",

language = "English",

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pages = "594--600",

journal = "Nat Photon",

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T1 - Subcycle contact-free nanoscopy of ultrafast interlayer transport in atomically thin heterostructures

AU - Plankl, M.

AU - Faria Junior, P.E.

AU - Mooshammer, F.

AU - Siday, T.

AU - Zizlsperger, M.

AU - Sandner, F.

AU - Schiegl, F.

AU - Maier, S.

AU - Huber, M.A.

AU - Gmitra, M.

AU - Fabian, J.

AU - Boland, J.L.

AU - Cocker, T.L.

A2 - Huber, Rupert

N1 - Funding Information: We thank M. Furthmeier for technical assistance and T. F. Heinz for fruitful discussions. This work was supported by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)—Project-ID, 314695032—SFB 1277 (Subprojects A05 and B05) and through research grants HU1598/3, HU1598/8 and CO1492/1. P.E.F.J. acknowledges funding by the A. v. Humboldt Foundation and by Capes (Grant No. 99999.000420/2016-06). M.A.H. was supported in part by the US Department of Energy, Office of Science, Basic Energy Sciences (BES), Chemical Sciences, Geosciences, and Biosciences Division, AMOS Program. M.G. acknowledges support by the Ministry of Education, Science, Research and Sport of the Slovak Republic (Grant No. VEGA 1/0105/20). J.L.B. acknowledges support by the A. v. Humboldt Foundation and EPSRC (UK) via project EP/S037438/1. Publisher Copyright: © 2021, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2021/5/13

Y1 - 2021/5/13

N2 - Tunnelling is one of the most fundamental manifestations of quantum mechanics. The recent advent of lightwave-driven scanning tunnelling microscopy has revolutionized ultrafast nanoscience by directly resolving electron tunnelling in electrically conducting samples on the relevant ultrashort length- and timescales. Here, we introduce a complementary approach based on terahertz near-field microscopy to perform ultrafast nano-videography of tunnelling processes even in insulators. The central idea is to probe the evolution of the local polarizability of electron–hole pairs with evanescent terahertz fields, which we detect with subcycle temporal resolution. In a proof of concept, we resolve femtosecond interlayer transport in van der Waals heterobilayers and reveal pronounced variations of the local formation and annihilation of interlayer excitons on deeply subwavelength, nanometre scales. Such contact-free nanoscopy of tunnelling-induced dynamics should be universally applicable to conducting and non-conducting samples and reveal how ultrafast transport processes shape functionalities in a wide range of condensed matter systems.

AB - Tunnelling is one of the most fundamental manifestations of quantum mechanics. The recent advent of lightwave-driven scanning tunnelling microscopy has revolutionized ultrafast nanoscience by directly resolving electron tunnelling in electrically conducting samples on the relevant ultrashort length- and timescales. Here, we introduce a complementary approach based on terahertz near-field microscopy to perform ultrafast nano-videography of tunnelling processes even in insulators. The central idea is to probe the evolution of the local polarizability of electron–hole pairs with evanescent terahertz fields, which we detect with subcycle temporal resolution. In a proof of concept, we resolve femtosecond interlayer transport in van der Waals heterobilayers and reveal pronounced variations of the local formation and annihilation of interlayer excitons on deeply subwavelength, nanometre scales. Such contact-free nanoscopy of tunnelling-induced dynamics should be universally applicable to conducting and non-conducting samples and reveal how ultrafast transport processes shape functionalities in a wide range of condensed matter systems.

U2 - 10.1038/s41566-021-00813-y

DO - 10.1038/s41566-021-00813-y

M3 - Article

SN - 1749-4885

VL - 15

SP - 594

EP - 600

JO - Nat Photon

JF - Nat Photon

IS - 8

ER -

Subcycle contact-free nanoscopy of ultrafast interlayer transport in atomically thin heterostructures

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