Formation of moiré interlayer excitons in space and time

David Schmitt; Jan Philipp Bange; Wiebke Bennecke; Abdul Aziz AlMutairi; Giuseppe Meneghini; Kenji Watanabe; Takashi Taniguchi; Daniel Steil; D. Russell Luke; R. Thomas Weitz; Sabine Steil; G. S.Matthijs Jansen; Samuel Brem; Ermin Malic; Stephan Hofmann; Marcel Reutzel; Stefan Mathias

doi:10.1038/s41586-022-04977-7

Formation of moiré interlayer excitons in space and time

David Schmitt
, Jan Philipp Bange
, Wiebke Bennecke
, Abdul Aziz AlMutairi
, Giuseppe Meneghini
, Kenji Watanabe
, Takashi Taniguchi
, Daniel Steil
, D. Russell Luke
, R. Thomas Weitz
, Sabine Steil
, G. S.Matthijs Jansen
, Samuel Brem
, Ermin Malic
, Stephan Hofmann
, Marcel Reutzel^*
, Stefan Mathias^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

131 Scopus citations

Abstract

Moiré superlattices in atomically thin van der Waals heterostructures hold great promise for extended control of electronic and valleytronic lifetimes^1–7, the confinement of excitons in artificial moiré lattices^8–13 and the formation of exotic quantum phases^14–18. Such moiré-induced emergent phenomena are particularly strong for interlayer excitons, where the hole and the electron are localized in different layers of the heterostructure^19,20. To exploit the full potential of correlated moiré and exciton physics, a thorough understanding of the ultrafast interlayer exciton formation process and the real-space wavefunction confinement is indispensable. Here we show that femtosecond photoemission momentum microscopy provides quantitative access to these key properties of the moiré interlayer excitons. First, we elucidate that interlayer excitons are dominantly formed through femtosecond exciton–phonon scattering and subsequent charge transfer at the interlayer-hybridized Σ valleys. Second, we show that interlayer excitons exhibit a momentum fingerprint that is a direct hallmark of the superlattice moiré modification. Third, we reconstruct the wavefunction distribution of the electronic part of the exciton and compare the size with the real-space moiré superlattice. Our work provides direct access to interlayer exciton formation dynamics in space and time and reveals opportunities to study correlated moiré and exciton physics for the future realization of exotic quantum phases of matter.

Original language	English
Pages (from-to)	499-503
Number of pages	5
Journal	Nature
Volume	608
Issue number	7923
DOIs	https://doi.org/10.1038/s41586-022-04977-7
State	Published - 18 Aug 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2022, The Author(s), under exclusive licence to Springer Nature Limited.

ASJC Scopus subject areas

General

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10.1038/s41586-022-04977-7

Cite this

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title = "Formation of moir{\'e} interlayer excitons in space and time",

abstract = "Moir{\'e} superlattices in atomically thin van der Waals heterostructures hold great promise for extended control of electronic and valleytronic lifetimes1–7, the confinement of excitons in artificial moir{\'e} lattices8–13 and the formation of exotic quantum phases14–18. Such moir{\'e}-induced emergent phenomena are particularly strong for interlayer excitons, where the hole and the electron are localized in different layers of the heterostructure19,20. To exploit the full potential of correlated moir{\'e} and exciton physics, a thorough understanding of the ultrafast interlayer exciton formation process and the real-space wavefunction confinement is indispensable. Here we show that femtosecond photoemission momentum microscopy provides quantitative access to these key properties of the moir{\'e} interlayer excitons. First, we elucidate that interlayer excitons are dominantly formed through femtosecond exciton–phonon scattering and subsequent charge transfer at the interlayer-hybridized Σ valleys. Second, we show that interlayer excitons exhibit a momentum fingerprint that is a direct hallmark of the superlattice moir{\'e} modification. Third, we reconstruct the wavefunction distribution of the electronic part of the exciton and compare the size with the real-space moir{\'e} superlattice. Our work provides direct access to interlayer exciton formation dynamics in space and time and reveals opportunities to study correlated moir{\'e} and exciton physics for the future realization of exotic quantum phases of matter.",

author = "David Schmitt and Bange, \{Jan Philipp\} and Wiebke Bennecke and AlMutairi, \{Abdul Aziz\} and Giuseppe Meneghini and Kenji Watanabe and Takashi Taniguchi and Daniel Steil and Luke, \{D. Russell\} and Weitz, \{R. Thomas\} and Sabine Steil and Jansen, \{G. S.Matthijs\} and Samuel Brem and Ermin Malic and Stephan Hofmann and Marcel Reutzel and Stefan Mathias",

note = "Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2022",

month = aug,

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doi = "10.1038/s41586-022-04977-7",

language = "English",

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T1 - Formation of moiré interlayer excitons in space and time

AU - Schmitt, David

AU - Bange, Jan Philipp

AU - Bennecke, Wiebke

AU - AlMutairi, Abdul Aziz

AU - Meneghini, Giuseppe

AU - Watanabe, Kenji

AU - Taniguchi, Takashi

AU - Steil, Daniel

AU - Luke, D. Russell

AU - Weitz, R. Thomas

AU - Steil, Sabine

AU - Jansen, G. S.Matthijs

AU - Brem, Samuel

AU - Malic, Ermin

AU - Hofmann, Stephan

AU - Reutzel, Marcel

AU - Mathias, Stefan

PY - 2022/8/18

Y1 - 2022/8/18

N2 - Moiré superlattices in atomically thin van der Waals heterostructures hold great promise for extended control of electronic and valleytronic lifetimes1–7, the confinement of excitons in artificial moiré lattices8–13 and the formation of exotic quantum phases14–18. Such moiré-induced emergent phenomena are particularly strong for interlayer excitons, where the hole and the electron are localized in different layers of the heterostructure19,20. To exploit the full potential of correlated moiré and exciton physics, a thorough understanding of the ultrafast interlayer exciton formation process and the real-space wavefunction confinement is indispensable. Here we show that femtosecond photoemission momentum microscopy provides quantitative access to these key properties of the moiré interlayer excitons. First, we elucidate that interlayer excitons are dominantly formed through femtosecond exciton–phonon scattering and subsequent charge transfer at the interlayer-hybridized Σ valleys. Second, we show that interlayer excitons exhibit a momentum fingerprint that is a direct hallmark of the superlattice moiré modification. Third, we reconstruct the wavefunction distribution of the electronic part of the exciton and compare the size with the real-space moiré superlattice. Our work provides direct access to interlayer exciton formation dynamics in space and time and reveals opportunities to study correlated moiré and exciton physics for the future realization of exotic quantum phases of matter.

AB - Moiré superlattices in atomically thin van der Waals heterostructures hold great promise for extended control of electronic and valleytronic lifetimes1–7, the confinement of excitons in artificial moiré lattices8–13 and the formation of exotic quantum phases14–18. Such moiré-induced emergent phenomena are particularly strong for interlayer excitons, where the hole and the electron are localized in different layers of the heterostructure19,20. To exploit the full potential of correlated moiré and exciton physics, a thorough understanding of the ultrafast interlayer exciton formation process and the real-space wavefunction confinement is indispensable. Here we show that femtosecond photoemission momentum microscopy provides quantitative access to these key properties of the moiré interlayer excitons. First, we elucidate that interlayer excitons are dominantly formed through femtosecond exciton–phonon scattering and subsequent charge transfer at the interlayer-hybridized Σ valleys. Second, we show that interlayer excitons exhibit a momentum fingerprint that is a direct hallmark of the superlattice moiré modification. Third, we reconstruct the wavefunction distribution of the electronic part of the exciton and compare the size with the real-space moiré superlattice. Our work provides direct access to interlayer exciton formation dynamics in space and time and reveals opportunities to study correlated moiré and exciton physics for the future realization of exotic quantum phases of matter.

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DO - 10.1038/s41586-022-04977-7

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AN - SCOPUS:85135977495

SN - 0028-0836

VL - 608

SP - 499

EP - 503

JO - Nature

JF - Nature

IS - 7923

ER -

Formation of moiré interlayer excitons in space and time

Abstract

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