Evidence of Rotational Fröhlich Coupling in Polaronic Trions

Maxim Trushin; Soumya Sarkar; Sinu Mathew; Sreetosh Goswami; Prasana Sahoo; Yan Wang; Jieun Yang; Weiwei Li; Judith L. MacManus-Driscoll; Manish Chhowalla; Shaffique Adam; T. Venkatesan

doi:10.1103/PhysRevLett.125.086803

Evidence of Rotational Fröhlich Coupling in Polaronic Trions

Maxim Trushin, Soumya Sarkar, Sinu Mathew, Sreetosh Goswami, Prasana Sahoo, Yan Wang, Jieun Yang, Weiwei Li, Judith L. MacManus-Driscoll, Manish Chhowalla, Shaffique Adam, T. Venkatesan

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16 Citations (Scopus)

Abstract

Electrons commonly couple through Fröhlich interactions with longitudinal optical phonons to form polarons. However, trions possess a finite angular momentum and should therefore couple instead to rotational optical phonons. This creates a polaronic trion whose binding energy is determined by the crystallographic orientation of the lattice. Here, we demonstrate theoretically within the Fröhlich approach and experimentally by photoluminescence emission that the bare trion binding energy (20 meV) is significantly enhanced by the phonons at the interface between the two-dimensional semiconductor MoS2 and the bulk transition metal oxide SrTiO3. The low-temperature binding energy changes from 60 meV in [001]-oriented substrates to 90 meV for [111] orientation, as a result of the counterintuitive interplay between the rotational axis of the MoS2 trion and that of the SrTiO3 phonon mode.

Original language	English
Article number	086803
Journal	Physical Review Letters
Volume	125
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevLett.125.086803
Publication status	Published - 21 Aug 2020

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© 2020 American Physical Society.

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title = "Evidence of Rotational Fr{\"o}hlich Coupling in Polaronic Trions",

abstract = "Electrons commonly couple through Fr{\"o}hlich interactions with longitudinal optical phonons to form polarons. However, trions possess a finite angular momentum and should therefore couple instead to rotational optical phonons. This creates a polaronic trion whose binding energy is determined by the crystallographic orientation of the lattice. Here, we demonstrate theoretically within the Fr{\"o}hlich approach and experimentally by photoluminescence emission that the bare trion binding energy (20 meV) is significantly enhanced by the phonons at the interface between the two-dimensional semiconductor MoS2 and the bulk transition metal oxide SrTiO3. The low-temperature binding energy changes from 60 meV in [001]-oriented substrates to 90 meV for [111] orientation, as a result of the counterintuitive interplay between the rotational axis of the MoS2 trion and that of the SrTiO3 phonon mode.",

author = "Maxim Trushin and Soumya Sarkar and Sinu Mathew and Sreetosh Goswami and Prasana Sahoo and Yan Wang and Jieun Yang and Weiwei Li and MacManus-Driscoll, {Judith L.} and Manish Chhowalla and Shaffique Adam and T. Venkatesan",

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AU - Trushin, Maxim

AU - Sarkar, Soumya

AU - Mathew, Sinu

AU - Goswami, Sreetosh

AU - Sahoo, Prasana

AU - Wang, Yan

AU - Yang, Jieun

AU - Li, Weiwei

AU - MacManus-Driscoll, Judith L.

AU - Chhowalla, Manish

AU - Adam, Shaffique

AU - Venkatesan, T.

PY - 2020/8/21

Y1 - 2020/8/21

N2 - Electrons commonly couple through Fröhlich interactions with longitudinal optical phonons to form polarons. However, trions possess a finite angular momentum and should therefore couple instead to rotational optical phonons. This creates a polaronic trion whose binding energy is determined by the crystallographic orientation of the lattice. Here, we demonstrate theoretically within the Fröhlich approach and experimentally by photoluminescence emission that the bare trion binding energy (20 meV) is significantly enhanced by the phonons at the interface between the two-dimensional semiconductor MoS2 and the bulk transition metal oxide SrTiO3. The low-temperature binding energy changes from 60 meV in [001]-oriented substrates to 90 meV for [111] orientation, as a result of the counterintuitive interplay between the rotational axis of the MoS2 trion and that of the SrTiO3 phonon mode.

AB - Electrons commonly couple through Fröhlich interactions with longitudinal optical phonons to form polarons. However, trions possess a finite angular momentum and should therefore couple instead to rotational optical phonons. This creates a polaronic trion whose binding energy is determined by the crystallographic orientation of the lattice. Here, we demonstrate theoretically within the Fröhlich approach and experimentally by photoluminescence emission that the bare trion binding energy (20 meV) is significantly enhanced by the phonons at the interface between the two-dimensional semiconductor MoS2 and the bulk transition metal oxide SrTiO3. The low-temperature binding energy changes from 60 meV in [001]-oriented substrates to 90 meV for [111] orientation, as a result of the counterintuitive interplay between the rotational axis of the MoS2 trion and that of the SrTiO3 phonon mode.

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VL - 125

JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Evidence of Rotational Fröhlich Coupling in Polaronic Trions

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