Dynamical decoupling and recoupling of the Wigner solid to a liquid helium substrate

David G. Rees; Sheng-Shiuan Yeh; Ban-Chen Lee; Simon K. Schnyder; Francis I. B. Williams; Juhn-Jong Lin; Kimitoshi Kono

doi:10.1103/PhysRevB.102.075439

Dynamical decoupling and recoupling of the Wigner solid to a liquid helium substrate

David G. Rees, Sheng-Shiuan Yeh, Ban-Chen Lee, Simon K. Schnyder, Francis I. B. Williams, Juhn-Jong Lin, Kimitoshi Kono^*

^*Corresponding author for this work

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

6 Scopus citations

Abstract

We investigate the dynamical interaction between an electron crystal trapped above the surface of liquid helium and surface waves ('ripplons') excited by its motion. At rest, the electron system is 'dressed' by static ripplons to form 'ripplopolaron' states. As the electrons move, resonant ripplon scattering results in a growth of the ripplopolaron effective mass, on timescales comparable with the inverse of the ripplon frequency (similar to 100 ns). Under sufficient driving force, the electron system decouples from the surface waves and moves at high velocity, before decelerating sharply when the electron solid and surface excitations recouple to form a 'new' ripplopolaron system. The mass of the newly formed ripplopolarons is similar to that in the initial static case.

Original language	English
Article number	075439
Pages (from-to)	1-6
Number of pages	6
Journal	Physical Review B
Volume	102
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevB.102.075439
State	Published - 24 Aug 2020

Keywords

2-DIMENSIONAL ELECTRONS
NONLINEAR CONDUCTIVITY
SURFACE
POLARONS
CRYSTAL
TRANSITIONS
STABILITY
STATE

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10.1103/PhysRevB.102.075439

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title = "Dynamical decoupling and recoupling of the Wigner solid to a liquid helium substrate",

abstract = "We investigate the dynamical interaction between an electron crystal trapped above the surface of liquid helium and surface waves ('ripplons') excited by its motion. At rest, the electron system is 'dressed' by static ripplons to form 'ripplopolaron' states. As the electrons move, resonant ripplon scattering results in a growth of the ripplopolaron effective mass, on timescales comparable with the inverse of the ripplon frequency (similar to 100 ns). Under sufficient driving force, the electron system decouples from the surface waves and moves at high velocity, before decelerating sharply when the electron solid and surface excitations recouple to form a 'new' ripplopolaron system. The mass of the newly formed ripplopolarons is similar to that in the initial static case.",

keywords = "2-DIMENSIONAL ELECTRONS, NONLINEAR CONDUCTIVITY, SURFACE, POLARONS, CRYSTAL, TRANSITIONS, STABILITY, STATE",

author = "Rees, {David G.} and Sheng-Shiuan Yeh and Ban-Chen Lee and Schnyder, {Simon K.} and Williams, {Francis I. B.} and Juhn-Jong Lin and Kimitoshi Kono",

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doi = "10.1103/PhysRevB.102.075439",

language = "English",

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journal = "Physical Review B",

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AU - Rees, David G.

AU - Yeh, Sheng-Shiuan

AU - Lee, Ban-Chen

AU - Schnyder, Simon K.

AU - Williams, Francis I. B.

AU - Lin, Juhn-Jong

AU - Kono, Kimitoshi

PY - 2020/8/24

Y1 - 2020/8/24

N2 - We investigate the dynamical interaction between an electron crystal trapped above the surface of liquid helium and surface waves ('ripplons') excited by its motion. At rest, the electron system is 'dressed' by static ripplons to form 'ripplopolaron' states. As the electrons move, resonant ripplon scattering results in a growth of the ripplopolaron effective mass, on timescales comparable with the inverse of the ripplon frequency (similar to 100 ns). Under sufficient driving force, the electron system decouples from the surface waves and moves at high velocity, before decelerating sharply when the electron solid and surface excitations recouple to form a 'new' ripplopolaron system. The mass of the newly formed ripplopolarons is similar to that in the initial static case.

AB - We investigate the dynamical interaction between an electron crystal trapped above the surface of liquid helium and surface waves ('ripplons') excited by its motion. At rest, the electron system is 'dressed' by static ripplons to form 'ripplopolaron' states. As the electrons move, resonant ripplon scattering results in a growth of the ripplopolaron effective mass, on timescales comparable with the inverse of the ripplon frequency (similar to 100 ns). Under sufficient driving force, the electron system decouples from the surface waves and moves at high velocity, before decelerating sharply when the electron solid and surface excitations recouple to form a 'new' ripplopolaron system. The mass of the newly formed ripplopolarons is similar to that in the initial static case.

KW - 2-DIMENSIONAL ELECTRONS

KW - NONLINEAR CONDUCTIVITY

KW - SURFACE

KW - POLARONS

KW - CRYSTAL

KW - TRANSITIONS

KW - STABILITY

KW - STATE

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U2 - 10.1103/PhysRevB.102.075439

DO - 10.1103/PhysRevB.102.075439

M3 - Article

SN - 2469-9950

VL - 102

SP - 1

EP - 6

JO - Physical Review B

JF - Physical Review B

IS - 7

M1 - 075439

ER -

Dynamical decoupling and recoupling of the Wigner solid to a liquid helium substrate

Abstract

Keywords

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