Ultrafast optical control of ferroelectric polarization via resonant magnon excitation
ORAL
Abstract
Optical control of order parameters in condensed matter is of great interest in fundamental as well as applied science. In the context of ferroic materials, controlling ferroic degrees of freedom using ultrafast optical pulses could pave the way towards ultrafast switches and devices that work on femtosecond timescales. Attempts to achieve this by direct excitation of ferroic modes have not been completely successful, necessitating other novel strategies.
In this work, we demonstrate a transient suppression of the ferroelectric polarization in the prototypical multiferroic BiFeO3 by resonant excitation of a magnon coupled to the ferroelectric mode. Ultrafast pump-probe measurements using a second harmonic generation probe reveal that the suppression and recovery of the polarization occur at a femtosecond timescale. Furthermore, we observe that the zero polarization transient state can be stabilized by tuning the domain structure of the lattice, increasing its lifetime by one order of magnitude.
In this work, we demonstrate a transient suppression of the ferroelectric polarization in the prototypical multiferroic BiFeO3 by resonant excitation of a magnon coupled to the ferroelectric mode. Ultrafast pump-probe measurements using a second harmonic generation probe reveal that the suppression and recovery of the polarization occur at a femtosecond timescale. Furthermore, we observe that the zero polarization transient state can be stabilized by tuning the domain structure of the lattice, increasing its lifetime by one order of magnitude.
*DOE Grant No. DE-SC0012375
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Presenters
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Haricharan Padmanabhan
- Pennsylvania State University