<p>The recent discovery of ferroelectric nematic liquid crystals (FNLCs) has led to exciting materials which combine polar long-range orientational order and giant spontaneous electric polarization <b>P</b><sub><b>s</b></sub> with 3D fluidity. While this fluidity opens new perspectives for directional control of <b>P</b><sub><b>s</b></sub> in space and time, it also requires confinement of FNLCs. We investigate whether and how ferroelectric nematics might be confined as a cylindrical core in a hollow polymer fiber by coaxial electrospinning and whether the ferroelectric order is preserved in this process. We find that it is, in fact, exceptionally easy to spin fibers with a continuous FNLC core, because the polarization stiffening effect counteracts the Rayleigh-Plateau instability. Polarization-resolved second-harmonic generation measurements reveal that the polar order is preserved in the core. While in thin fibers with a core diameter on the order of 1 μm, <b>P</b><sub><b>s</b></sub> is uniformly aligned along the fiber axis, we find a twist of <b>P</b><sub><b>s</b></sub> along the diameter in thicker fibers. The latter is analyzed in light of the current debate on the twisted ground states of ferroelectric nematics. The confinement of FNLCs in macroscopically polar fibers offers new research opportunities and might be an important step toward application in, e.g., actuators or energy harvesting devices.</p>

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Electrospun fibers with axially polarized ferroelectric nematic core

  • Tom Ott,
  • Pierre Nacke,
  • Betül Küçüköz,
  • George Zograf,
  • Timur Shegai,
  • Frank Giesselmann,
  • Jan P. F. Lagerwall,
  • Per Rudquist

摘要

The recent discovery of ferroelectric nematic liquid crystals (FNLCs) has led to exciting materials which combine polar long-range orientational order and giant spontaneous electric polarization Ps with 3D fluidity. While this fluidity opens new perspectives for directional control of Ps in space and time, it also requires confinement of FNLCs. We investigate whether and how ferroelectric nematics might be confined as a cylindrical core in a hollow polymer fiber by coaxial electrospinning and whether the ferroelectric order is preserved in this process. We find that it is, in fact, exceptionally easy to spin fibers with a continuous FNLC core, because the polarization stiffening effect counteracts the Rayleigh-Plateau instability. Polarization-resolved second-harmonic generation measurements reveal that the polar order is preserved in the core. While in thin fibers with a core diameter on the order of 1 μm, Ps is uniformly aligned along the fiber axis, we find a twist of Ps along the diameter in thicker fibers. The latter is analyzed in light of the current debate on the twisted ground states of ferroelectric nematics. The confinement of FNLCs in macroscopically polar fibers offers new research opportunities and might be an important step toward application in, e.g., actuators or energy harvesting devices.