Molecular Technology for Chirality Control: From Structure to Circular Polarization

“…In fact, the wavelength, intensity and polarization of the random laser in NLCs can be controlled by electrical [16][17][18][19], thermal [13,20] and magnetic [19] stimuli, and the alignment of LC cells [15,21]. In particular, the optical switching owing to the molecular reorientation in a magnetic field [22] has some advantages in remote operability [8]. However, to reorient the nematic director using a weak magnetic field, high magnetic anisotropy ∆ χ of the LC molecule is needed [23,24], which is defined as the subtraction of the molar magnetic susceptibility component ( χ ⊥ ) perpendicular to the molecular long axis from that ( χ ) parallel to the axis [25].…”

Magnetically controllable random laser in ferromagnetic nematic liquid crystals

“…In fact, the wavelength, intensity and polarization of the random laser in NLCs can be controlled by electrical [16][17][18][19], thermal [13,20] and magnetic [19] stimuli, and the alignment of LC cells [15,21]. In particular, the optical switching owing to the molecular reorientation in a magnetic field [22] has some advantages in remote operability [8]. However, to reorient the nematic director using a weak magnetic field, high magnetic anisotropy ∆ χ of the LC molecule is needed [23,24], which is defined as the subtraction of the molar magnetic susceptibility component ( χ ⊥ ) perpendicular to the molecular long axis from that ( χ ) parallel to the axis [25].…”

Magnetically controllable random laser in ferromagnetic nematic liquid crystals

Circularly polarized luminescence of achiral open-shell π-radicals