The dispersion and tunable alignment of colloidal nanomaterials
is desirable for practical applications in electric–optic (E–O)
devices; however, it remains challenging for large one-dimensional
nanomaterials with a large aspect ratio. Here, we demonstrate a large-scale,
simple, multi-microdomain, and noncontact photoalignment technology
to align colloidal silver nanowires (AgNWs, length ∼4.5 μm,
diameter ∼70.6 nm) in a liquid crystal (LC) with a high two-dimensional
order parameter (about 0.9). The AgNWs are precisely self-assembled
via photomasks with twisted nematic and planar alignment models in
microdomain regions. The AgNW orientation is tuned with an electric
field, through the rotation of an LC director n, which
allows three-dimensional (3D) tunable orientation combined with photoalignment.
The colloidal dispersions of AgNWs in the LC cell influenced the ion
transfer, elastic constant, dielectric anisotropy, and near LC alignment,
changing the E–O properties of the LC devices. The 3D tunable
orientation of an AgNW by photoalignment and an electric field could
provide a new way to assemble large colloidal nanomaterials and fabricate
functional E–O devices.