Optically
driven ordering transitions are rarely observed in macromolecular
systems, often because of kinetic limitations. Here, we report a series
of block co-oligomers (BCOs) that rapidly order and disorder at room
temperature in response to optical illumination, and the absence thereof.
The system is a triblock where rigid azobenzene (Azo) mesogens are
attached to each end of a flexible siloxane chain. UV-induced trans-to-cis
Azo isomerization, and vice versa in the absence
of UV light, drive disordering and ordering of lamellar superstructures
and smectic mesophases, as manifested by liquefaction and solidification
of the material, respectively. The impacts of chemical structure on
BCO self-assembly and photoswitching kinetics are explored by in situ microscopy and X-ray measurements for different
mesogen end groups (NO2 or CN), and different carbon chain
lengths (0C or 12C) between the siloxane and the mesogen. The presence
of the 12C spacer leads to hierarchical ordering with smectic layers
of mesogens existing alongside larger length-scale lamellae, versus
only smectic ordering without the spacer. These hierarchically ordered
BCOs display highly persistent lamellar sheets that contrast with
the tortuous, low-persistence “fingerprint”-type structures
seen in conventional block copolymers. The reordering kinetics upon
removal of UV illumination are extremely rapid (<5 s). This fast
response is due to the electron-withdrawing NO2 and CN,
which facilitate cis-to-trans isomerization via thermal relaxation
at room temperature without additional stimuli. This work elucidates
structure–property relationships in photoswitching BCOs and
advances the possibility of developing systems in which ordered nanostructures
can be easily optically written and erased.
The fabrication of mechanically robust nanoporous polymeric membrane materials with aligned, accessible functionalized nanopores is extremely important for many applications.
This review describes recent progress made in designing stimuli-responsive, functional, side-chain, end-on mesogen attached liquid crystalline polymers (LCPs). Developments in synthetic methodologies including controlled and living techniques provides an easy...
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