10 research outputs found
Unique Monotropic Phase Transition Behaviors of a Butterfly-Shaped Diphenylpyrimidine Molecule
The
physical properties of two-dimensional disc-shaped aromatic
carbon molecules strongly depend on the molecular packing structures.
A butterfly-shaped diphenylpyrimidine molecule (DPP-6C12) was synthesized
by covalently attaching two tridodecyl benzoate tails (6C12) at the
both sides of the diphenylpyrimidine (DPP) moiety. Unique phase transition
behaviors of DPP-6C12 and their origins were investigated with the
combined techniques of thermal, scattering, spectroscopic, and microscopic
analyses. On the basis of the experimental results and analyses, it
was realized that a butterfly-shaped DPP-6C12 formed three ordered
phases: a plastic crystal phase (PK), a crystal phase (K), and a liquid
crystal phase (Φ). By breaking the molecular symmetry and coplanarity
of DPP-6C12, peculiar monotropic phase transition behaviors were observed.
The stable Φ mesophase was formed either by a slow heating above
the metastable PK phase or by an isothermal annealing between <i>T</i><sub>Φ</sub> and <i>T</i><sub>K</sub>.
The stable K phase was only formed by a slow heating from the preordered
Φ mesophase, and the formation of the K phase directly from
the isotropic state (I) was forbidden because the nucleation barrier
from I to K was too high to be overcome via thermal annealing
Photopolymerization of Reactive Amphiphiles: Automatic and Robust Vertical Alignment Layers of Liquid Crystals with a Strong Surface Anchoring Energy
A photopolymerizable
itaconic acid-based amphiphile (abbreviated
as Ita3C<sub>12</sub>) consisting of a hydrophilic carboxylic acid,
three alkyl tails, and a reactive vinyl function was newly designed
and synthesized for the formation of automatic and robust vertical
alignment (VA) layer of nematic liquid crystals (NLC). Since a hydrophilic
carboxylic acid was chemically attached to the end of Ita3C<sub>12</sub>, the Ita3C<sub>12</sub> amphiphiles initially dissolved in the host
NLC medium were migrated toward the substrates for the construction
of VA layer of NLC. The alkyl tails of Ita3C<sub>12</sub> in the VA
layer directly interacted with host NLC molecules and made them to
automatically align vertically. Because of the reactive vinyl functions
of Ita3C<sub>12</sub> amphiphiles, it was possible to stabilize the
automatic VA layer by the photopolymerization with methacryl polyhedral
oligomeric silsesquioxane (MAPOSS) cross-linkers. The polymer-stabilized
robust Ita3C<sub>12</sub> VA layer exhibited a strong surface anchoring
energy without generating any light scatterings. The automatic fabrication
of robust LC alignment layers can allow us to reduce the manufacturing
cost and to open new doors for electro-optical applications
Photoresponsive Carbohydrate-based Giant Surfactants: Automatic Vertical Alignment of Nematic Liquid Crystal for the Remote-Controllable Optical Device
Photoresponsive carbohydrate-based
giant surfactants (abbreviated
as CELA<i><sub>n</sub></i>D-OH) were specifically designed
and synthesized for the automatic vertical alignment (VA) layer of
nematic (N) liquid crystal (LC), which can be applied for the fabrication
of remote-controllable optical devices. Without the conventional polymer-based
LC alignment process, a perfect VA layer was automatically constructed
by directly adding the 0.1 wt % CELA<sub>1</sub>D-OH in the N-LC media.
The programmed CELA<sub>1</sub>D-OH giant surfactants in the N-LC
media gradually diffused onto the substrates of LC cell and self-assembled
to the expanded monolayer structure, which can provide enough empty
spaces for N-LC molecules to crawl into the empty zones for the construction
of VA layer. On the other hand, the CELA<sub>3</sub>D-OH giant surfactants
forming the condensed monolayer structure on the substrates exhibited
a planar alignment (PA) rather than a VA. Upon tuning the wavelength
of light, the N-LC alignments were reversibly switched between VA
and PA in the remote-controllable LC optical devices. Based on the
experimental results, it was realized that understanding the interactions
between N-LC molecules and amphiphilic giant surfactants is critical
to design the suitable materials for the automatic LC alignment
Geometric Transformations Afforded by Rotational Freedom in Aramid Amphiphile Nanostructures
Molecular self-assembly in water
leads to nanostructure
geometries
that can be tuned owing to the highly dynamic nature of amphiphiles.
There is growing interest in strongly interacting amphiphiles with
suppressed dynamics, as they exhibit ultrastability in extreme environments.
However, such amphiphiles tend to assume a limited range of geometries
upon self-assembly due to the specific spatial packing induced by
their strong intermolecular interactions. To overcome this limitation
while maintaining structural robustness, we incorporate rotational
freedom into the aramid amphiphile molecular design by introducing
a diacetylene moiety between two aramid units, resulting in diacetylene
aramid amphiphiles (D-AAs). This design strategy enables rotations
along the carbon–carbon sp hybridized bonds
of an otherwise fixed aramid domain. We show that varying concentrations
and equilibration temperatures of D-AA in water lead to self-assembly
into four different nanoribbon geometries: short, extended, helical,
and twisted nanoribbons, all while maintaining robust structure with
thermodynamic stability. We use advanced microscopy, X-ray scattering,
spectroscopic techniques, and two-dimensional (2D) NMR to understand
the relationship between conformational freedom within strongly interacting
amphiphiles and their self-assembly pathways
Construction of Polymer-Stabilized Automatic MultiDomain Vertical Molecular Alignment Layers with Pretilt Angles by Photopolymerizing Dendritic Monomers under Electric Fields
The synthesized itaconic acid-based
dendritic amphiphile (Ita3C<sub>12</sub>) monomers and the methacryl
polyhedral oligomeric silsesquioxane
(MAPOSS) cross-linkers were directly introduced for the construction
of automatic vertical alignment (auto-VA) layers in the host nematic
liquid crystal (NLC) medium. The auto-VA layer can be stabilized by
irradiating UV light. For the automatic fabrication of a polymer-stabilized
multidomain VA (PS auto-MDVA) layer with a pretilt angle, Ita3C<sub>12</sub> and MAPOSS were photopolymerized under the electric field
by irradiating UV light on the multidomain electrode cell. Mainly
because of the pretilted NLC at zero voltage, the electro-optic properties
of the PS auto-MDVA cell were dramatically improved. From the morphological
observations combined with surface chemical analyses, it was found
that various sizes of protrusions on the solid substrates were automatically
constructed by the two-step mechanisms. We demonstrated the PS auto-MDVA
cell with the enhancement of electro-optic properties as a single-step
process and investigated how the protrusions were automatically developed
during the polymer stabilization
Pyrene-Based Asymmetric Supramolecule: Kinetically Controlled Polymorphic Superstructures by Molecular Self-Assembly
To
understand the kinetically controlled polymorphic superstructures
of asymmetric supramolecules, a pyrene-based asymmetric supramolecule
(abbreviated as Py3M) was newly synthesized by connecting two pyrene
headgroups (Py) to a biphenyl-based dendritic tail (3M) with an isoÂphthalaÂmide
connector. On the basis of thermal,
microscopic, spectroscopic, and scattering results, it was realized
that Py3M exhibited the monotropic phase transition between a stable
crystalline phase (K1) and a metastable crystalline phase (K2). This
monotropic phase transition behavior was mainly originated from the
competitions of intra- and intermolecular interactions (π–π
interactions and hydrogen bonds) as well as from the nanophase separations.
From the two-dimensional (2D) wide-angle X-ray diffraction patterns
and transmission electron microscopy images of the self-assembled
Py3M superstructures, it was found that Py3M formed two synclinically
tilted crystalline superstructures: the 6.75 and 4.4 nm periodicities
of layered structures for K1 and K2 phases, respectively. The stable
K1 phase was predominantly induced by the π–π interactions
between pyrenes, while the intermolecular hydrogen bonds between isoÂphthalaÂmides
were the main driving forces for the formation of the metastable K2
phase. Ultraviolet–visible and photoluminescence experiments
indicated that the photophysical properties of Py3M were directly
related to their molecular packing superstructures
Flexible and Patterned Thin Film Polarizer: Photopolymerization of Perylene-based Lyotropic Chromonic Reactive Mesogens
A perylene-based reactive mesogen
(DAPDI) forming a lyotropic chromonic liquid crystal (LCLC) phase
was newly designed and synthesized for the fabrication of macroscopically
oriented and patterned thin film polarizer (TFP) on the flexible polymer
substrates. The anisotropic optical property and molecular self-assembly
of DAPDI were investigated by the combination of microscopic, scattering
and spectroscopic techniques. The main driving forces of molecular
self-assembly were the face-to-face π–π intermolecular
interaction among aromatic cores and the nanophase separation between
hydrophilic ionic groups and hydrophobic aromatic cores. Degree of
polarization for the macroscopically oriented and photopolymerized
DAPDI TFP was estimated to be 99.81% at the <i><b>λ</b></i><sub>max</sub> = 491 nm. After mechanically shearing the
DAPDI LCLC aqueous solution on the flexible polymer substrates, we
successfully fabricated the patterned DAPDI TFP by etching the unpolymerized
regions selectively blocked by a photomask during the photopolymerization
process. Chemical and mechanical stabilities were confirmed by the
solvent and pencil hardness tests, and its surface morphology was
further investigated by optical microscopy, atomic force microscopy,
and three-dimensional surface nanoprofiler. The flexible and patterned
DAPDI TFP with robust chemical and mechanical stabilities can be a
stepping stone for the advanced flexible optoelectronic devices
Hierarchical Striped Walls Constructed by the Photopolymerization of Discotic Reactive Building Blocks in the Anisotropic Liquid Crystal Solvents
A triphenylene-based
reactive mesogenic molecule (abbreviated as
HABET) was newly designed and synthesized as a programmed building
block to construct the striped walls by the photopolymerization in
the anisotropic liquid crystal (LC) solvents. On the basis of thermal,
scattering and microscopic analyses, it was found that HABET formed
three ordered structures: a columnar hexagonal LC phase (Φ<sub>H</sub>), a tilted columnar hexagonal LC phase (Φ<sub>T</sub>) and a highly ordered columnar oblique crystal phase (Φ<sub>OK</sub>). The microscopic molecular orientations in the hierarchical
superstructures were controlled in the anisotropic LC solvents with
the help of surface anchoring forces, while the dimensions of the
striped wall morphologies were determined by the patterned photomasks.
The long axis of self-assembled columns in the striped walls was perpendicular
to the surface alignment direction regardless of the photomask direction.
Additionally, it was realized that the shapes of water drops as well
as the surface water contact angles can be tuned by the hierarchical
superstructures and morphologies of the polymerized HABET networks.
The anisotropic hierarchical superstructures and morphologies concurrently
fabricated during the polymerization in the anisotropic LC medium
can offer a potential pathway for liquid transportation in the microfluidic
devices
Azobenzene Molecular Machine: Light-Induced Wringing Gel Fabricated from Asymmetric Macrogelator
To develop light-triggered
wringing gels, an asymmetric macrogelator
(1AZ3BP) was newly synthesized by the chemically bridging a photoisomerizable
azobenzene (1AZ) molecular machine and a biphenyl-based (3BP) dendron
with a 1,4-phenylenediformamide connector. 1AZ3BP was self-assembled
into a layered superstructure in the bulk state, but 1AZ3BP formed
a three-dimensional (3D) network organogel in solution. Upon irradiating
UV light onto the 3D network organogel, the solvent of the organogel
was squeezed and the 3D network was converted to the layered morphology.
It was realized that the metastable 3D network organogels were fabricated
mainly due to the nanophase separation in solution. UV isomerization
of 1AZ3BP provided sufficient molecular mobility to form strong hydrogen
bonds for the construction of the stable layered superstructure. The
light-triggered wringing gels can be smartly applied in remote-controlled
generators, liquid storages, and sensors
Self-Assembled Hierarchical Superstructures from the Benzene-1,3,5-Tricarboxamide Supramolecules for the Fabrication of Remote-Controllable Actuating and Rewritable Films
The
well-defined hierarchical superstructures constructed by the self-assembly
of programmed supramolecules can be organized for the fabrication
of remote-controllable actuating and rewritable films. To realize
this concept, we newly designed and synthesized a benzene-1,3,5-tricarboxamide
(BTA) derivative (abbreviated as BTA-3AZO) containing photoresponsive
azobenzene (AZO) mesogens on the periphery of the BTA core. BTA-3AZO
was first self-assembled to nanocolumns mainly driven by the intermolecular
hydrogen-bonds between BTA cores, and these self-assembled nanocolumns
were further self-organized laterally to form the low-ordered hexagonal
columnar liquid crystal (LC) phase below the isotropization temperature.
Upon cooling, a lamello-columnar crystal phase emerged at room temperature
via a highly ordered lamello-columnar LC phase. The three-dimensional
(3D) organogel networks consisted of fibrous and lamellar superstructures
were fabricated in the BTA-3AZO cyclohexane-methanol solutions. By
tuning the wavelength of light, the shape and color of the 3D networked
thin films were remote-controlled by the conformational changes of
azobenzene moieties in the BTA-3AZO. The demonstrations of remote-controllable
3D actuating and rewritable films with the self-assembled hierarchical
BTA-3AZO thin films can be stepping stones for the advanced flexible
optoelectronic devices