4 research outputs found
Controlling the Structure of Supraballs by pH-Responsive Particle Assembly
Supraballs
of various sizes and compositions can be fabricated
via drying of drops of aqueous colloidal dispersions on super-liquid-repellent
surfaces with no chemical waste and energy consumption. A “supraball”
is a particle composed of colloids. Many properties, such as mechanical
strength and porosity, are determined by the ordering of a colloidal
assembly. To tune such properties, a colloidal assembly needs to be
controlled when supraballs are formed during drying. Here, we introduce
a method to control a colloidal assembly of supraballs by adjusting
the dispersity of the colloids. Supraballs are fabricated on superamphiphobic
surfaces from colloidal aqueous dispersions of polystyrene microparticles
carrying pH-responsive poly[2-(diethylamino)ethyl methacrylate]. Drying
of dispersion drops at pH 3 on superamphiphobic surfaces leads to
the formation of spherical supraballs with densely packed colloids.
The pH 10 supraballs are more oblate and consist of more disordered
colloids than the pH 3 supraballs, caused by particle aggregates with
random sizes and shapes in the pH 10 dispersion. Thus, the shape,
crystallinity, porosity, and mechanical properties could be controlled
by pH, which allows broader uses of supraballs
Controlling the Structure of Supraballs by pH-Responsive Particle Assembly
Supraballs
of various sizes and compositions can be fabricated
via drying of drops of aqueous colloidal dispersions on super-liquid-repellent
surfaces with no chemical waste and energy consumption. A “supraball”
is a particle composed of colloids. Many properties, such as mechanical
strength and porosity, are determined by the ordering of a colloidal
assembly. To tune such properties, a colloidal assembly needs to be
controlled when supraballs are formed during drying. Here, we introduce
a method to control a colloidal assembly of supraballs by adjusting
the dispersity of the colloids. Supraballs are fabricated on superamphiphobic
surfaces from colloidal aqueous dispersions of polystyrene microparticles
carrying pH-responsive poly[2-(diethylamino)ethyl methacrylate]. Drying
of dispersion drops at pH 3 on superamphiphobic surfaces leads to
the formation of spherical supraballs with densely packed colloids.
The pH 10 supraballs are more oblate and consist of more disordered
colloids than the pH 3 supraballs, caused by particle aggregates with
random sizes and shapes in the pH 10 dispersion. Thus, the shape,
crystallinity, porosity, and mechanical properties could be controlled
by pH, which allows broader uses of supraballs
Formation of Liquid Marbles Using pH-Responsive Particles: Rolling vs Electrostatic Methods
Aqueous
dispersions of micrometer-sized, monodisperse polystyrene
(PS) particles carrying pH-responsive poly[2-(diethylamino)ethyl methacrylate]
(PDEA) colloidal stabilizer on their surfaces were dried under ambient
conditions at pH 3.0 and 10.0. The resulting dried cake-like particulate
materials were ground into powders and used as a stabilizer to fabricate
liquid marbles (LMs) by rolling and electrostatic methods. The powder
obtained from pH 3.0 aqueous dispersion consisted of polydisperse
irregular-shaped colloidal crystal grains of densely packed colloids
which had hydrophilic character. On the other hand, the powder obtained
from pH 10.0 aqueous dispersion consisted of amorphous and disordered
colloidal aggregate grains with random sizes and shapes, which had
hydrophobic character. Reflecting the hydrophilic–hydrophobic
balance of the dried PDEA–PS particle powders, stable LMs were
fabricated with distilled water droplets by rolling on the powders
prepared from pH 10.0, but the water droplets were adsorbed into the
powders prepared from pH 3.0. In the electrostatic method, where an
electric field assists transport of powders to a droplet surface,
the PDEA–PS powders prepared from pH 3.0 jumped to an earthed
pendant distilled water droplet to form a droplet of aqueous dispersion.
Conversely the larger powder aggregates prepared from pH 10.0 did
not jump due to cohesion between the hydrophobic PDEA chains on the
PS particles, resulting in no LM formation
Formation of Liquid Marbles Using pH-Responsive Particles: Rolling vs Electrostatic Methods
Aqueous
dispersions of micrometer-sized, monodisperse polystyrene
(PS) particles carrying pH-responsive poly[2-(diethylamino)ethyl methacrylate]
(PDEA) colloidal stabilizer on their surfaces were dried under ambient
conditions at pH 3.0 and 10.0. The resulting dried cake-like particulate
materials were ground into powders and used as a stabilizer to fabricate
liquid marbles (LMs) by rolling and electrostatic methods. The powder
obtained from pH 3.0 aqueous dispersion consisted of polydisperse
irregular-shaped colloidal crystal grains of densely packed colloids
which had hydrophilic character. On the other hand, the powder obtained
from pH 10.0 aqueous dispersion consisted of amorphous and disordered
colloidal aggregate grains with random sizes and shapes, which had
hydrophobic character. Reflecting the hydrophilic–hydrophobic
balance of the dried PDEA–PS particle powders, stable LMs were
fabricated with distilled water droplets by rolling on the powders
prepared from pH 10.0, but the water droplets were adsorbed into the
powders prepared from pH 3.0. In the electrostatic method, where an
electric field assists transport of powders to a droplet surface,
the PDEA–PS powders prepared from pH 3.0 jumped to an earthed
pendant distilled water droplet to form a droplet of aqueous dispersion.
Conversely the larger powder aggregates prepared from pH 10.0 did
not jump due to cohesion between the hydrophobic PDEA chains on the
PS particles, resulting in no LM formation