Transparent,
Superhydrophobic Surface with Varied Surface Tension Responsiveness
in Wettability Based on Tunable Porous Silica Structure for Gauging
Liquid Surface Tension
posted on 2017-01-10, 00:00authored byYan Wang, Yingjie Zhu, Chunyang Zhang, Jun Li, Zisheng Guan
Any solid surface
can spontaneously exhibit variational wettability toward liquids with
varied surface tension (γ). However, this correspondence has
seldom been proposed or used on an artificial superhydrophobic surface,
which should be more remarkable and peculiar. Herein, we fabricated
robust, transparent superhydrophobic surfaces utilizing acid- and
base-catalyzed silica (AC- and BC-silica) particles combined with
candle soot template for structural construction and the CVD process
for chemical modification. Three types of porous silica structures
were devised, which presented distinctive surface tension responsiveness
in wettability. Interestingly, all types of surfaces (i.e., AC-, AC/BC-,
and BC-silica) show high repellence to high surface tension liquid
(γ > 35 mN/m), and small differences are observed. With decreasing
γ of the ethanol–water mixtures (γ < 35 mN/m),
the static contact angles (SCAs) on all surfaces have an evident decline,
but the features of the decreases are fairly different. As γ
decreases, the SCA on the AC-silica surface decreases gradually, but
the extent of decline becomes larger when γ < 27.42 mN/m.
However, the SCA on the BC-silica surface decreases gradually except
for γ ≈ 30.81 mN/m, and the SCA undergoes a sharp decline
at γ ≈ 30.81 mN/m. The SCA on the AC/BC-silica surface
has a similar variation as that of the SCA on the BC-silica surface,
but a lower rate of BC-silica particles, e.g., 1/16, 1/8, 1/1 (AC/BC),
further diminishes the critical γ values (where a sharp SCA
drop occurs) to 30.16, 29.56, and 28.04 mN/m, respectively. The diversity
is believed to be ascribed to the structure-induced selectivity of
pore infiltration for the liquid. The tunable responsiveness can be
generalized to various classes of organic aqueous solutions including
methanol, acetic acid, acetone, and N,N-dimethylformamide. Benefiting from this, we can estimate organics
concentration of an organic aqueous solution as well as its liquid
surface tension by detecting its wettability on all of the diverse
superhydrophobic surfaces.