2 research outputs found
Structural Dynamics of the Electrical Double Layer during Capacitive Charging/Discharging Processes
Transitional
structures of Cs<sup>+</sup> at the outer Helmholtz plane (OHP) have
been determined using time-resolved X-ray diffraction during the double-layer
charging/discharging on the Ag(100) electrode in CsBr solution. At
the double-layer potential region at which c(2 × 2)-Br is formed
on Ag(100), the transient current comprises two exponential terms
with different time scales: a rapid and a slow one are due to the
dielectric polarization of water molecules and the transfer of Cs<sup>+</sup>, respectively. The slow term is composed of different dynamic
processes of Cs<sup>+</sup> during charging and discharging. When
the potential is stepped in the positive direction, the coverage of
Cs<sup>+</sup> at the OHP decreases. In this step, the transient X-ray
intensity at the (0 0 1) reflection, which is sensitive to the OHP
structure, shows that Cs<sup>+</sup> is released from the OHP according
to exponential function of time. The decay of transient intensity
of X-ray has a time scale similar to that of the current transient
measurement. On the other hand, the accumulation process of Cs<sup>+</sup> from the diffuse double layer to the OHP comprises two different
kinetic processes after a potential step in the negative direction:
a rapid one is the accumulation of Cs<sup>+</sup> near the outer layer,
and a slow one is the structural stabilization of the Cs<sup>+</sup> layer
Air/Liquid Interfacial Nanoassembly of Molecular Building Blocks into Preferentially Oriented Porous Organic Nanosheet Crystals <i>via</i> Hydrogen Bonding
Nanosheets with highly regulated
nanopores are ultimately thin
functional materials for diverse applications including molecular
separation and detection, catalysis, and energy conversion and storage.
However, their availability has hitherto been restricted to layered
parent materials, covalently bonded sheets, which are layered <i>via</i> relatively weak electrostatic interactions. Here, we
report a rational bottom-up methodology that enables nanosheet creation
beyond the layered systems. We employ the air/liquid interface to
assemble a triphenylbenzene derivative into perfectly oriented highly
crystalline noncovalent-bonded organic nanosheets under ambient conditions.
Each molecular building unit connects laterally by hydrogen bonding,
endowing the nanosheets with size- and position-regulated permanent
nanoporosity, as established by <i>in situ</i> synchrotron
X-ray surface crystallography and gas sorption measurements. Notably,
the nanosheets are constructed specifically by interfacial synthesis,
which suppresses the intrinsic complex interpenetrated structure of
the bulk crystal. Moreover, they possess exceptional long-term and
thermal stability and are easily transferrable to numerous substrates
without loss of structural integrity. Our work shows the power of
interfacial synthesis using a suitably chosen molecular component
to create two-dimensional (2D) nanoassemblies not accessible by conventional
bulk crystal exfoliation techniques