Balancing
interfacial stability and Li+ transfer kinetics
through surface engineering is a key challenge in developing high-performance
battery materials. Although conformal coating enabled by atomic layer
deposition (ALD) has shown great promise in controlling impedance
increase upon cycling by minimizing side reactions at the electrode–electrolyte
interface, the coating layer itself usually exhibits poor Li+ conductivity and impedes surface charge transfer. In this work,
we have shown that by carefully controlling postannealing temperature
of an ultrathin ZrO2 film prepared by ALD, Zr4+ surface doping could be achieved for Ni-rich layered oxides to accelerate
the charge transfer yet provide sufficient protection. Using single-crystal
LiNi0.6Mn0.2Co0.2O2 as
a model material, we have shown that surface Zr4+ doping
combined with ZrO2 coating can enhance both the cycle performance
and rate capability during high-voltage operation. Surface doping
via controllable postannealing of ALD surface coating layer reveals
an attractive path toward developing stable and Li+-conductive
interfaces for single-crystal battery materials.
Electrochromic energy storage devices (EESDs) are incorporating electrochromic and energy storage functions, which can visually display energy storage levels in real-time to promote the next generation of transparent battery development. However, their performances are still limited for practical applications. Herein, a self-powered EESD based on complex niobium tungsten oxide is designed using aqueous Zn 2+ and hybrid Zn 2+ /M n+ (M n+ = Al 3+ , Mg 2+ , and K + ) electrolytes. The results reveal that the use of Zn 2+ /Al 3+ hybrid electrolyte achieves superior electrochromic performances including a short self-coloring time, high optical contrast, and excellent cyclic stability. Furthermore, it is also found that the self-coloring process is accompanied by a high discharged capacity of niobium tungsten oxide, with high optical modulation in the Zn 2+ /Al 3+ hybrid electrolyte. The detailed mechanism on the performances of EESD using various electrolytes is systematically studied. This work provides a simple and effective strategy for an aqueous and self-powered EESD with high optical contrast and good cycle stability.
Thin
films with effective ion sieving ability are highly desired
in energy storage and conversion devices, including batteries and
fuel cells. However, it remains challenging to design and fabricate
cost-effective and easy-to-process ultrathin films for this purpose.
Here, we report a 300 nm-thick functional layer based on porous organic
cages (POCs), a new class of porous molecular materials, for fast
and selective ion transport. This solution processable material allows
for the design of thin films with controllable thickness and tunable
porosity by tailoring cage chemistry for selective ion separation.
In the prototype, the functional layer assembled by CC3 can selectively
sieve Li+ ions and efficiently suppress undesired polysulfides
with minimal sacrifice for the system’s total energy density.
Separators modified with POC thin films enable batteries with good
cycle performance and rate capability and offer an attractive path
toward the development of future high-energy-density energy storage
devices.
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