The development of highly efficient catalysts in the cathodes of rechargeable Li−O 2 batteries is a considerable challenge. Polyelemental catalysts consisting of two or more kinds of hybridized catalysts are particularly interesting because the combination of the electrochemical properties of each catalyst component can significantly facilitate oxygen evolution and oxygen reduction reactions. Despite the recent advances that have been made in this field, the number of elements in the catalysts has been largely limited to two metals. In this study, we demonstrate the electrochemical behavior of Li−O 2 batteries containing a wide range of catalytic element combinations. Fourteen different combinations with single, binary, ternary, and quaternary combinations of Pt, Pd, Au, and Ru were prepared on carbon nanofibers (CNFs) via a joule heating route. Importantly, the Li−O 2 battery performance could be significantly improved when using a polyelemental catalyst with four elements. The cathode containing quaternary nanoparticles (Pt−Pd−Au−Ru) exhibited a reduced overpotential (0.45 V) and a high discharge capacity based on total cathode weight at 9130 mAh g −1 , which was ∼3 times higher than that of the pristine CNF electrode. This superior electrochemical performance is be attributed to an increased catalytic activity associated with an enhanced O 2 adsorbability by the quaternary nanoparticles.
Nanocomposites of crystalline-controlled TiO(2) -carbon are prepared by a novel one-step approach and applied in anodes of lithium ion batteries. In our nanocomposite anodes, the Li(+) capacity contribution from the TiO(2) phase was enormous, above 400 mAh g(-1) (Li(1+x) TiO(2) , x>0.2), and the volumetric capacity was as high as 877 mAh cm(-3) with full voltage utilization to 0 V versus Li/Li(+) , which resulted in higher energy density than that of state-of-the-art titania anodes. For the first time, it was clearly revealed that the capacity at 1.2 and 2.0 V corresponded to Li(+) storage at amorphous and crystalline TiO(2) , respectively. Furthermore, improvements in the rate capability and cycle performance were observed; this was attributed to resistance reduction induced by higher electrical/Li(+) conduction and faster Li(+) diffusion.
The
rechargeable Li–CO2 battery has attracted
considerable attention in recent years because of its carbon dioxide
(CO2) utilization and because it represents a practical
Li–air battery. As with other battery systems such as the Li-ion,
Li–O2, and Li–S battery systems, understanding
the reaction pathway is the first step to achieving high battery performance
because the performance is strongly affected by reaction intermediates.
Despite intensive efforts in this area, the effect of material parameters
(e.g., the electrolyte, the cathode, and the catalyst) on the reaction
pathway in Li–CO2 batteries is not yet fully understood.
Here, we show for the first time that the discharge reaction pathway
of a Li–CO2 battery composed of graphene nanoplatelets/beta
phase of molybdenum carbide (GNPs/β-Mo2C) is strongly
influenced by the dielectric constant of its electrolyte. Calculations
using the continuum solvents model show that the energy of adsorption
of oxalate (C2O4
2–) onto Mo2C under the low-dielectric electrolyte tetraethylene glycol
dimethyl ether is lower than that under the high-dielectric electrolyte N,N-dimethylacetamide (DMA), indicating
that the electrolyte plays a critical role in determining the reaction
pathway. The experimental results show that under the high-dielectric
DMA electrolyte, the formation of lithium carbonate (Li2CO3) as a discharge product is favorable because of the
instability of the oxalate species, confirming that the dielectric
properties of the electrolyte play an important role in the formation
of the discharge product. The resulting Li–CO2 battery
exhibits improved battery performance, including a reduced overpotential
and a remarkable discharge capacity as high as 14,000 mA h g–1 because of its lower internal resistance. We believe that this work
provides insights for the design of Li–CO2 batteries
with enhanced performance for practical Li–air battery applications.
Despite
the extremely high energy density of the lithium metal,
dendritic lithium growth caused by nonuniform lithium deposition can
result in low Coulombic efficiency and safety hazards, thereby inhibiting
its practical applications. Here, we report a new strategy for adopting
a nanopatterned gold (Au) seed on a copper current collector for uniform
lithium deposition. We find that Au nanopatterns enhance lithium metal
battery performance, which is strongly affected by the feature dimensions
of Au nanopatterns (diameter and height). Ex situ scanning electron microscopy images confirm that this can be attributed
to the perfectly selective lithium nucleation and uniform growth resulting
from the spatial confinement effect. The spatial arrangement of Au
dot seeds homogenizes the Li+ flux and electric field,
and the size-controlled Au seeds prevent both seed-/substrate-induced
agglomeration and interseed-induced lithium growth, leading to uniform
lithium deposition. This dendrite-free lithium deposition results
in the improvement of electrochemical performance, and the system
showed cyclic stability over 300 cycles at 0.5 mA cm–2 and 200 cycles at 1.0 mA cm–2 (1 mA h cm–2) and a high rate capability. This study provides in-depth insights
into the more complicated and diverse seed geometry control of seed
materials for the development of high-performance lithium metal batteries.
Solid-state
lithium batteries have been intensively studied as
part of research activities to develop energy storage systems with
high safety and stability characteristics. Despite the advantages
of solid-state lithium batteries, their application is currently limited
by poor reversible capacity arising from their high resistance. In
this study, we significantly improve the reversible capacity of solid-state
lithium batteries by lowering the resistance through the introduction
of a graphene and wrinkle structure on the surface of the copper (Cu)
current collector. This is achieved through a process of chemical
vapor deposition (CVD) facilitating graphene-growth synthesis. The
modified graphene/wrinkled Cu current collector exhibits a periodic
wrinkled pattern 420 nm in width and 22 nm in depth, and we apply
it to a graphite composite electrode to obtain an improved areal loading
average value of ∼2.5 mg cm–2. The surface-modified
Cu current collector is associated with a significant increase in
discharge capacity of 347 mAh g–1 at 0.2 C when
used with a solid polymer electrolyte. Peel test results show that
the observed enhancement is due to the improved strength of adhesion
occurring between the graphite composite anode and the Cu current
collector, which is attributed to mechanical interlocking. The surface-modified
Cu current collector structure effectively reduces resistance by improving
adhesion, which subsequently improves the performance of the solid-state
lithium batteries. Our study can provide perspective and emphasize
the importance of electrode design in achieving enhancements in battery
performance.
Ti(3+) self-doped TiO2 nanoparticles were prepared via a simple imidazole reduction process and developed as an anode material for Li-ion batteries. Introducing the Ti(3+)-state on TiO2 nanoparticles resulted in superior rate performances that the capacity retention of 88% at 50 C. The enhanced electrochemical performances were attributed to the resulting lower internal resistance and improved electronic conductivity, based on galvanostatic intermittent titration technique and electrochemical impedance spectroscopy analyses.
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