1 research outputs found
Antimony-Coated Carbon Nanocomposites as High-Performance Anode Materials for High-Temperature Sodium–Metal Batteries
Metallic sodium (Na) possesses several advantageous characteristics,
including a high theoretical specific capacity, low electrode potential,
and availability in abundance, making it an ideal anode material for
sodium–metal batteries (SMBs). However, the practical use of
Na metal anodes is severely impeded due to the uncontrolled formation
of dendrites due to the slow electrochemical kinetics and chemical
instability of the formed solid-electrolyte interphase (SEI) layer.
This situation can worsen considerably under high-temperature (HT)
conditions (>55 °C). To overcome this issue, we have fabricated
a thermally stable antimony (Sb)-coated carbon (Sb@C) nanocomposite
as a sodium host material, where Sb nanoparticles are encapsulated
within the carbon layers. This unique nanostructure controls vaporization
during the plating-stripping process and dendrite formation and provides
acceptor sites for Na+ ions. The Sb@C electrode exhibits
an extended life span of symmetrical cycles (2400 h at 1 mA cm–2) due to the abundant nucleation sites. It maintains
a low nucleation overpotential (∼15 mV), enhancing its performance
and long cycle stability. Moreover, the in situ formed Na–Sb
synergistically offers durable ionic/electronic diffusion paths and
chemically interacts with Na, forming abundant Na nucleation sites.
Therefore, in this study, we emphasize the importance of the rational
design of highly stable alloys and present an effective strategy for
achieving high-performance sodium–metal anodes