Na@C composite anode for a stable Na|NZSP interface in solid-state Na–CO2 battery

“…The parasitic reactions between Na and NZSP give rise to a kinetically stable interphase. To address the problem, Tong et al developed a Na@C composite anode by mixing different amounts of carbon black with melted Na (melted at 300 °C for 30 min in a steel crucible) for their NZSP SSE and Ru/CNT cathode-based Na–CO 2 batteries . Na@C resulted in intimate contact with NZSP because of the significantly improved wettability with NZSP.…”

“…248,249 Tong et al used commercially available NZSP pellets for Na− CO 2 batteries. 151,250 They ascertained a good contact between the NZSP electrolyte and Ru/CNT cathode by using a succinonitrile-based solution prepared by coheating succinonitrile (92.5 wt %) and NaClO 4 (7.5 wt %). 151 Figure 22(a) depicts the monoclinic crystal unit cell of NZSP (space group C2/c).…”

“…Constructing a stable interface between the Na metal anode and solid-state electrolyte (SSE) has always been one of the major challenges in solid-state Na−CO 2 batteries owing to the instability of the SSE toward Na. 241 Tong et al 250 utilized NZSP as the SSE. From the grazing incidence X-ray diffraction (GIXRD) results, they observed that the (200) and (−111) faces are the most likely to be etched in NZSP.…”

“…From the grazing incidence X-ray diffraction (GIXRD) results, they observed that the (200) and (−111) faces are the most likely to be etched in NZSP. The (200) and 250 Na@C resulted in intimate contact with NZSP because of the significantly improved wettability with NZSP. Utilization of Na@C remarkably reduced the interfacial resistance from 918 to 98 Ω cm 2 .…”

Recent Advances in Rechargeable Metal–CO₂ Batteries with Nonaqueous Electrolytes

“…The parasitic reactions between Na and NZSP give rise to a kinetically stable interphase. To address the problem, Tong et al developed a Na@C composite anode by mixing different amounts of carbon black with melted Na (melted at 300 °C for 30 min in a steel crucible) for their NZSP SSE and Ru/CNT cathode-based Na–CO 2 batteries . Na@C resulted in intimate contact with NZSP because of the significantly improved wettability with NZSP.…”

“…248,249 Tong et al used commercially available NZSP pellets for Na− CO 2 batteries. 151,250 They ascertained a good contact between the NZSP electrolyte and Ru/CNT cathode by using a succinonitrile-based solution prepared by coheating succinonitrile (92.5 wt %) and NaClO 4 (7.5 wt %). 151 Figure 22(a) depicts the monoclinic crystal unit cell of NZSP (space group C2/c).…”

“…Constructing a stable interface between the Na metal anode and solid-state electrolyte (SSE) has always been one of the major challenges in solid-state Na−CO 2 batteries owing to the instability of the SSE toward Na. 241 Tong et al 250 utilized NZSP as the SSE. From the grazing incidence X-ray diffraction (GIXRD) results, they observed that the (200) and (−111) faces are the most likely to be etched in NZSP.…”

“…From the grazing incidence X-ray diffraction (GIXRD) results, they observed that the (200) and (−111) faces are the most likely to be etched in NZSP. The (200) and 250 Na@C resulted in intimate contact with NZSP because of the significantly improved wettability with NZSP. Utilization of Na@C remarkably reduced the interfacial resistance from 918 to 98 Ω cm 2 .…”

Recent Advances in Rechargeable Metal–CO₂ Batteries with Nonaqueous Electrolytes

“…A solid-state electrolyte matched with sodium metal is regarded as a potential solution to improve the performance of liquid-electrolyte-based sodium-ion batteries in terms of safety, energy density, and cost. − Among various solid-state electrolytes, NASICON electrolytes have attracted much attention due to their high ionic conductivity, chemical stability, and high mechanical strength. − Nevertheless, several challenges still remain with regard to the NASICON/Na interface, including a large interface resistance, drastic fluctuation of interface resistance, and dendrite growth. , …”

Insight into the Evolution of Voids at the NASICON/Na Interface and Suppressing Void Accumulation by a Semiliquid Wetting Strategy

Interface issues and challenges for NASICON-based solid-state sodium-metal batteries