Capacity Enhancement and Discharge Mechanisms of Room‐Temperature Sodium–Sulfur Batteries

Abstract: A strategy for capacity and cyclability enhancement of roomtemperature sodium-sulfur (Na-S) batteries is reported by inserting a nanostructured, carbon-based interlayer between the sulfur cathode and the separator. The interlayer localizes the soluble polysulfide species and prevents its migration to the sodium anode. Electrochemical and spectroscopic characterizations along with thermodynamic analyses indicate that the charge/discharge of the Na-S cell involves complicated transition processes through a serie… Show more

“…The diffusion of sodium ions would be low due to the highly localized and viscous sodium polysulfides formed around unreacted Na 2 S. This kinetic barrier accounts for the long charge time in the first charge. The first discharge, as well as the subsequent discharge, shows two voltage plateaus, which are similar to those of conventional sulfur–carbon composite electrodes4k (Figure S2 in the Supporting Information). The subsequent charge shows a complete two‐plateau charging process unlike the first charge, indicating the discharged product is much more active than the pristine Na 2 S within the MWCNT electrode.…”

“…However, operation of a Na–S battery at room temperature faces much more challenges than Li–S batteries, especially in terms of utilization of the sulfur active material and capacity fade during cycling. Recently, quite a few advances have been made towards improving the overall performances of the RT Na–S batteries, such as advanced sulfur–carbon cathode nanomaterials,4g, i unique cell configuration structures,4h, k, l smart cycling strategies,4j etc. In all of these previous studies, the RT Na–S cells were fabricated in a fully charged state with sulfur as the starting cathode material.…”

Na₂S–Carbon Nanotube Fabric Electrodes for Room‐Temperature Sodium–Sulfur Batteries

“…The diffusion of sodium ions would be low due to the highly localized and viscous sodium polysulfides formed around unreacted Na 2 S. This kinetic barrier accounts for the long charge time in the first charge. The first discharge, as well as the subsequent discharge, shows two voltage plateaus, which are similar to those of conventional sulfur–carbon composite electrodes4k (Figure S2 in the Supporting Information). The subsequent charge shows a complete two‐plateau charging process unlike the first charge, indicating the discharged product is much more active than the pristine Na 2 S within the MWCNT electrode.…”

“…However, operation of a Na–S battery at room temperature faces much more challenges than Li–S batteries, especially in terms of utilization of the sulfur active material and capacity fade during cycling. Recently, quite a few advances have been made towards improving the overall performances of the RT Na–S batteries, such as advanced sulfur–carbon cathode nanomaterials,4g, i unique cell configuration structures,4h, k, l smart cycling strategies,4j etc. In all of these previous studies, the RT Na–S cells were fabricated in a fully charged state with sulfur as the starting cathode material.…”

Na₂S–Carbon Nanotube Fabric Electrodes for Room‐Temperature Sodium–Sulfur Batteries

“…Table S3 summarizes the different poly(sulfide)s formed during discharge together with the corresponding voltage at which they are formed. [35][36][37][38] Upon discharge, S/ACF in 1M LiTFSI in DME/DOL as electrolyte shows a maximum in the range of 2.3-2.4 V, which correspond to long-chain poly(sulfide)s, i.e. Li 2 S 8 and Li 2 S 4 , respectively.…”

Differences in Electrochemistry between Fibrous SPAN and Fibrous S/C Cathodes Relevant to Cycle Stability and Capacity

“…In a typical discharge process, the electrons in the external circuit are captured by sulfur cathode through a two-step reduction reaction with Li + /Na + : a higher reduction process corresponding to conversion of cyclo-S 8 to high-order polysulfides (M 2 S x , 4 ≤ x ≤ 8, M = Li, Na), and a lower reduction process involving the conversion of M 2 S x to lower-order species, which are assumed to ultimately convert to solid M 2 S ( Figure 1A). [22] The critical challenges arising from a similar cathodic reaction in Li-S and Na-S systems can be concluded into the following aspects ( Figure 1D). For Li-S batteries, the formation of a series of soluble polysulfides (Li 2 S x , 4 ≤ x ≤ 8) at the first step (≈2.3 V) and solid Li 2 S 2 /Li 2 S at the second step (≈2.1 V) achieves a theoretical capacity of 418 and 1254 mAh g −1 , respectively.…”

Rational Design of Binders for Stable Li‐S and Na‐S Batteries