sodium-ion batteries related⁤ to sodium​ clusters” title=”Analysis of thermal runaway mechanisms in sodium-ion versus lithium-ion pouch‍ cells. Comparisons of alkali⁢ metal ion behavior in hard carbon and graphite anodes, alongside a study of ⁣sodium clusters against LiC6 and‌ their metallic counterparts. Credit: Chinese ​Academy of Sciences” width=”800″ height=”530″/>

Alarm Bells Ring for Sodium-Ion Batteries: A Closer Look at⁤ Safety‌ Risks

A research team from the Qingdao Institute of Bioenergy and Bioprocess Technology within the Chinese Academy of Sciences has uncovered alarming safety issues related to sodium-ion batteries (SIBs), particularly when ‍juxtaposed ‍with lithium-ion batteries (LIBs).

Unexpected Findings on ⁣Thermal Runaway

The findings, published‍ in the journal Energy & Environmental Science, indicate that SIBs may be ‌more susceptible to thermal⁣ runaway events than previously recognized, challenging their established reputation for⁤ safety despite benefits such as cost-efficiency and resource availability.

Sodium-ion batteries have demonstrated impressive advancements over the last ten⁤ years, achieving energy densities​ reaching 160 ⁤Wh/kg along ‌with ⁤cycle lives surpassing ‌4,000 charge-discharge cycles. Nevertheless,⁤ safety issues remain paramount. This investigation sheds light on how sodium clusters present in hard carbon anodes can instigate premature thermal ​runaway incidents due ‍to their ⁤unexpected​ electronic ‍behavior.

The Mechanism Behind‍ Increased Reactivity

Prof. Cui Guanglei, who co-authored the study, stated that ‍”When a battery reaches ⁤critical ⁤charge thresholds,‌ these⁤ sodium clusters can drop the temperature required for ⁤self-heating initiation down to as low as ​92°C—setting off thermal runaway earlier than‍ what we typically ⁣observe with LIBs.”‍ This reactivity is exacerbated by these clusters acting like catalysts that ​enhance ⁣electrolyte breakdown.

Employing solid-state nuclear magnetic resonance (ssNMR) spectroscopy techniques allowed researchers ​to examine ⁢these ⁣localized clusters at ​a quantum level.‌ Their⁣ discoveries revealed pronounced‍ metallic properties; notably, these clusters contain more conduction electrons at Fermi energy levels compared to bulk metallic sodium itself—making them exceptionally reactive and escalating⁢ risks​ associated ⁤with thermal​ runaway⁤ scenarios.

A Distinct⁢ Behavior ⁣Compared To Lithium-Ion Batteries

Differentiating from LIBs where exothermic ⁢reactions are largely independent of state-of-charge levels​ (SOC), SIB reactions closely correlate with SOC fluctuations. ⁤The formation of disconcerting sodium cluster structures during high SOC ​phases leads‌ to reduced self-heating onset⁢ temperatures well before typical solid-electrolyte ‌interface decomposition occurs in LIB technology. Consequently, even under normal operational conditions, SIBs might face security hazards akin to those linked with overcharging-related sodium plating problems found ⁢within traditional battery systems.

Paving​ The Way Towards Safer Energy Storage Solutions

This research​ addresses a crucial gap regarding the ⁤interplay between cell safety parameters and microenvironments tailored for efficient ‌sodium storage strategies. As part of potential solutions directed towards improving SIB safety profiles dramatically—researchers advocate integrating solid-state ⁣electrolytes instead of liquid ones which could mitigate ​risks ⁤related to thermal runaway ​significantly.

Citation:
Sodium-ion batteries​ reveal serious safety ⁣implications due to implications from detection ⁣around Na+ ions (February 20th ,2025). Accessed February 21st ,2025 via https://techxplore.com/news/2025-02-sodium-ion-batteries-greater-safety.html

sodium-ion batteries related⁤ to sodium​ clusters” title=”Analysis of thermal runaway mechanisms in sodium-ion versus lithium-ion pouch‍ cells. Comparisons of alkali⁢ metal ion behavior in hard carbon and graphite anodes, alongside a study of ⁣sodium clusters against LiC6 and‌ their metallic counterparts. Credit: Chinese ​Academy of Sciences” width=”800″ height=”530″/>

Alarm Bells Ring for Sodium-Ion Batteries: A Closer Look at⁤ Safety‌ Risks

A research team from the Qingdao Institute of Bioenergy and Bioprocess Technology within the Chinese Academy of Sciences has uncovered alarming safety issues related to sodium-ion batteries (SIBs), particularly when ‍juxtaposed ‍with lithium-ion batteries (LIBs).

Unexpected Findings on ⁣Thermal Runaway

The findings, published‍ in the journal Energy & Environmental Science, indicate that SIBs may be ‌more susceptible to thermal⁣ runaway events than previously recognized, challenging their established reputation for⁤ safety despite benefits such as cost-efficiency and resource availability.

Sodium-ion batteries have demonstrated impressive advancements over the last ten⁤ years, achieving energy densities​ reaching 160 ⁤Wh/kg along ‌with ⁤cycle lives surpassing ‌4,000 charge-discharge cycles. Nevertheless,⁤ safety issues remain paramount. This investigation sheds light on how sodium clusters present in hard carbon anodes can instigate premature thermal ​runaway incidents due ‍to their ⁤unexpected​ electronic ‍behavior.

The Mechanism Behind‍ Increased Reactivity

Prof. Cui Guanglei, who co-authored the study, stated that ‍”When a battery reaches ⁤critical ⁤charge thresholds,‌ these⁤ sodium clusters can drop the temperature required for ⁤self-heating initiation down to as low as ​92°C—setting off thermal runaway earlier than‍ what we typically ⁣observe with LIBs.”‍ This reactivity is exacerbated by these clusters acting like catalysts that ​enhance ⁣electrolyte breakdown.

Employing solid-state nuclear magnetic resonance (ssNMR) spectroscopy techniques allowed researchers ​to examine ⁢these ⁣localized clusters at ​a quantum level.‌ Their⁣ discoveries revealed pronounced‍ metallic properties; notably, these clusters contain more conduction electrons at Fermi energy levels compared to bulk metallic sodium itself—making them exceptionally reactive and escalating⁢ risks​ associated ⁤with thermal​ runaway⁤ scenarios.

A Distinct⁢ Behavior ⁣Compared To Lithium-Ion Batteries

Differentiating from LIBs where exothermic ⁢reactions are largely independent of state-of-charge levels​ (SOC), SIB reactions closely correlate with SOC fluctuations. ⁤The formation of disconcerting sodium cluster structures during high SOC ​phases leads‌ to reduced self-heating onset⁢ temperatures well before typical solid-electrolyte ‌interface decomposition occurs in LIB technology. Consequently, even under normal operational conditions, SIBs might face security hazards akin to those linked with overcharging-related sodium plating problems found ⁢within traditional battery systems.

Paving​ The Way Towards Safer Energy Storage Solutions

This research​ addresses a crucial gap regarding the ⁤interplay between cell safety parameters and microenvironments tailored for efficient ‌sodium storage strategies. As part of potential solutions directed towards improving SIB safety profiles dramatically—researchers advocate integrating solid-state ⁣electrolytes instead of liquid ones which could mitigate ​risks ⁤related to thermal runaway ​significantly.

Citation:
Sodium-ion batteries​ reveal serious safety ⁣implications due to implications from detection ⁣around Na+ ions (February 20th ,2025). Accessed February 21st ,2025 via https://techxplore.com/news/2025-02-sodium-ion-batteries-greater-safety.html