Bluesky Facebook Reddit Email

Breakthrough in sodium batteries: gradient anode enables 200 Wh kg-1 energy density and dendrite-free cycling

11.10.25 | Science China Press

SAMSUNG T9 Portable SSD 2TB

SAMSUNG T9 Portable SSD 2TB transfers large imagery and model outputs quickly between field laptops, lab workstations, and secure archives.
Breakthrough in Sodium Batteries: Gradient Anode Enables 200 Wh kg-1 Energy Density and Dendrite-Free Cycling
Figure 2. Electrochemical test of GNS/Na||NVP and Pure Na||NVP. Long-term cycling performances (a) and rate performances (b) of GNS/Na||NVP and Pure Na||NVP cells. Mass loading of NVP is 2.0 mg cm-2, with lean electrolyte. (c) Long-term cycling performances of GNS/Na||NVP and Pure Na||NVP cells. Mass loading of NVP is 30 mg cm-2, with flooded electrolyte. (d) Long-term cycling performance of GNS/Na||NVP cell. Mass loading of NVP is 30 mg cm-2, with lean electrolyte. Voltage profiles of the Pure Credit: ©Science China Press

The development of sustainable energy storage systems demands cost-effective and high-performance battery technologies. Sodium (Na)-based batteries have emerged as promising alternatives to conventional lithium-ion batteries in the renewable energy sector, primarily due to the greater natural abundance and lower cost of Na. However, the realization of high-energy-density Na batteries faces fundamental challenges at the anode, where three critical requirements converge: high capacity, Na compensation capability, and dendrite suppression.

Now, a research team led by Prof. Danni Lei and Prof. Chengxin Wang at Sun Yat-sen University has developed a gradient sodium-tin/sodium bilayer anode (GNS/Na) that addresses these critical issues. The work, published in National Science Review, demonstrates the new anode that fundamentally redefines sodium deposition behavior.

A gradient sodium-tin/sodium bilayer anode (GNS/Na) via in-situ chemical displacement involving Sn ethoxide reduction and controlled interdiffusion. The compositionally modulated unsaturated NaxSny alloys (x/y≤15:4) serves as an electrochemical buffer layer, which simultaneously optimizes both the thermodynamics and kinetics of ion diffusion, thereby achieving dendrite-free morphology. Beneath this gradient layer, the bulk Na reservoir ensures both the stability of gradient structure and compensation of Na + depletion through dynamic ion replenishment during extended cycling. Therefore, this work redefines anode design principles. As a result, the symmetric cell achieves an ultralong cycle life of 7000 and 700 hours at current densities of 3 and 10 mA cm −2 , respectively. Notably, when paired with a high-loading Na3V2(PO4)3 (NVP) (30 mg cm −2 ) cathode, the full cycles stably for nearly 1000 cycles and delivers an unprecedented energy density of 200 Wh kg −1 . We establish a materials design paradigm that simultaneously addresses capacity, stability, and safety–key barriers to sustainable energy storage. This strategy can be extended to post-lithium batteries.

This achievement has been published in National Science Review . Original article link: https://doi.org/10.1093/nsr/nwaf427

National Science Review

10.1093/nsr/nwaf427

Experimental study

Additional Media

Breakthrough in Sodium Batteries: Gradient Anode Enables 200 Wh kg-1 Energy Density and Dendrite-Free Cycling
Figure 1 Design and characterization of gradient electrode. (a) Cross-sectional SEM image, the corresponding EDS mapping and the corresponding elemental line scan of NS/Na. (b) The measured potential of NS/Na. (c) Schematic illustration of the NS/Na electrode after Na plating and stripping process. (d) Cross-sectional SEM image, the corresponding EDS mapping and the corresponding elemental line scan of GNS/Na. (e) The measured potential of GNS/Na. (f) Schematic illustration of the GNS/Na electro Credit: ©Science China Press

Keywords

Anodes Applied Sciences and Engineering Batteries Energy Storage Physical Sciences

Article Information

Journal
National Science Review
DOI
10.1093/nsr/nwaf427
Method of Research
Experimental study

Contact Information

Bei Yan
Science China Press
yanbei@scichina.com

Source

Original Source
https://doi.org/10.1093/nsr/nwaf427

How to Cite This Article

APA:
Science China Press. (2025, November 10). Breakthrough in sodium batteries: gradient anode enables 200 Wh kg-1 energy density and dendrite-free cycling. Brightsurf News. https://www.brightsurf.com/news/LMJ74DRL/breakthrough-in-sodium-batteries-gradient-anode-enables-200-wh-kg-1-energy-density-and-dendrite-free-cycling.html
MLA:
"Breakthrough in sodium batteries: gradient anode enables 200 Wh kg-1 energy density and dendrite-free cycling." Brightsurf News, Nov. 10 2025, https://www.brightsurf.com/news/LMJ74DRL/breakthrough-in-sodium-batteries-gradient-anode-enables-200-wh-kg-1-energy-density-and-dendrite-free-cycling.html.