Comparison, Li-ion, Lithium Ion and Sodium

Stanford team develops sodium-ion battery with performance equivalent to Li-ion, but at much lower cost

Green Car Congress

OCTOBER 10, 2017

Stanford researchers have developed a sodium-ion battery (SIB) that can store the same amount of energy as a state-of-the-art lithium ion, at substantially lower cost. Thus, further research is required to find better sodium host materials. The sodium salt makes up the cathode; the anode is made up of phosphorous.

Sodium

Sodium Li-ion Batteries Battery

New long-duration, extended capacity Na-Al battery design for grid storage

Green Car Congress

MARCH 2, 2023

Researchers led by the Department of Energy’s Pacific Northwest National Laboratory (PNNL) have extended the capacity and duration of sodium-aluminum batteries. The new sodium-based molten salt battery uses two distinct reactions. It is a variation of a sodium-metal halide battery. of peak charge capacity.

Molten Salt

Molten Salt Grid Design Sodium

Antimony nanocrystals as high-capacity anode materials for both Li-ion and Na-ion batteries

Green Car Congress

MARCH 19, 2014

The nanocrystals possess high and similar Li-ion and Na-ion charge storage capacities of 580?640 85% of the low-rate value, indicating that rate capability of Sb nanostructures can be comparable to the best Li-ion intercalation anodes and is so far unprecedented for Na-ion storage. 640 mAh g ?1

Li-ion

Li-ion Sodium Batteries Battery

Faradion demonstrates proof-of-concept sodium-ion electric bike

Green Car Congress

MAY 15, 2015

E-bike powered by Faradion prototype Na-ion battery pack. British battery R&D company Faradion has demonstrated a proof-of-concept electric bike powered by sodium-ion batteries at the headquarters of Williams Advanced Engineering, which collaborated in the development of the bike. Sodium-ion intercalation batteries—i.e.,

Sodium

Sodium Concept Li-ion Lithium Ion

Aqua Metals is building a more sustainable battery recycling ecosystem

Charged EVs

APRIL 1, 2024

The economic benefits of recycling Li-ion batteries are clear, but at present, only a small percentage of them are recycled. The two main processes for recycling lithium-ion batteries are pyrometallurgy and hydrometallurgy. There are currently two main processes for recycling lithium-ion batteries.

Building

Building Batteries Battery Lithium Ion

Aqua Metals is building a more sustainable battery recycling ecosystem – Charged EVs

Baua Electric

APRIL 1, 2024

The economic benefits of recycling Li-ion batteries are clear, but at present, only a small percentage of them are recycled. The two main processes for recycling lithium-ion batteries are pyrometallurgy and hydrometallurgy. There are currently two main processes for recycling lithium-ion batteries.

Building

Building Batteries Battery Charging

Researchers call for integration of materials sustainability into battery research; the need for in situ monitoring

Green Car Congress

JANUARY 18, 2017

The size of these batteries (in comparison to those used for portable electronics) places severe pressure on materials resources. Under such a scenario, the production of Li-ion batteries should expand hugely over the years to come, hence reviving the issue of finite Li reserves. —Grey and Tarascon.

Li-ion

Li-ion Ni-Li Batteries Battery

OSU smart membrane could enable new category of high-energy, high-power energy storage for EVs

Green Car Congress

AUGUST 24, 2016

A team at the Ohio State University has developed a membrane that regulates bi-directional ion transport across it as a function of its redox state and that could be used as a programmable smart membrane separator in future supercapacitors and redox flow batteries. —Herya and Sundaresan. plugin EVs to Tesla’s 85 kWh battery pack).

Energy Storage

Energy Storage Energy Power Powered

Can Flow Batteries Finally Beat Lithium?

Cars That Think

DECEMBER 24, 2023

The cell of a flow battery uses two chemical solutions containing ions, one acting as the anolyte (adjacent to the anode), the other as the catholyte (near the cathode). Typical redox flow batteries use ions based on iron chromium or vanadium chemistries; the latter takes advantage of vanadium’s four distinct ionic states.

Lithium Ion

Lithium Ion Batteries Battery Li-ion

PNNL study outlines requirements for grid storage, reviews four electrochemical energy storage systems: vanadium redox flow, Na-beta, Li-ion and lead-carbon

Green Car Congress

MARCH 15, 2011

published in the ACS journal Chemical Reviews , reviews in detail four stationary storage systems considered the most promising candidates for electrochemical energy storage: vanadium redox flow; sodium-beta alumina membrane; lithium-ion; and lead-carbon batteries. Sodium-beta alumina membrane battery. —Yang et al.

Li-ion

Li-ion Energy Storage Grid Carbon

EV Driven

Stanford team develops sodium-ion battery with performance equivalent to Li-ion, but at much lower cost

New long-duration, extended capacity Na-Al battery design for grid storage

Antimony nanocrystals as high-capacity anode materials for both Li-ion and Na-ion batteries

Faradion demonstrates proof-of-concept sodium-ion electric bike

Aqua Metals is building a more sustainable battery recycling ecosystem

Aqua Metals is building a more sustainable battery recycling ecosystem – Charged EVs

Researchers call for integration of materials sustainability into battery research; the need for in situ monitoring

OSU smart membrane could enable new category of high-energy, high-power energy storage for EVs

Can Flow Batteries Finally Beat Lithium?

PNNL study outlines requirements for grid storage, reviews four electrochemical energy storage systems: vanadium redox flow, Na-beta, Li-ion and lead-carbon

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