Solid-state battery

A solid-state battery is an electrical battery that uses a solid electrolyte to conduct ions between the electrodes, instead of the liquid or gel polymer electrolytes found in conventional batteries. Theoretically, solid-state batteries offer much higher energy density than the typical lithium-ion or lithium polymer batteries.
While solid electrolytes were first discovered in the 19th century, several problems prevented widespread application. Developments in the late 20th and early 21st century generated renewed interest in the technology, especially in the context of electric vehicles. [|As of 2026], the solid-state battery market has yet to reach scalability and commercialization.
Solid-state batteries can use metallic lithium for the anode and oxides or sulfides for the cathode, thereby enhancing energy density. The solid electrolyte acts as an ideal separator that allows only lithium ions to pass through. For that reason, solid-state batteries can potentially solve many problems of currently used liquid electrolyte Li-ion batteries, including flammability, limited voltage, unstable solid-electrolyte interface formation, poor cycling performance, and strength.
Materials proposed for use as electrolytes include ceramics, and solid polymers. Solid-state batteries are found in pacemakers and in RFID and wearable devices. These batteries offer enhanced safety and higher energy densities. Challenges to widespread adoption include energy and power density, durability, material costs, sensitivity, and stability.

History

Origin

Between 1831 and 1834, Michael Faraday discovered the solid electrolytes silver sulfide and lead fluoride, which laid the foundation for solid-state ionics.
By the late 1950s, several silver-conducting electrochemical systems employed solid electrolytes, at the price of low energy density and cell voltages, and high internal resistance. In 1967, the discovery of fast ionic conduction β-alumina for a broad class of ions kick-started the development of solid-state electrochemical devices with increased energy density. Most immediately, molten sodium / β-alumina / sulfur cells were developed at Ford Motor Company in the US, and NGK in Japan. This excitement manifested in the discovery of new systems in both organics, i.e. poly oxide, and inorganics such as NASICON. However, many of these systems required operation at elevated temperatures or were expensive to produce, limiting commercial deployment.

1990s and 2000s

A new class of solid-state electrolyte developed by Oak Ridge National Laboratory, lithium–phosphorus oxynitride, emerged in the 1990s. LiPON was successfully used to make thin-film lithium-ion batteries, although applications were limited due to the cost associated with deposition of the thin-film electrolyte, along with the small capacities that could be accessed using the thin-film format.

2010s

Kamaya et al. demonstrated in 2011 the first solid-electrolyte, LiGePS, capable of achieving a bulk ionic conductivity in excess of liquid electrolyte counterparts at room temperature. With this advancement, bulk solid-ion conductors could compete technologically with Li-ion counterparts.
Automotive companies researched the technology in the 2010s. Bolloré launched in 2011 a fleet of their BlueCar model cars featuring a 30 kWh lithium metal polymer battery with a polymeric electrolyte, created by dissolving lithium salt in polyoxyethylene co-polymer. Toyota began conducting in 2012 research into automotive applications of solid-state batteries. At the same time, Volkswagen began partnering with small technology companies specializing in the technology. Researchers at the University of Colorado Boulder announced in 2013 the development of a solid-state lithium battery, with a solid iron–sulfur composite cathode that promised higher energy. Toyota extended its decades-long partnership with Panasonic in 2017 to include collaboration on solid-state batteries. As of 2019 Toyota held the most SSB-related patents. The following years similar research efforts into solid-state batteries was separately annouced by BMW, Honda, Hyundai, and Nissan.
Outside of the automotive sector, other research and development in the 2010s included: solid-state batteries for electronics by Qing Tao announced in 2018; and a solid-state glass battery by John Goodenough, the co-inventor of Li-ion batteries, unveiled in 2017, featuring a glass electrolyte and an alkali-metal anode consisting of lithium, sodium or potassium.

2020s

Many companies have announced readiness to commercialize solid-state batteries at the GWh scale in the 2020s, but their batteries' feasibility or technology readiness is unknown. These announcements include: ProLogium - GWh production capacity by 2022; QuantumScape - GWh production capacity by 2024; Qing Tao - GWh production capacity by 2020; Ampcera - commercial availability by 2021; Panasonic and Toyota - market maturity by 2025; Solid Power, BMW, and Ford - market maturity by end of 2020s; WeLion - GWh production capacity by 2022; StoreDot; Honda - market maturity by 2030; Ionic Materials and Hyundai - market maturity in the 2030s; and others. Many of these companies have not commercialized their product as of January 2026, and the solid-state battery market has yet to reach scalability and commercialization.

Materials

Candidate materials for solid-state electrolytes include ceramics such as lithium orthosilicate, glass, sulfides and RbAg₄I₅. Mainstream oxide solid electrolytes include Li_1.5Al_0.5Ge_1.5₃, Li_1.4Al_0.4Ti_1.6₃, perovskite-type Li_3xLa_2/3-xTiO₃, and garnet-type Li_6.4La₃Zr_1.4Ta_0.6O₁₂ with metallic Li. The thermal stability versus Li of the four SSEs was in order of LAGP < LATP < LLTO < LLZO. Chloride superionic conductors have been proposed as another promising solid electrolyte. They are ionic conductive as well as deformable sulfides, but at the same time not troubled by the poor oxidation stability of sulfides. Other than that, their cost is considered lower than oxide and sulfide SSEs. The present chloride solid electrolyte systems can be divided into two types: Li₃MCl₆ and Li₂M_2/3Cl₄. M Elements include Y, Tb-Lu, Sc, and In. The cathodes are lithium-based. Variants include LiCoO₂, LiNi_1/3Co_1/3Mn_1/3O₂, LiMn₂O₄, and LiNi_0.8Co_0.15Al_0.05O₂. The anodes vary more and are affected by the type of electrolyte. Examples include In, Si, Ge_xSi_1−x, SnO–B₂O₃, SnS –P₂S₅, Li₂FeS₂, FeS, NiP₂, and Li₂SiS₃.
Lithium-ceramic batteries demonstrate potential improvements with the integration of single wall carbon nanotubes. SWCNTs build durable, long-range conductive pathways between electrode particles, effectively reducing electrode resistance and enhancing energy density.
One promising cathode material is Li–S, which has a theoretical specific capacity of 1,670 mAh/g, "ten times larger than the effective value of LiCoO₂". Sulfur makes an unsuitable cathode in liquid electrolyte applications because it is soluble in most liquid electrolytes, dramatically decreasing the battery's lifetime. Sulfur is studied in solid-state applications.
Another encouraging cathode is NCM662, especially when coated with NiCo₂S₄ in a resonant acoustic mixing process. This creates a material with a capacity retention of 60.6%, with minimal side reactions.
Li-O₂ also have high theoretical capacity. The main issue with these devices is that the anode must be sealed from ambient atmosphere, while the cathode must be in contact with it.
A Li/LiFePO₄ battery shows promise as a solid-state application for electric vehicles. A 2010 study presented this material as a safe alternative to rechargeable batteries for EV's that "surpass the USABC-DOE targets".
A cell with a pure silicon μSi||SSE||NCM811 anode was assembled by Darren H.S Tan et al. using μSi anode, solid-state electrolyte and lithium–nickel–cobalt–manganese oxide cathode. This kind of solid-state battery demonstrated a high current density up to 5 mA cm⁻², a wide range of working temperature, and areal capacity of up to 11 mAh/cm². At the same time, after 500 cycles under 5 mA cm⁻², the batteries still provide 80% of capacity retention, which is the best performance of μSi all solid-state battery reported so far.
Chloride solid electrolytes also show promise over conventional oxide solid electrolytes owing to chloride solid electrolytes having theoretically higher ionic conductivity and better formability. In addition chloride solid electrolyte's exceptionally high oxidation stability and high ductility add to its performance. In particular a lithium mixed-metal chloride family of solid electrolytes, Li₂In_xSc_0.666-xCl₄ developed by Zhou et al., show high ionic conductivity over a wide range of composition. This is owing to the chloride solid electrolyte being able to be used in conjunction with bare cathode active materials as opposed to coated cathode active materials and its low electronic conductivity. Alternative cheaper chloride solid electrolyte compositions with lower, but still impressive, ionic conductivity can be found with an Li₂ZrCl₆ solid electrolyte. This particular chloride solid electrolyte maintains a high room temperature ionic conductivity, deformability, and has a high humidity tolerance.

Perovskite-type

Meanwhile, Perovskite materials also have great potential for application in solid-state batteries. In order to improve the low efficiency and high pollution of traditional fossil-based energy sources, more and more researchers have put forward the idea of solid-state batteries, which will have a longer lifespan and higher efficiency. However, solid-state batteries still have a lot of safety concerns and drawbacks, so researchers are using a lot of new materials to solve this problem. One such material is perovskite materials.
Perovskite materials have excellent ionic conductivity, excellent charge storage capacity and good electrochemical activity, so this material has a very great potential for application in the field of electrochemical energy storage as well as energy conversion. This material is used in many new energy batteries, such as solid state batteries and solar cells. Its general formula is ABX3. In ABX3, the B ion is surrounded by the X ion octahedron and the A ion is located in the center of the cube. Transition metal perovskite fluoride as a perovskite-type electrode material, has high voltage window, specific capacity and stability, moreover, the structure of transition metal perovskite fluoride facilitates ion migration and its general pseudocapacitance-controlled kinetic features make it has a fast charge transport rate so this material has good electrochemical properties. Thus, more and more researchers focus on this material. Shan et al.'s research not only shows that lithium ions can be inserted into the lattice of perovskite oxides, but also demonstrates that perovskite oxides, with its high ionic conductivity, can be used as an electrode material. For the transition metal perovskite fluoride, it has a fast charge transport rate, high energy density and high stability because it has metal-fluorine bond and the strong electronegativity of fluorine. Jiao et al. used solvothermal method to make the perovskite-type fluoride with a hollow micrometer spherical structure, after testing, this material shows a good retention rate like it has capacity of 142 mAh/g after 1000 cycles at 0.1 A/g.