Chemical energy storage, including lead acid batteries, nickel system batteries, and lithium ion batteries (LiBs), is considered to be the most promising energy storage technology for industrialization. Among these, LiBs have many advantages such as light weight, high energy density, high power density, and long life, and they are overwhelmingly preferred by designers for use in portable electronic devices such as cell phones and laptops. However, overcharging or short-circuiting can lead to high temperature and result in fire or explosion due to the presence of flammable organic electrolytes. Fires and explosions of LiBs have been reported throughout the world. The developments of electric vehicles (EVs) and large-scale energy storage devices for new kinds of power stations greatly expand the market for LiBs, meanwhile, stricter safety requirements apply to LiBs. Since large numbers of LiBs are packed together in EVs or power stations, fire or explosion in an LiB could be disastrous. Safety has become the main obstacle for the wide application of LiBs. To meet this issue, solid state batteries have entered the field.

A solid state battery is composed mainly of cathode, anode, and solid electrolyte, as developed during the latter half of the 20th century. Solid state batteries have a simpler structure than the traditional LiBs, and the simplified structure with a solid electrolyte enables higher energy density. Solid electrolytes not only conduct Li+ ions but also serve as the separator, as shown in Figure below. In solid state batteries, no organic liquid electrolyte, electrolyte salt, separator, or binder is required, which dramatically simplifies the assembly process. The operational principle of solid state batteries is no different from the traditional LiBs. In the charge process, lithium ions deintercalate from the cathode material and transport to the anode through the electrolyte, while electrons drift to the anode by the external circuit. Lithium ions combine with electrons to form more complete lithium atoms. The discharge process is just the reverse.

Although Solid State Batteries based on inorganic solid electrolytes have clearly demonstrated their great possibilities for electric vehicles and large-scale energy storage systems, further development is still required to improve their energy density, rate capability, and cycling stability, while ensuring excellent safety. Actually, they are still far from being commercialized for industrial applications, which require systematical studies and will be a complicated process.
Making Solid State Batteries usable outside the laboratory involves multiple factors such as solid electrolytes, electrodes, interface properties, and construction design. The high cost and very small production scale of solid state electrolytes with high ionic conductivity hinder the application of Solid State Batteries. Meanwhile, Solid State Batteries still suffer from inferior power density and poor cycle life, due to the high transfer resistance of lithium ions between the electrodes and solid electrolytes. Thus, at this stage, the direction for research exploring Solid State Batteries for commercial applications is to develop new cathodes based on the conversion reaction mechanism with low or even zero strain and energy levels well matched with the electrolytes. All of these together are expected to yield new material systems with high capacity. In addition, the use of lithium metal in anodes will be another thrust of Solid State Batteries development. Another is the design of novel SEs with high lithium-ion conductivity at room temperature and wide electrochemical window. Meanwhile, future SEs should show excellent chemical stability in the presence of metallic lithium. Also, new methods should be proposed to reduce the interfacial resistance between the electrode and electrolyte. Finally, the optimal combination of different fabrication processes and equipment automation as well as device design are necessary for the realization of Solid State Batteries with high capacity, low cost, and high yield.
In summary, scientific and technical research on Solid State Batteries is progressing gradually. The current achievements indicate that Solid State Batteries with high energy density are promising candidates for large-scale energy storage and even electric vehicle applications



The Global Solid State Batteries Market had reached xxx million USD with a CAGR xx from 2018-2022. Later on, it will go to xxx million USD in 2023 with a CAGR xx % from 2023 - 2030.

In the global Solid State Batteries Market, This report focuses particularly in North America, South America, Europe and Asia-Pacific, and Middle East and Africa. This report classifies the Market on the basis of application, type, regions, and manufactures.

In Market segmentation by manufacturers, the report covers the following companies-

BMW
Hyundai
Dyson
Apple
CATL
Bolloré
Toyota
Panasonic
Jiawei
Bosch
Quantum Scape
Ilika
Excellatron Solid State
Cymbet
Solid Power
Mitsui Kinzoku
Samsung
ProLogium
Front Edge Technology

In Market segmentation by geographical regions, the report has analysed the following regions-
North America (USA, Canada and Mexico)
Europe (Germany, France, UK, Russia and Italy)
Asia-Pacific (China, Japan, Korea, India and Southeast Asia)
South America (Brazil, Argentina, Columbia etc.)
Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria and South Africa)

In Market segmentation by types :

Polymer-Based Solid State Batteries
Solid State Batteries with Inorganic Solid Electrolytes
In Market segmentation by applications :

Consumer Electronics
Electric Vehicle
Aerospace
others

The research provides answers to the following key questions:
• What is the estimated growth rate and Market share and size of the Solid State Batteries Market for the forecast period 2023 - 2030?
• What are the driving forces in the Solid State Batteries Market for the forecast period 2023 - 2030?
• Who are the prominent Market players and how have they gained a competitive edge over other competitors?
• What are the Market trends influencing the progress of the Solid State Batteries industry worldwide?
• What are the major challenges and threats restricting the progress of the industry?
• What opportunities does the Market hold for the prominent Market players?
Any special requirements about this report, please let us know and we can provide custom report.

Note – In order to provide more accurate market forecast, all our reports will be updated before delivery by considering the impact of COVID-19.

Research Methodology

The Market Research Update offers technology-driven solutions and its full integration in the research process to be skilled at every step. We use diverse assets to produce the best results for our clients. The success of a research project is completely reliant on the research process adopted by the company. Market Research Update assists its clients to recognize opportunities by examining the global market and offering economic insights. We are proud of our extensive coverage that encompasses the understanding of numerous major industry domains.

Market Research Update provide consistency in our research report, also we provide on the part of the analysis of forecast across a gamut of coverage geographies and coverage. The research teams carry out primary and secondary research to implement and design the data collection procedure. The research team then analyzes data about the latest trends and major issues in reference to each industry and country. This helps to determine the anticipated market-related procedures in the future. The company offers technology-driven solutions and its full incorporation in the research method to be skilled at each step.

The Company's Research Process Has the Following Advantages:

1. Information Procurement

The step comprises the procurement of market-related information or data via different methodologies & sources.

2. Information Investigation

This step comprises the mapping and investigation of all the information procured from the earlier step. It also includes the analysis of data differences observed across numerous data sources.

3. Highly Authentic Source

We offer highly authentic information from numerous sources. To fulfills the client’s requirement.

4. Market Formulation

This step entails the placement of data points at suitable market spaces in an effort to assume possible conclusions. Analyst viewpoint and subject matter specialist based examining the form of market sizing also plays an essential role in this step.

5. Validation & Publishing of Information

Validation is a significant step in the procedure. Validation via an intricately designed procedure assists us to conclude data-points to be used for final calculations.