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Battery, Battery Materials, Emerging Industry

 <2022> Solid State Electrolyte Technology Trend & Market Outlook (~2030)


 

With the growth of xEV battery industry, there has been growing interest in emerging products of the next generation. All-solid-state battery is one of the key players among the newcomers in the market. Major companies in the industry have been bracing for new challenges ahead by outlining their future roadmaps. The all-solid-state battery sector is expected to flourish around 2027. The K-trio battery makers as well as non-Korean companies on the global stage such as Toyota in Japan and QuantumScape in the US have been working behind-the-scenes to take a leading position in the market.

 

 

 

Among the K-trio companies, Samsung SDI recently started the establishment of pilot line, named 'S line,' for all-solid-state battery in Suwon, Gyeonggi-do Province. The S Line, constructed on a 6,500 square-metre premise, will encompass related manufacturing infrastructure such as solid electrolyte production facilities.

 

LG Energy Solution has been working on the development two different types of all-solid-state battery - polymer and sulfide - at the same time. SK On has agreed to cooperate with SOLIDpower in the US about the R&D of all-solid-state battery.

 

SNE Research, one of the most influential market research institutes in Korea, forecasts the all-solid-state battery market to grow from 2GWh in 2021 to 135GWh in 2030. It is expected that all-solid-state battery may join the mainstream in 2035.

 

 

 

The concept of all-solid-state battery was first proposed in the late 1970s. All-solid-state battery has flammable liquid electrolyte / separator replaced by non-flammable / flame-retardant solid electrolyte which acts as ion-conductive electrolyte and separator. All-solid-state battery, though, has not received much recognition for a long time with only research on solid electrolyte conducted for academic purpose. However, after Toyota in Japan unveiled its prototype of all-solid-state battery using the sulfide solid electrolyte in 2010, all-solid-state battery has drawn a great attention from the world. After that, related research has become noticeably active, and at present, candidate materials for solid electrolyte including oxide, sulfide, polymer, and organic / inorganic hybrid materials are all subject to active research of today.

 

 

 

Most of the next-generation, high-capacity/high-power (high-voltage)/ large-size lithium-ion batteries, that have been subject to the recent research and development, use the organic liquid electrolyte, which is superior in ion conductivity, but at the same time, is highly volatile, thus inevitably creating anxiety about the safety of batteries. There have been researches on electrolyte, separator and electrode materials, with an aim to secure the safety of lithium-ion battery, but any research on the all-solid-state battery system based on solid electrolyte, which can address the fundamental safety issues with battery, have not kicked off yet. In general, when moving from liquid to polymer gel and then, solid electrolyte on the spectrum of electrolyte, the safety level of lithium-ion battery increases. On the contrary, the electrochemical reactiveness deteriorates as the electrolyte becomes solid. Such deterioration is caused by low ion-conductivity of solid electrolyte and high interfacial resistance due to reduced contact area. All of these added up to become a major obstacle for the commercialization of all-solid-state battery. To address these issues, there have been brisk research movements across the industry.

 

 

 

To secure the safety of next-generation, high-capacity / high-power (high-voltage) / large-size lithium-ion battery, it has become critical to develop lithium ion batteries using the solid electrolyte. In addition, there are hightened expectations on the potential commercialization as industry leaders in Japan and the US have begun their research projects in earnest.

 

 

 

This report explores different types and features of solid electrolyte. In particular, the report will closely examine the properties of organic/inorganic hybrid solid electrolyte that has recently drawn attention from the market. It will also take a close look into the development status and production technology of today.

 

The report includes a summary of different types of solid electrolyte, research trends in different nations, and information of major developers.

 

  

 

 

 

Strong points of this report are as follows:  

 

     Detailed explanations on types and features of solid electrolyte

 

     Comparative analysis on technical features of solid electrolyte

 

     Summary of solid electrolyte production process and up-to-date trend in technology development

 

     Trend in technology development of solid electrolyte by country and by company

 

     Useful to those who want to enter the solid electrolyte material market or carry out a feasibility study before entering the market

 

  

 

 

 

Table of Contents

 

<2022> Solid Electrolyte Technology Trend and Market Outlook (~2030)

 

 

 

1. Introduction

 

1.1. Overview of All-Solid-State Battery

 

1.2. Types and Characteristics of Solid Electrolyte

 

1.3. Required Characteristics of All-Solid-State Battery

 

 

 

2. Characteristics of Solid Electrolyte by Type

 

2.1. Oxynitride Solid Electrolyte

 

2.2. Oxide Solid Electrolyte

 

2.2.1. Garnet Solid Electrolyte

 

2.2.2. Perovskite Solid Electrolyte

 

2.3. NASICON-type Solid Electrolyte

 

2.4. LISICON Solid Electrolyte

 

2.5. Sulfide Solid Electrolyte

 

2.6. Polymer Electrolyte

 

2.6.1. Solid Polymer Electrolyte

 

2.6.2. Gel Polymer Electrolyte

 

2.7. Lithium-ion Conductivity in Organic∙Inorganic Hybrid Solid Electrolyte

 

 

 

3. Solid Electrolyte Technology Development Trend

 

3.1. Oxynitride Solid Electrolyte Technology Trend

 

3.2. Oxide Solid Electrolyte Technology Trend

 

3.2.1. Garnet Solid Electrolyte

 

3.2.2. Perovskite Solid Electrolyte

 

3.3. NASICON Solid Electrolyte Technology Trend

 

3.4. LISICON Solid Electrolyte Technology Trend

 

3.5. Sulfide Solid Electrolyte Technology Trend

 

3.6. Polymer Electrolyte Technology Trend

 

3.7. Organic∙Inorganic Hybrid Solid Electrolyte Technology Trend

 

3.7.1. Nanoparticle Filler (0D)

 

3.7.2. Nanowire Filler (1D)

 

3.7.3. Nano Plate Filler (2D)

 

3.7.4. Ceramic Matrix (3D)

 

3.7.5. Gel-based Organic∙Inorganic Hybrid Solid Electrolyte

 

3.8. Solid Electrolyte Patent Trend

 

 

 

4. Research Updates for Solid Electrolyte

 

4.1. Oxide Solid Electrolyte Technology

 

4.2. NASICON Solid Electrolyte Technology

 

4.3. Sulfide Solid Electrolyte Technology

 

4.4. Polymer Electrolyte Technology

 

4.5. Organic·Inorganic Hybrid Solid Electrolyte Technology

 

4.5.1. Organic·Inorganic Hybrid Solid Electrolyte Production Method

 

4.5.2. Oxide-based Organic·Inorganic Hybrid Solid Electrolyte

 

4.5.3. Sulfide-based Organic·Inorganic Hybrid Solid Electrolyte

 

4.5.4. Strategies for Ion-conductivity of Organic·Inorganic Hybrid Solid Electrolyte

 

4.6. Electrodes for All-Solid-State Battery

 

4.7. Interface

 

4.7.1. Solution for Interface Issues by Organic·Inorganic Hybrid Solid Electrolyte

 

4.7.2. Liquid-Oxide Multilayer Organic·Inorganic Hybrid Solid Electrolyte

 

4.7.3. Polymer-Oxide Multilayer Organic·Inorganic Hybrid Solid Electrolyte

 

4.8. Fast Charging

 

4.9. Production Process

 

 

 

5. Technology and Market Trend by Major Countries

 

5.1. Technology and Market Trend in Japan

 

5.2. Technology and Market Trend in US

 

5.3. Technology and Market Trend in China

 

5.4. Technology and Market Trend in Europe

 

5.5 Technology and Market Trend in Korea

 

 

 

6. Solid Electrolyte Market Outlook

 

6-1. Solid Electrolyte Market Outlook

 

6-2. Key Players in Solid Electrolyte Development

 

6-2-1. Idemitsu Kosan (JP)

 

6-2-2. Mitsui Mining & Smelting (JP)

 

6-2-3. Fuji Film (JP)

 

6-2-4. Ohara (JP)

 

6-2-5. Solid Power (US)

 

6-2-6. Quantum Scape (US)

 

6-2-7. Solid Energy Systems (US)

 

6-2-8. Ionic Materials (US)

 

6-2-9. Albermale (US)-Universität Siegen (Ger)

 

6-2-10. Qingdao Energy (CHN)

 

6-2-11. Enovate (CHN)

 

6-2-12. Nio (CHN)

 

6-2-13. Ganfeng Lithium (CHN)

 

6-2-14. ProLogium (Taiwan)

 

6-2-15. Ilika (Ger)

 

6-2-16. BASF (Ger) – Sion Power

 

6-2-17. Bollore (France)

 

6-2-18. Hydro Quebec (Canada)

 

6-2-19. EU Others

 

6-2-20. ISU Chemical (KOR)

 

6-2-21. Chunbo (KOR)

 

6-2-22. POSCO Chemical (KOR)

 

6-2-23. Hansol Chemical (KOR)

 

6-2-24. Iljin Materials (KOR)

 

6-2-25. Donghwa Electrolyte (KOR)

 

6-2-26. INCHEMS (KOR)

 

6-2-27. Jeong Kwan (KOR)

 

6-2-28. KERI (KOR)

 

6-2-29. CIS (KOR)

 

6-2-30. Solivis (KOR)

 

6-2-31. EN Plus (KOR)

 

6-2-32. ENCHEM (KOR)

 

6-2-33. TDL (KOR)

 

6-2-34. Seven King Energy (KOR)

 

6-2-35 Hannong (KOR)

 

6-2-36 Others (KOR)

 

 

 

7. References

 

 

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