<2022> All-Solid-State Battery Technology Trend and Market Outlook (~2030)
With the issues related to the stability and energy density of LiB continuously emerging in the industry, there are growing interests in developing next-generation batteries to address those issues. Among them, the all-solid-state battery has been attracting the biggest attention from the industry players in terms of stability and development readiness.
The all-solid-state battery can be categorized into three types: sulfide-based, oxide-based, and polymer-based. Each type has different advantages/disadvantages and pending issues. This report describes the advantages/disadvantages and issues related to each type as well as the details of their manufacturing processes. Furthermore, this report explores the major developments and achievements made by each battery maker and offers a market outlook for each type till 2030.
This report draws market estimates from comprehensive research on the level of technology development, requirements by OEMs and mass production targets of all-solid-state battery makers. The market analysis provided in this report is categorized into battery maker types, companies, and applications.
All of the above are provided in 10 chapters of which brief indexes are as stated in the following table of contents.
To provide a deeper insight, the 2022 report adds the SNE Insight chapter which deals with the challenges facing different electrolytes and tries to guide directions for their improvement. The chapter also investigates Semi Solid/Hybrid batteries and the mass production time and targets of different battery makers. The report is all the more meaningful as it offers a more detailed market outlook than the 2021 edition, based on the current status and future plans of all-solid-state battery developers.
Table of
Contents
1. Introduction
1.1 History of Battery Development
1.1.1 History of Ancient Battery
Development
1.1.2 Manganese Battery (Leclanché cell)
1.1.3 Alkaline cell
1.1.4 Lead-acid battery
1.1.5 Ni-Cd battery
1.1.6 Ni-MH battery
1.1.7 Lithium-ion
battery
1.2
Challenges with Lithium-Ion Battery
1.2.1 Safety
1.2.2 Energy Density
2. All-Solid-State Battery
2.1 Advantages of All-Solid-State Battery
2.1.1 Increase of Energy Density
2.1.2 Availability in Application of
New Active Materials
2.1.3 Low Activation Energy
2.2 Manufacturing Process of All-Solid-State
Battery
2.2.1 Manufacturing of Electrolyte
Layers
2.2.2 Production of Anode and Cathode
Composite Layers
2.2.3 Cell Assembly
2.3
Solid Electrolyte
2.3.1 History of Solid Electrolyte
Development
2.3.2 Operation Mechanism of Solid
Electrolyte
2.3.3 Classification of Solid
Electrolyte
2.4 Influences of All-Solid-State Battery
on Existing SCMs
3. Sulfide-Based Electrolyte
3.1 Types of Sulfide-Based Electrolyte
3.1.1 Thio-LISICON-based
3.1.2 Binary sulfide-based
3.1.3 Argyrodite-based
3.1.4 Others: Li7P2S8I
3.2
Synthesizing Methods for Sulfide-Based Electrolyte
3.2.1 Solid-phase Synthesis
3.2.2 Liquid-phase Synthesis
3.2.3 Wet-chemical Synthesis
3.3 Synthesizing Methods for Core Raw Materials
3.3.1 Core Raw Materials: Li2S
3.3.2 Synthesis of Starting Materials
3.3.3 Starting Material: Li metal
3.3.4 Starting Material: Li2SO4
3.3.5 Starting Material: Li2CO3
3.3.6 Starting Material: LiOH
3.3.7 Starting Material: Li-R
4. Oxide-Based Electrolyte
4.1
Types of Oxide-Based Electrolyte
4.1.1 Perovskite-based
4.1.2 Garnet-based
4.1.3 NASICON-based
4.1.4 Li1+xAlxGe2-x(PO4)3
(LAGP)
4.1.5 Others: Li2.9PO3.3N0.46
(LiPON)
4.2
Synthesizing Methods for Oxide-Based Electrolyte
4.2.1 Solid-phase Synthesis
4.2.2 Solid-phase Synthesis
5. Polymer-Based Electrolyte
5.1
Types of Polymer-Based Electrolyte
5.1.1 PEO-based Electrolyte
5.1.2 Polymer/Ceramic Composite
5.2
Synthesizing Methods for Polymer-Based Electrolyte
5.2.1 Blending method - PEO-based
Electrolyte
5.2.2 Blending method – Polymer/Ceramic
Composite
6. All-Solid-State Battery R&D Trend
6.1 Problems of All-Solid-State Battery
6.2
All-Solid-State Battery R&D Trend
6.2.1 Enhancement of Li metal stability
6.2.2 Improvement of Electrode Binding
Capacity
6.2.3 Improvement of Pole Plate
Manufacturing Process
6.3
Sulfide-Based Electrolyte R&D Trend
6.3.1 Improvement of Interfacial
Stability of Solid Electrolyte/Electrode
6.3.2 Improvement of Particle Segregation
6.3.3 Suppression of Void Generation
6.3.4 Improvement of Solid Electrolyte
Performance
6.4 Oxide-Based Electrolyte R&D Trend
6.4.1 Improvement of Solid Electrolyte/Electrode
Contact
6.4.2 Improvement of Solid Electrolyte
Performance
6.5
Polymer-Based Electrolyte R&D Trend
6.5.1 Enhancement of Self-standing
Characteristics of Electrolyte Layers
6.5.2 Suppression of Li Dendrite
Formation
7. Trend of All-Solid-State Battery Patents
7.1 Outline of All-Solid-State Battery
Patents
7.2 Polymer-type Major Patents
7.3
Inorganic, Organic/Polymer Hybrid Major Patens
7.4
All-Solid-State Battery Patents – Raw Materials
7.5
All-Solid-State Battery Patents – Battery Application
7.6 Core Patents by All-Solid-State Battery
Material
8. Current Status of ASB Developers
8.1
In Asia
8.1.1 Samsung Electronics
8.1.2 Korea Institute of Industrial
Technology
8.1.3 LG Chem
8.1.4 SK Innovation
8.1.5 Hyundai
Motors
8.1.6 Seven King Energy
8.1.7 Toyota
8.1.8 Hitachi Zosen
8.1.9 TDK
8.1.10 Ohara
8.1.11 Murata
8.1.12 Idemitsu Kosan
8.1.13 APB
8.1.14 FDK
8.1.15 NGK SPARK PLUG
8.1.16 Taiyo Yuden
8.1.17 CATL
8.1.18 Prologium
8.1.19 Ganfeng Lithium
8.1.20 TDL
8.1.21 Coslight
8.1.22 Welion New Energy
8.1.23 BYD
8.1.24 Daejoo Electronic Materials
8.1.25 ISU Chemical
8.1.26 CIS
8.1.27 Hannong Hawseong
8.2 In Europe
8.2.1 Ilika
8.2.2 Blue Solutions
8.2.3 IMEC
8.2.4 Embatt
8.2.5 Innolith
8.2.6 Saft
8.3 In North America
8.3.1 Solid Power
8.3.2 Solid Energy Systems
8.3.3 24M
8.3.4 Hydro Québec
8.3.5 Sakti3
8.3.6 SEEO
8.3.7 Brightvolt
8.3.8 Ionic Materials
8.3.9 TeraWatt
8.3.10 QuantumScape
8.3.11 Infinite
Power Solution
8.3.12 Prieto
8.3.13 Factorial
8.3.14 Amprius
8.3.15 EoCell
8.3.16 Cymbet
8.3.17 Johnson
energy storage
8.4 Current Status of Joint Partnership
for All-Solid-State Battery Development
8.5 Status of Supporting Agencies by
Region
8.5.1
Global Cooperation Through Inter-national Government Funding
8.5.1
Major Agencies in Asia
8.5.2
Major Agencies in Europe
8.5.3
Major Agencies in North America
8.6 Support
Programs by Region
8.6.1 Japan
8.6.2 Europe
9. SNE Insight
9.1 Drawbacks of Electrolyte by Type
(Large-area Battery)
9.2 Challenges and Development Direction
for Different Electrolytes
9.3 Various Types of Batteries (Hybrid/Semi
Solid)
9.4 Time of All-Solid-State Battery Mass
Production by Companies
9.5 Current Status and Future Direction of
All-solid-state Battery Anode/Cathode
9.6 Competition Amongst All-Solid-State
Battery Types (Oxide/Sulfide/Polymer)
9.7 Various Applications of
All-Solid-State Battery
9.8 Images of All-Solid-State Battery
Production Facilities
10. All-Solid-State Battery Market Outlook
10.1 Overview
10.2 Market Outlook