Recently, the secondary battery market is expanding into the ESS and EV markets, from the application market for small ITs. The cathode material market of secondary batteries is also expected to increase in its demand thereby.
The Li-ion secondary battery was invented by Akira Yoshino in Japan around the year of 1985, which was commercialized by the company of SONY in 1991. At the time, the cathode material, used by SONY, was lithium cobalt oxide (LiCoO2; hereinafter, referred to as ‘LCO’). The LCO as a cathode material in Li-ion secondary batteries has nominal voltage of 3.7V and is the material where lithium can be reversibly intercalated and delithiated. It is still the most used material because it is easy to be synthesized and also has relatively good life characteristics. However, problems of such LCO began to emerge. One of the problems is that LCO, mainly composed of Co – which has limited reserves, is very expensive. Another problem is on the performance of the material: that the battery capacity is at most 150mAh/g, about a half of the theoretical capacity, due to the structural instability of LCO at the end of charging. Due to this, it is difficult to use LCO cathode materials in mid- and large-sized batteries for EVs and power storage, which becomes an unfavorable condition.
Accordingly, the cathode material, where this point has been improved, is lithium-nickel-cobalt-aluminum oxide (LiNi0.8Co0.15Al0.05O2; hereinafter, referred to as ‘NCA’). And the newly developed cathode material is lithium-nickel-cobalt-manganese oxide (LiNi1/3Co1/3Mn1/3O2; hereinafter, referred to as ‘NCM’), which was invented by 3M – holding the NCM111 patent. LG Chem has also developed LiNi0.5Co0.2Mn0.3O2 (NCM 523) material some of whose compositions, composed of NCM, have been adjusted. Recently, many researches have been conducted on high Ni-based cathode materials, such as NCM622, NCM811, etc.
In addition, there is lithium-manganese oxide (LiMn2O4; hereinafter, referred to as ‘LMO’) which structurally has a spinel structure; even though its capacity is 100mAh/g, lower than LCO, it has good output characteristics and excellent safety, and above all, it is applied to low-end products by using its low price as an advantage or being blended in some cathode materials for EVs.
The last one is lithium-Ferric Phosphate oxide (LiFePO4; hereinafter, referred to as ‘LFP’), which has the Olivine Structure; since its structural safety is high but the discharge voltage is relatively lower as appr. 3.5V, researches are in full swing on the high-voltage olivine cathode material in which Fe is replaced with Mn, Ni or the like.
In the case of the cathode materials that form the cathode among the four major components (cathode, anode, electrolyte, and separator) of Li-ion secondary batteries, since its proportion is large to the extent of accounting for about 30-40% of the total cost of Li-ion secondary batteries, it could be said that in order to commercialize large-sized lithium-ion secondary batteries whose cost is considered as the most important factor, improving the performance of cathode materials and lowering prices at the same time is an essential factor.
In the global cathode material market, 3 countries of Korea, China, and Japan are leading the market. Chinese companies have emerged as the absolute strong by increasing the quantity of supply along with the growth of major Chinese battery makers based on the domestic market and where Japanese companies are responding to the China's offensive based on their advanced technology for precursors. Korean cathode material companies are in the situation where they will have to confront the price competition with Chinese companies and simultaneously, to cope with the keen technical competition for cathode materials and precursors with Japanese makers.
In the future, the cathode material market is expected to lead to the keenly competitive phase among materials makers in 3 countries of Korea, China, and Japan, along with the great growth of LIB in the global EV market.
In this report, we described the technical trends on cathode materials by various types, and especially, have updated the development trend of cathode material technologies centered on Ni-rich NCM. Moreover, the mineral market used for cathode materials was also discussed in detail. The subject company for cathode materials included 6 Korean, 6 Japanese, and 9 Chinese companies.
In the market segment, we analyzed the demand and supply outlooks for the market by country, company, and cathode material type, for the last four years (2015-2018).
Chapter Ⅰ. Current Status and Development Trend of Cathode Material Technology
1. Introduction
1.1 Status of Cathode Material Development
1.2 Design Criteria for Cathode Materials
1.2.1 Ionic Bonding and Covalent Bonding
1.2.2 Types of Mott-Hubbard and Charge Transfer
1.2.3 Concept of Charge Transfer Reaction in 3d Transition Metal Oxide
1.2.4 Concepts of diffusion in Solid-Phase and of 2-Phase Coexistence Reaction
1.3 Properties Required for Cathode Materials
2. Type of Cathode Material
2.1 Layered-Based Compound
2.1.1 LiCoO2
2.1.2 LiNiO2
2.1.3 LiMO2 (M = Fe, Mn)
2.1.4 Ni-Mn Based
2.1.5 3-Component (Ni-Co-Mn) Based
2.1.6 Lithium-Excessive Compound
2.2 Spinel-Based Compound
2.2.1 LiMn2O4
2.2.2 LiMxMn2-xO4
2.3 Olivine-Based Compound
2.3.1 LiFePO4
2.3.2 LiMPO4 (M = Mn, Co, Ni)
3. Other Cathode Materials
3.1 Fluoride-Based Compound
Chapter Ⅱ. Ni-Rich NCM Technology
1. Introduction
2. Problems of Ni-Rich NCM
2.1 Cation Mixing
2.2 H2-H3 Phase Change
2.3 Residual Lithium Compounds
3. Challenges for Ni-Rich NCM
3.1 Transition Metal Doping
3.2 Surface Modification
3.3 Concentration Gradient Structure
Chapter Ⅲ. Manufacturing Process of Cathode Material
1. Manufacturing Process of Cathode Material
1.1 Mixing
1.2 Calcination
1.3 Crushing
1.4 Sieving
1.5 Magnetic Separation
2. Precursor Manufacturing Process
2.1 Reactor
2.2 Process after Reactor
3. Characteristic Evaluation of Cathode Material
3.1 Chemical Composition Analysis
3.2 Measurement of Specific Surface Area
3.3 Measurement of Particle Size
3.4 Measurement of Tapped Density
3.5 Measurement of Moisture Content
3.6 Measurement of Residual Lithium Carbonate
3.7 Thermal Analysis
3.8 Particle Strength
4. Manufacturing Process of Cathode Substrate
Chapter Ⅳ. Trends of Cathode Material Company
1. Korean Cathode Company
1.1 L&F
1.2 Umicore Korea
1.3 Ecopro BM
1.4 Cosmo AM&T
1.5 Iljin Materials
1.6 Posco Chemical
2. Japanese Cathode Company
2.1 Nichia
2.2 Sumitomo Metal Mining
2.3 Toda Kogyo
2.4 Mitsui Kinzoku
2.5 Nippon Denko
3. Chinese Cathode Company
3.1 Reshine
3.2 Shanshan
3.3 Easpring
3.4 B&M
3.5 Pulead
3.6 XTC
3.7 ZEC
3.8 CY Lico
3.9 Ronbay
Chapter Ⅴ. Outlook for Global LIB Market (by 2030)
1. Outlook for Global LIB Market
2. Outlook for Global LIB Market for Small-Sized IT
3. Outlook for Global LIB Market for Medium-Sized EV
4. Outlook for Global LIB Market for Large-Sized ESS
Chapter Ⅵ. Market Trend and Outlook for Cathode Material
1. Market Demand for Cathode Material
1.1 Cathode Demand by Country
1.2 Cathode Demand by Material
1.3 Cathode Market by Supplier
1.4 Demand Change Trends by Material
1.5 Cathode Demand by LIB Company
1.5.1 Samsung SDI's Usage Status for Cathode
1.5.2 LG Chem's Usage Status for Cathode
1.5.3 SKI's Usage Status for Cathode
1.5.4 Panasonic's Usage Status for Cathode
1.5.5 CATL’s Usage Status for Cathode
1.5.6 ATL's Usage Status for Cathode
1.5.7 BYD's Usage Status for Cathode
1.5.8 Lishen's Usage Status for Cathode
1.5.9 Guoxuan's Usage Status for Cathode
1.5.10 AESC's Usage Status for Cathode
1.6 Cathode Production Capacity
1.7 Trends of Cathode Prices
1.7.1 Price Structure of Cathode Materials
1.7.2 Price Trends by Cathode Material Type
1.7.3 Mineral Market Trends
1.7.3.1 Nickel
1.7.3.2 Cobalt
1.7.3.3 Manganese
1.7.3.4 Lithium