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Silicon Carbide Power Electronics: Market Shares, Market Forecasts, Market Analysis, 2022-2028

  • Report

  • 326 Pages
  • July 2022
  • Region: Global
  • Wintergreen Research, Inc
  • ID: 5631621

Silicon carbide SiC power electronics markets are forecast to grow at a CAGR of 37.56 % through 2028. Market growth is the result of rapid adoption of EV electric vehicles in response to an effort to decrease carbon emission worldwide. The SiC is harder, more durable, and permits more efficient implementation of power electronics in a variety of EV applications

The publisher announces that it has a new study on Silicon Carbide Power Electronics: Market Shares, Market Forecasts, Market Analysis, 2022-2028. The 2022 study has 326 pages, 180 tables and figures. Silicon Carbide represents next generation automation of EVs and home and campus electricity storage, a market in line for significant growth. It is expected to grow at a compound annual growth rate (CAGR) of 147.8% from 2021 to 2028.  

The electrical solid state battery energy industry will reshape the future. The integrated business model of storage is becoming an application for energy consumption. Amid a greater industry focus on battery technology, automakers with EVs in their lineups are scrambling to position themselves for the arrival of solid-state battery cells  

Solid state battery market expected to grow at a compound annual growth rate (CAGR) of 147.8% from 2021 to 2028. Rising demand for solid-state batteries among end-use sectors along with the rising research and development activities are focused on commercializing the battery. Solid state batteries drive an immediate shift to EVs  

Solid-State Batteries and silicon carbide represent next generation automation of electricity storage, a market in line for significant growth. It is expected to grow at a compound annual growth rate (CAGR) of 147.8% from 2021 to 2028. Rising demand for solid-state batteries among end-use sectors along with the rising research and development activities are focused on commercializing the battery. Lower costs for solid state batteries are expected to propel market growth. 

EVs represent a primary market. The electrical solid state battery energy industry will reshape the future. The integrated business model of storage is becoming an application for energy consumption. Amid a greater industry focus on battery technology, automakers with EVs in their lineups are scrambling to position themselves for the arrival of solid-state battery cells soon.

Table of Contents

Silicon Carbide Power Electronics Executive SummarySilicon Carbide Power ElectronicsSiC Power Electronics
1. Silicon Carbide Market Definition and Market Dynamics
1.1 Silicon Carbide
1.2 Description
1.3 Modern SiC Manufacture
1.4 Properties and Applications.
2. Silicon Carbide Market Shares and Market Forecasts
2.1 Silicon Carbide Market Driving Forces
2.2 Silicon Carbide Power Electronics Market Shares
2.3 Silicon Carbide Market Forecasts
2.4 Silicon Carbide Market Segment Forecasts
2.5 Silicon Carbide Pricing
2.5.1 Silicon Carbide Prices
2.5.2 Infineon
2.6 Silicon Carbide Regional Market Segments
2.6.1 US
2.6.2 Europe
2.6.3 Asia-Pacific
2.6.4 China
3 Silicon Carbide Technology and Configurations
3.1 Green Silicon Carbide, Black Silicon Carbide, And Other
3.2 Silicon Carbide Power Electronics Technology
3.2.1 SiC Wide-Bandgap Advantage
3.2.2 Silicon Carbide Research Directions
3.2.3 Wolfspeed Schematic, Pinout, and Performance Plots
3.3 Electronic Chip Manufacture
3.3.1 U.S. Opens First Major Silicon Carbide Chip Plant In New York, Wolfspeed
3.3.2 Taiwan Semiconductor Manufacturing Company
3.3.3 Wolfspeed Reference Designs and Supporting Tools
3.3.4 Foxconn
3.4 Silicon Carbide Structure - SiC
3.4.1 Bonding in Silicon Carbide - SiC
3.5 Silicon Carbide MOSFETs: Proven Reliability and Performance
3.5.1 Managing Impurities So Silicon Carbides Can Embrace the Electrical Properties of a Semiconductor
3.5.2 SiC Chemical Stability
3.5.3 Production of Silicon Carbide
3.6 Silicon Carbide: An Electro-Chemical Reaction of Silica (Quartz) with Carbon
3.7 n-Type SiC Substrate
3.8 Silicon Carbide (SiC) Wide Bandgap Materials
3.9 Silicon Carbide Ceramics Structure
3.10 Silicon Carbide Ceramics Properties
3.11 Silicon Carbide Ceramics Applications
3.12 Silicon Carbide Specifications 2”, 4”, 6”
4 Silicon Carbide Applications
4.1 Silicon Carbide Applications
4.2 SiC Chemical Compound Images
4.3 Typical Applications of SiC Devices
4.3.1 5G Infrastructure: Communication Power
4.3.2 Application of Flexible Transmission DC Circuit Breaker
4.4 Silicon Carbide Technology
4.4 Tesla's Innovative Power Electronics: The Silicon Carbide Inverter
4.5 Lucid Motors
5 Silicon Carbide Company Profiles
5.1 II-VI Incorporated
5.1.1 II-VI Incorporated Licenses Technology for Silicon Carbide Devices and Modules for Power Electronics
5.1.2 II-VI Partner Dynax - Silicon Carbide Substrates for Wireless RF Devices
5.1.3 II-VI Multiyear $100M Agreement to Supply Silicon Carbide Substrates
5.2 Advanced Materials Advanced Silicon Carbide Materials (ASCM)
5.3 Aymont Technology
5.4 Bosch
6.1.1 Bosch Silicon Carbide Clean-Room Space
5.4.2 BOSCH Circular Sanding Discs
5.5 Murugappa Group/Carborundum Universal Ltd (CUMI)
5.5.1 Murugappa_Group/Carborundum Universal
5.6 China Electronics Technology Group Corporation (CETC)
5.7 CM Advanced Ceramics
5.8 Dow Corning
5.9 Entegris
5.9.1 Entegris SUPERSiC-3CX
5.9.2 Entegris Revenue
5.9.3 Entegris - CMC Materials and Acquisitions
5.9.4 Entegris Segment Reporting
5.9.5 Specialty Chemicals and Engineered Materials Segment
5.9.6 Entegris Manufacturing Capacity
5.10 GlobalFoundries
5.11 Saint-Gobain Group/GNO Grindwell Norton
5.12 Hebei Synlight Crystal
5.13 Infineon
5.13.1 Infineon CoolSiC™ MOSFETs in Trench Technology
5.13.2 Infineon Fast/Wireless EV Charging
5.13.3 Wireless Methods for Power Transfer to Charge the Batteries
5.13.4 Infineon Silicon Carbide CoolSiC™ MOSFETs
5.13.5 Infineon AC/DC Battery Charger
5.13.6 Infineon Power Controllers for Solar
5.13.7 Infineon Automotive MOSFET
5.14 Kyocera
5.15 Lucid Motors
5.16 Macronix
5.17 Microchip Technology
5.17.1 Microchip Technology/Microsemi
5.17.2 Microchip Technology Revenue
5.18 Mitsubishi
5.19 Morgan Advanced Materials
5.19.1 Morgan Advanced Materials Chemical Vapor Deposition - Silicon Carbide (CVD-SiC)
5.20 Nippon Steel
5.21 NXP Semiconductors
5.22 Onsemi
5.22.1 On Semiconductor Acquisition of GT Advanced Technologies
5.23 Powerex/G.E. and Mitsubishi
5.24 Renesas Electronics
5.25 RHI Magnesita GMBH
5.26 Arrow Electronics/Richardson
5.27 Rohm
5.27.1 Rohm’s SiC MOSFET
5.27.2 Rohm SiC MOSFETs
5.27.3 Rohm’s 4th Generation SiC MOSFET
5.27.4 Rohm Automotive-Grade 6ch Buck Constant Current White LED Driver
5.27.5 Rohm/SiCrystal
5.28 Showa Denko
5.29 Sumitomo Metal
5.27.1 Sumitomo Metal High-Efficiency SiC Power Transistor
5.30 Solitron
5.31 ST Microelectronics
5.31.1 ST Microelectronics Corporate Profile
5.31.2 STMicroelectronics/Norstel
5.31.3 STMicroelectronics Power MOSFET, Silicon Carbide (“SiC”)
5.32 Taiwan Semiconductor Manufacturing Company
5.33 TankeBlue
5.33.1 TankeBlue Semiconductor Silicon Carbide Material Properties
5.34 Tesla
5.35 Toshiba
5.36 Wolfspeed
5.36.1 Wolfspeed Revenue
5.36.2 Wolfspeed Silicone Carbide Positioning
5.36.3 Wolfspeed Automotive-Qualified Silicon Carbide Power Module
5.36.4 Wolfspeed Utica NY Silicon Carbide Fab
5.36.5 General Motors/Wolfspeed
5.36.6 Wolfspeed XM3 series
5.36.7 Wolfspeed Manufacturing Capacity
5.36.8 Wolfspeed Silicon Carbide SiC Summary
5.37 X-FAB
5.37.1 Silicon Carbide High Voltage
5.38 Xiamen Powerway Advanced Material
5.39 Selected Silicon Carbide Companies
List of Tables and Figures
Figure 1. Significant EV Energy Conservation
Figure 2. Thermal conductivity of Silicon vs. Silicon carbide
Figure 3. Silicon Carbide
Figure 4. Silicon Carbide Image
Figure 5. Third-Generation Semiconductors High-Power Application, HighFrequency, Characteristics
Figure 6. Silicon Carbide Applications
Figure 7. Chemical Mechanical Planarization
Figure 8. Silicon Carbide Market Driving Forces
Figure 9. Silicon Carbide Power Electronics Market Shares, Dollars, Worldwide,2021
Figure 10. Silicon Carbide Power Electronics Market Shares, Worldwide, Dollars, 2021
Figure 11. Silicon Carbide Power Electronics Market Participant Descriptions, Worldwide, Dollars, 2021
Figure 12. Vendors Compete Primarily on The Basis of The Following Factors
Figure 13. Silicon Carbide Power Electronics Market Forecasts, Dollars, Worldwide, 2022-2028
Figure 14. Silicon Carbide Power Electronics Market Forecasts, Dollars, Worldwide, 2022-2028
Figure 15. Silicon Carbide Power Electronics Market Forecasts, Dollars, Worldwide, 2022-2028
Figure 16. Silicon Carbide Power Electronics Market Segments, Dollars, 2022 to 2028
Figure 17. Silicon-Carbide (SiC) Power Device Applications
Figure 18. SiC Application Outlook
Figure 19. Arrow Pricing on Silicon Carbide
Figure 20. Silicon Carbide Pricing
Figure 21. SiC MOSFER Die Costs
Figure 22. Mitsubishi Electric Focused on SiC for High-Power Devices
Figure 23. Silicon Carbide Ceramic Bearing Prices
Figure 24. SiC Prices
Figure 25. Silicon Carbide SiC Regional Market Segments, Dollars, 2021
Figure 26. Silicon Carbide (SiC) Market Regional Segments, US, Europe, China, Japan, RoW, Dollars, Worldwide, 2021
Figure 27. Benefits of Silicon Carbide
Figure 28. Advantages of Silicon Carbide
Figure 29. Semiconductor Silicon Carbide (SiC) Heat Sink
Figure 30. Semiconductor Silicon Carbide (SiC) Heat Sink
Figure 31. X-Fab Silicon Carbide Wafer
Figure 32. indicates the internal wiring schematic and pinout of the Wolfspeed SiC EAB450M12XM3
Figure 33. Wolfspeed SiC: Managing the Module Temperature by Proper Mounting and Cooling
Figure 34. Wolfspeed SiC MOSFET junction-case thermal impedance (left) and forward-bias safe operating area (right)
Figure 35. Wolfspeed Output Current Capability vs. Switching Frequency (Inverter Application)
Figure 36. Wolfspeed SiC DC Bus Voltage of 800 V (900 V max) with 360-A current
Figure 37. Wolfspeed KIT-CRD-CIL12N-XM3 Evaluation Platform for MX3 HalfBridge Module (Left) and the CDG12HBXMP XM3 Gate Driver
Figure 38. Common Impurities that Provide SiC Electrical Properties of a Semiconductor
Figure 39. Bandgap Energy Levels: Germanium, Gallium Arsenide, Silicon, Silicon Carbide
Figure 40. SiC Reduces Semiconductor Power Losses by 70%
Figure 41. Silicon Carbide Structure
Figure 42. Uninterruptable Power Supply UPS Current Flow in a Semiconductor88
Figure 43. 2 Inch Diameter Silicon Carbide SiC Substrate Specification
Figure 44. 4 Inch Diameter Silicon Carbide SiC Substrate Specification
Figure 45. 4 Inch Diameter Silicon Carbide SiC Substrate Specification
Figure 46. Silicon Carbide Products
Figure 47. EV Powertrain
Figure 48. II-VI SIC for Power Electronics
Figure 49. II-VI Engineered Materials and Compound Semiconductors
Figure 50. SiC Power Electronics in Electric Vehicles
Figure 51. SiC-Based RF Electronics: 5G Wireless
Figure 52. II-VI GaN/SiC power amplifiers
Figure 53. II-VI SiC Positioning
Figure 54. II-VI SiC Technologies
Figure 55. II-VI Multiyear Agreement to Supply Silicon Carbide Substrates
Figure 56. Advanced Silicon Carbide Materials (ASCM) Mirrors Materials
Figure 57. Silicon Carbide High Performance Mirrors and Telescopes
Figure 58. Advanced Silicon Carbide Materials (ASCM) CVC SiC® or Composites117
Figure 59. Bosch SiC Chips Fabricated on 8-Inch Wafers
Figure 60. Bosch Silicon Carbide Manufacturing
Figure 61. Bosch Silicon Carbide Sanding Disc
Figure 62. Carborundum Universal Metrics
Figure 63. Carborundum Universal Products
Figure 64. Carborundum Universal Coated Abrasives
Figure 65. Carborundum Universal Cumituff Material Features
Figure 66. Carborundum Universal Associates and Subsidiaries
Figure 67. CM Advanced Ceramics Sintered Silicon Carbide Main Components131
Figure 68. CM Advanced Ceramics Sintered Silicon Carbide Application Areas
Figure 69. CM Advanced Ceramics Sintered Silicon Carbide Main Uses
Figure 70. CM Advanced Ceramics - Sintered Silicon Carbide Standard Production Process
Figure 71. Dow Corning Prime Grade Portfolio of 150 mm SiC Substrate Product and Market Factors
Figure 72. Dow Corning Next-Generation Silicon Carbide Switching Devices
Figure 73. Entegris Silicon Carbide SuperSic Materials
Figure 74. Grindwell Norton Ltd. (GNO) Silicon Carbide (SiC) to Leading Abrasives, Refractory and Metallurgy
Figure 75. Grindwell Norton Ltd. (GNO) Silicon Carbide (SiC) Products:
Figure 76. Grindwell Norton Ltd. (GNO) Silicon Carbide (SiC) Metrics
Figure 77. Grindwell Norton Ltd. (GNO) Silicon Carbide (SiC) to Manufacturing Plants:
Figure 78. Infineon SiC Wafers to Produce Power Semiconductors for EVs
Figure 79. Infineon Silicon Carbide CoolSiC Product Portfolio
Figure 80. Infineon Silicon Carbide CoolSiC Product Industrial and Automotive Capabilities
Figure 81. Fast Silicon-Based Switch with a CoolSiC Producing Several Million Hybrid Modules
Figure 82. Infineon Energy-Efficient DC EV Charging Application Diagram
Figure 83. Infineon Offerings
Figure 84. Wireless Charging Application Diagram
Figure 85. Infineon Low Voltage Power Inverter Systems
Figure 86. Infineon CoolSiC™ MOSFET Product Sizes
Figure 87. Infineon CoolSiC™ MOSFET Product Offering
Figure 88. Infineon CoolSiC™ MOSFET Customer Benefits
Figure 89. Infineon Automotive MOSFET Product Advantages
Figure 90. Kyocera Residential Solar US
Figure 91. Kyocera Solar Energy
Figure 92. Kyocera Solar
Figure 93. Kyocera Analysis and Evaluation Technology
Figure 94. Kyocera Silicon Carbide Wafer Polishing Plate
Figure 95. Kyocera Silicon Carbide Wafer Polishing Plate
Figure 96. Microchip Silicon Carbide (SiC) Discretes
Figure 97. Microsemi Target Markets
Figure 98. Microsemi SiC Power Module
Figure 99. Microsemi SiC MOSFETs Advantages
Figure 100. Microsemi SiC Advantages
Figure 101. Microsemi SiC Applications
Figure 102. Mitsubishi Silicon Carbide Reduction of Electrical Resistance in MOSDET
Figure 103. Mitsubishi Silicon Carbide Reduction of Energy Loss
Figure 104. Mitsubishi UPS Data Center Uninterruptible, Conditioned, Reliable Power
Figure 105. Morgan-Seals-Bearings-Silicon-Carbide
Figure 106. Morgan-Seals Silicon-Carbide Production Environment
Figure 107. Morgan Advanced Materials Desirable Characteristics:
Figure 108. Morgan Silicon Carbide Material Families
Figure 109. Morgan Advanced Materials Silicon Carbide Materials - Silicon Carbide Bearing
Figure 110. Morgan Advanced Materials Silicon Carbide Materials - Silicon Carbide Bearing Applications
Figure 111. Morgan Advanced Materials Applications for Silicon Carbide
Figure 112. NXP SiC Tools and Services Available
Figure 113. Onsemi Target Markets
Figure 114. Onsemi Product Segment Technologies
Figure 115. On Semiconductor Revenue
Figure 116. On Semiconductor Revenue
Figure 117. Powerex Target Markets:
Figure 118. Powerex Manufacturing Capacity
Figure 119. Powerex Development Strategy
Figure 120. Powerex Mission Critical Applications
Figure 121. Rohm Silicon-Carbide (SiC) Power Devices
Figure 122. Rohm Silicon-carbide (SiC) Power Devices Surface Mount Package Types to Support Automated Mounting for Improved Productivity
Figure 123. Rohm Silicon-Carbide (SiC) Power Device Applications
Figure 124. Rohm Ultra-Compact Monolithic LED Drivers
Figure 125. Rohm Automotive LED Lighting (Front light) Block Diagram
Figure 126. SiCrystal Silicon Carbide Wafers
Figure 127. Rohm Crystal Manufacturing Functions
Figure 128. Rohm SiCrystal Silicon Carbide SiC-Wafer in Händen
Figure 129. New Systems of SiC Power Electronics
Figure 130. Requirements of Automotive OEMs for Electronic Systems
Figure 131. Sumitomo Metal SiC Transistors on Epitaxial Wafer
Figure 132. Sumitomo Metal Structure and On-Resistance in Of Next Generation VMOSFETs
Figure 133. Solitron SiC Characteristics
Figure 134. Solitron Silicon Carbide MOSFETs
Figure 135. Solitron’s Silicon Carbide (SiC) MOSFETs
Figure 136. ST Microelectronics SiC MOSFETs features of our include:
Figure 137. ST Microelectronics STPOWER SiC MOSFET Bare-Die in T&R
Figure 138. Model 3 Main Inverter - Featuring 24 SiC MOSFET modules from ST Microelectronics
Figure 139. Toshiba SiC MOSFETs
Figure 140. ST Microelectronics Performance of Wide-Bandgap Materials
Figure 141. ST Microelectronics Company Metrics
Figure 142. ST Microelectronics Automotive SiC Applications
Figure 143. ST Microelectronics Discrete & Power Transistors SiC Applications244
Figure 144. ST Microelectronics Analog, Industrial, & Power Conversion ICs Applications
Figure 145. Product Portfolio
Figure 146. ST Microelectronics IoT Product Portfolio
Figure 147. ST Microelectronics Global Presence
Figure 148. ST Microelectronics Serves 200,000 Customers, Including Tesla Among the Top 10
Figure 149. ASICS Based on ST Proprietary Technologies
Figure 150. Norstel AB Reportable Segments:
Figure 151. TankeBlue Semiconductor Silicon Carbide Material Properties
Figure 152. TankeBlue Semiconductor Silicon Carbide Applications
Figure 153. TankeBlue Semiconductor Silicon Carbide SiC Substrate Orientation
Figure 154. TankeBlue Semiconductor Silicon Carbide Orthogonal Misorientation
Figure 155. TankeBlue Semiconductor Headquarters
Figure 156. XinJiang TankeBlue Semiconductor
Figure 157. Toshiba 1200V SiC MOSFET TW070J120B
Figure 158. Toshiba SiC MOSFETs Merits
Figure 159. Toshiba SiC MOSFETs Features
Figure 160. Wolfspeed Revenue
Figure 161. Wolfspeed Silicone Carbide Positioning
Figure 162. Wolfspeed High-Performance X-Band Portfolio Key Features
Figure 163. Wolfspeed High-Performance X-Band Portfolio Key Benefits
Figure 164. Wolfspeed X-Band Product Lineups & X-band Diagram
Figure 165. Wolfspeed SiC X-Band Power Amplifier Line-Up Solutions Features and Benefits
Figure 166. Wolfspeed SiC X-Band Power Amplifier Line-Up Solutions Diagram274
Figure 167. Wolfspeed X-Band GaN on SiC Solutions Features and Benefits
Figure 168. Wolfspeed X-Band GaN on SiC Solutions Diagram
Figure 169. Wolfspeed X-Band Metrics
Figure 170. Wolfspeed Advantages of Silicon Carbide (SiC) Technology
Figure 171. Wolfspeed Automotive-Qualified 1200 V, 450A Silicon Carbide HalfBridge Module
Figure 172. Wolfspeed Power Module Portfolio
Figure 173. Wolfspeed Utica NY Silicon Carbide Fab
Figure 174. Wolfspeed Opened XM3 Half-Bridge Module
Figure 175. Wolfspeed MOSFET Switching Energy
Figure 176. Wolfspeed MOSFET Switching Reverse-Recovery Performance
Figure 177. X-FAB manufacturing Sites in Germany Positioning
Figure 178. X_Fab Silicon Carbide
Figure 179. PAM-XIAMEN Wide Silicon Carbide Wafer
Figure 180. PAM Xiamen SIC Epitaxial Wafer

Executive Summary

The study is designed to give a comprehensive overview of the Silicon Carbide Power Electronics market segment. Research represents a selection from the mountains of data available of the most relevant and cogent market materials, with selections made by the most senior analysts. Commentary on every aspect of the market from independent analysts creates an independent perspective in the evaluation of the market. In this manner the study presents a comprehensive overview of what is going on in this market, assisting managers with designing market strategies likely to succeed.

Companies Mentioned (Partial List)

A selection of companies mentioned in this report includes, but is not limited to:

  •  
  • Arrow Electronics/Richardson
  • Aymont Technology
  • Bosch
  • China Electronics Technology Group Corporation (CETC)
  • CM Advanced Ceramics
  • Dow Corning
  • Entegris
  • GlobalFoundries
  • Hebei Synlight Crystal
  • II-VI Incorporated
  • Infineon
  • Kyocera
  • Lucid Motors
  • Macronix
  • Microchip Technology
  • Mitsubishi
  • Morgan Advanced Materials
  • Murugappa Group/Carborundum Universal Ltd (CUMI)
  • Nippon Steel
  • NXP Semiconductors
  • Onsemi
  • Powerex/G.E. and Mitsubishi
  • Renesas Electronics
  • RHI Magnesita GMBH
  • Rohm
  • Saint-Gobain Group/GNO Grindwell Norton
  • Selected Silicon Carbide Companies
  • Showa Denko
  • Solitron
  • ST Microelectronics
  • Sumitomo Metal
  • Taiwan Semiconductor Manufacturing Company
  • TankeBlue
  • Tesla
  • Toshiba
  • Wolfspeed
  • X-FAB
  • Xiamen Powerway Advanced Material