Global MOCVD Market By Type (III-V semiconductors, II-VI semiconductors, IV Semiconductors, and IV-V-VI Semiconductors), By Application (Optoelectronics, and Power electronics), By Region and Key Companies - Industry Segment Outlook, Market Assessment, Competition Scenario, Trends and Forecast 2021-2030 (Includes Business Impact of COVID-19)

                                          
Report updated on 11th September, 2021: Global MOCVD Market By Type (III-V semiconductors, II-VI semiconductors, IV Semiconductors, and IV-V-VI Semiconductors), By Application (Optoelectronics, and Power electronics), By Region and Key Companies - Industry Segment Outlook, Market Assessment, Competition Scenario, Trends and Forecast 2021-2030 (Includes Business Impact of COVID-19)
Trusted Business Insights has published a comprehensive market research report on, Global MOCVD Market by Product Type (III-V semiconductors, II-VI semiconductors, and other products), By Application (optoelectronics and power electronics), and by Region -Global Forecast to 2030, which offers a holistic view of the global MOCVD Market through systematic segmentation that covers every aspect of the target market.

The global MOCVD market is projected to be US$ 852.0 Mn in 2020 to reach US$ 1,928.5 Mn by 2030 at a CAGR of 8.5%.

The MOCVD equipment is used to produce compound semiconductors. MOCVD stands for Metalorganic Chemical Vapor Deposition. It is alternatively known as Metalorganic Vapour-Phase Epitaxy (MOVPE), as epitaxy means depositing a thin layer of atoms over a substrate. Atoms to be added to the crystal are passed over a heated semiconductor wafer in combination with organic gas molecules. Due to the heated wafer, it breaks down the molecules, and required atoms are deposited on the surface of the semiconductor wafer. In order to control the growth of these depositions, the process is carried out in a controlled environment.

MOCVD is used for creating a thin film on semiconductor wafers. It is also called as Organo-Metallic Chemical Vapor Deposition (OMCVD). The thickness of the layer can be easily controlled by the MOCVD process, and therefore the demand MOCVD is increasing for the manufacturing of electronic components such as diodes. The applications are for power electronics is increasing, and this is resulting in high demand for MOCVD across the globe. In addition, rising government initiatives for the use of various power electronics is expected to support the growth of the global market. For instance, the Chinese government is offering a subsidy to promote the use of MOCVD equipment for the manufacturing of electronic devices such as LED as the demand for LED lighting is on the rise.

Furthermore, the increasing number of end use applications such as autonomous technology; for example, the autonomous car is expected to result in high growth of MOCVD in the forecast period. Increasing focus on renewable energy sources across the globe is another key factor driving the growth of the global MOCVD market.


Global MOCVD Market Revenue (US$ Mn), 2021 to 2030


Increasing use of MOCVD by semiconductor manufacturers to develop highly efficient photovoltaic cells or triple junction solar cells is expected to bolster the growth of the global MOCVD market. In addition, rising use of MOCVD in the manufacturing of multilayer semiconductor structure that is used across optoelectronic or electronic equipment. The use of advanced MOCVD equipment in the manufacturing process of the semiconductor device increases performance, delivers high switching speed, and also increases efficiency. Furthermore, it is expected that the gallium nitride will replace silicon technology across the power semiconductor applications owing to its high thermal conductivity and high breakdown voltage. This is expected to support the growth of the target market during the forecast period.

In addition, increasing production of and use of advanced technology in electronic gadgets such as video games, smartphones, PDAs, DVD players, portable media players, home-theatre systems, printers and microwaves is expected to propel the growth of the global MOCVD market in the next 10 years.


Global MOCVD Market by Product Type, 2018


On the basis of product type, the market is segmented into III-V semiconductors, II-VI semiconductors, and Other Products. III-V semiconductors account for the majority share in the global MOCVD Market, followed by II-VI semiconductors.

On the basis of region, the market is segmented into North America, Europe, Asia Pacific, South America and MEA. Asia Pacific accounts majority share in global MOCVD market followed by North America.
The research report on the global MOCVD Market includes profiles of some of the major companies such as AIXTRON SE, Taiyo Nippon Sanso Corporation, Veeco Instruments Inc., CVD Equipment Corporation, Alliance MOCVD, HC SemiTek, Schunk GmbH (Xycarb Ceramics B.V.), JUSUNG Engineering Co. Ltd., SAMCO, Inc., etc.



Below are the active patents related to MOCVD Market.


Patent Number: US20040200413A1

Chemical vapor deposition apparatus

Abstract

A chemical vapor deposition apparatus is provided, which includes: a chamber having an inner space; a gas feed member for supplying a gas into the chamber; a susceptor disposed in the chamber and supporting a substrate; a diffuser partitioning the inner space of the chamber into first and second partitions and having a plurality of holes connecting the first partition and the second partition for gas communication; a diffuser frame incorporated into the diffuser; and an insulating frame disposed between the chamber and the diffuser.

Application File Date: 2003-12-31

Application Granted Date: 2007-05-15

Current Assignee: Samsung Display Co Ltd

Patent Number: US20150333129A1

Double Stepped Semiconductor Substrate

Abstract

A method for forming a double step surface on a semiconductor substrate includes, with an etching process used in a Metal-Organic Chemical Vapor Deposition (MOCVD) process, forming a rough surface on a region of a semiconductor substrate. The method further includes, with an annealing process used in the MOCVD process, forming double stepped surface on the region of the semiconductor substrate.

Application File Date: 2015-07-27

Application Granted Date: 2016-05-31

Current Assignee: Taiwan Semiconductor Manufacturing Co TSMC Ltd

Patent Number: US6887736B2

Method of forming a p-type group II-VI semiconductor crystal layer on a substrate

Abstract

A method of depositing a p-type magnesium-, cadmium- and/or zinc-oxide-based II-VI Group compound semiconductor crystal layer over a substrate by a metalorganic chemical vapor deposition technique. A reaction gas is supplied to a surface of a heated substrate in a direction parallel or oblique to the substrate. The p-type magnesium-, cadmium- and/or zinc-oxide-based II-VI Group compound semiconductor crystal layer is grown on the heated substrate, while introducing a pressing gas substantially in a vertical direction toward the substrate to press the reaction gas against the entire surface of the substrate.

Application File Date: 2003-04-23

Application Granted Date: 2005-05-03

Current Assignee: Nause Catherine D

Key Market Segments:

By Type

  
III-V semiconductors
  
II-VI semiconductors
  
IV Semiconductors
  
IV-V-VI Semiconductors

By Application

  
Optoelectronics
  
Power electronics


Key Market Players included in the report:


  
AIXTRON SE
  
Advanced Micro-Fabrication Equipment Inc.
  
Agnitron Technology Inc.
  
AIXTRON AG
  
Alliance MOCVD LLC
  
ASM International N.V.
  
CVD Equipment Corporation
  
HC SemiTek
  
JUSUNG Engineering Co. Ltd.
  
Nichia Corporation
  
NuFlare Technology Inc.
  
SAMCO Inc.
  
Schunk GmbH (Xycarb Ceramics B.V.)
  
Taiyo Nippon Sanso Corporation
  
Toyoda Gosei
  
Veeco Instruments Inc.
  
Xycarb Ceramics


Below are the key development related to MOCVD Market in 2020 and 2021.


June 2021: AMEC Introduces Prismo UniMax™ MOCVD System For High Performance Mini LED Production. Advanced Micro-Fabrication Equipment Inc. China (AMEC, SSE stock code: 688012), announced the launch of the Prismo UniMax™ system (UniMax) – an advanced Metal Organic Chemical Vapor Deposition (MOCVD) tool engineered for high performance Mini LED production which enables LED manufacturers enhance productivity and achieve lower cost of ownership (CoO). The system is the newest addition to AMECs portfolio of Prismo MOCVD products that are used by most of leading GaN-based LED manufacturers in the world. It can accommodate up to 4 reactors in one system which can be controlled independently. With its innovated local temperature adjustable heating system, the UniMax system can deliver excellent wavelength uniformity, repeatability and reliability for Mini LED production. Other novel features include optimized showerhead for better uniformity and production stability, and the large-sized susceptor which can significantly improve the production throughput and reduce the cost of ownership. Built for high throughput, the system offers industry-leading wafer capacity with extendibility to 164 4-inch or 72 6-inch wafers through susceptor configuration change. AMEC has received orders for this tool from leading customers in China while more customer demonstrations are in progress. The tools strengthen AMECs portfolio and offer global LED manufacturers new solutions for their Mini LED production challenges. With increasing demand for applications in LED-based TVs, tablets, laptops, monitors, smartphones, automotive displays and so on, Mini-LEDs are gaining popularity as an emerging technology which can significantly enhance the display quality by delivering superior brightness, precise dynamic response and excellent contrast. The UniMax system is engineered to help customers address the challenges in Mini LED production, achieving exceptional wavelength uniformity and reliability that are critical success imperatives. Source

February 2021: Veeco Announces Capacity Expansion Plan for Laser Annealing Technology That Serves the World’s Leading Semiconductor Customers. Veeco Instruments Inc. (NASDAQ: VECO) announced plans to expand its manufacturing capabilities in San Jose, California to meet growing demand for its advanced laser annealing technology that serves the world’s leading semiconductor technology companies. Veeco’s new, SEMI-compliant facility will serve as the company’s center of excellence for the development and production of laser annealing and advanced packaging lithography systems for semiconductor applications. Source

February 2021: Osram backs deep-UV LED disruptor Bolb. Lighting giant’s venture unit leads $16 million investment in California startup developing efficient short-wavelength emitters for germicidal applications. Osram’s “Fluxunit” investment division has acquired a significant equity stake in Bolb, which is developing deep-ultraviolet (UVC) LEDs for chemical-free disinfection of pathogens in air, water, and on surfaces - including efforts to mitigate coronavirus transmission. The Germany-headquartered lighting company led a $16 million round of series A venture funding in exchange for 20 per cent ownership of Livermore-based Bolb. Other investors in the round include Southeast Asian UVC-Tech Group, and the Silicon Valley based venture investor Walden International. Bolb says that the new funds will be used to expand its manufacturing capacity and global sales effort, among other things. Source

August 2020: AMEC Introduces MOCVD System For UV-LEDS. Advanced Micro-Fabrication Equipment Inc. China (AMEC), has launched the Prismo HiT3 system - an MOCVD tool engineered to mass produce deep ultra-violet light emitting diodes (DUV LEDs). The system is the newest addition to AMECs portfolio of Prismo MOCVD products. With a maximum reactor chamber temperature of 1400degC, the tool enables the growth of high-quality aluminium nitride and high-aluminium component material. Built for high throughput, the system can process up to 18 2-inch epitaxial wafers per run, with extendibility to 4-inch wafers. Early customers include China-based Jason Semiconductor Co., Ltd. (Jason) a producer of DUV LEDs for home applications, medical instruments, and products used for scientific research. DUV light has been used for decades as a disinfectant for industrial and consumer applications. It works by disrupting the DNA of bacteria and viruses, and killing their reproductive capabilities. The emergence of pathogens like SARS, MERS, and COVID-19 has increased demand for DUV LED products with the wavelength power to destroy new microorganisms. Source