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STMicroelectronics announced a collaboration with Compuware Technology Inc, (Compuware), a leading provider of high-efficiency power supplies, on a reference design for server power using ST’s industry-leading silicon carbide (SiC), galvanic isolation, and microcontroller technologies. This reference design provides unparalleled power-supply options for digital power converter applications including server, datacenter and telecom power.
As demand for digital services continues to grow, fueled by Artificial Intelligence (AI), 5G, and the Internet of Things (IoT), keeping power usage under control is an important piece of the sustainability puzzle for data centers. The STDES-3KWTLCP reference design is perfect for a 3kW and higher wattage CRPS (Common Redundancy Power Supply) server power supply. This technical advancement comes with superior efficiency, faster switching, reduced energy losses, and better thermal management capabilities. In addition, this total system solution shortens time-to-market.
Compuware stands as a global power supply leader, holding the world record for the highest number of 80 PLUS Titanium certifications, ensuring unparalleled power efficiency. Engineered for excellence, Compuware power solutions are the ideal choice for HPC, AI, Deep Learning, Cloud, and advanced applications. With high power density, it optimizes space usage without compromising reliability and efficiency, setting a new performance standard in demanding computing environments.
“Combining ST’s latest SiC MOSFET, galvanic isolation, and microcontroller technologies with Compuware’s leading-edge power energy expertise is helping Compuware unleash our design creativity to develop high-density and -efficiency solutions. Now we can achieve 89W/in.3 power density, a small size, and high power output, this reference design is a great choice for power-hungry, high-performance computing applications,” according to Robin Cheng, Vice President at Compuware.
“With a focus on the Industrial market, ST’s Power & Energy Competence Center provides low-power, mid-power, and high-power solutions with the most advanced ST technologies to our customers, and this reference design- STDES-3KWTLCP can help our customers increase energy efficiency and reduce time-to-market using ST’s efficient and reliable power solutions,” said Eric Chou, Head of Power & Energy Competence Center at STMicroelectronics.
Original – STMicroelectronics
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Heraeus is making a multi-million-euro investment in Compound Semiconductor (Xiamen) Technology Co. (CSMH), a China-headquartered material supplier of premium industrial diamond. This strategic partnership aims to drive innovations in the semiconductor industry by leveraging diamond’s unique thermal conductivity and electrical insulation properties.
Heraeus signed an investment agreement with CSMH and the deal is expected to close in several weeks. As part of the agreement, Heraeus will hold a stake in the company and receive a seat on the board of directors.
Single-crystal diamond is ultra-wideband gap (UWBG) semiconductor material with the highest known thermal conductivity, surpassing existing thermal solutions such as copper by several times. Typical silicon has a thermal conductivity around 140 W/(m-K), copper is about 400 W/(m-K), and diamond has a much higher thermal conductivity up to 2200 W/(m-K). This allows heat to be dissipated more efficiently, enabling high-performance components to endure with maximum efficiency.
In addition to its superior heat dissipation properties, diamond also withstands extremely high voltages without causing an electric breakdown. This is critical for advancing miniaturization, efficiency, and robustness in power electronics.
“This investment reinforces Heraeus’ commitment to cutting-edge material start-ups and emphasizes its strategic focus on the semiconductor market. With CSMH’s outstanding diamond wafer technologies, we expect to set new standards to accelerate AI and cloud computing, as well as revolutionize inverter architecture for EVs,” said Dr. Steffen Metzger, member of the Heraeus Executive Board.
CSMH’s core business includes the production of polycrystalline and large-sized monocrystalline diamonds, which are particularly important for high-end applications in the semiconductor industry. With already 40 patents – consisting of 23 invention patents and 17 utility models – the company has successfully established itself as an innovator and technical specialist.
“We are very excited to partner with a global industry leader like Heraeus to realize our vision to be the world’s advanced compound semiconductor material provider. Being coined as ‘the ultimate semiconductor’, diamond has many excellent performance parameters such as high pressure resistance, large radio frequency, and high-temperature resistance,” noted Zhang Xing, CEO of CSMH. “The expertise that Heraeus has in global market resources, technology insights, and industrial-scale production of advanced materials will empower CSMH to promote diamond for more applications in the near future.”
Due to its exceptional physical and chemical properties, diamond’s other prominent application includes quantum sensors, optics/detection and high-power lasers, among others. CSMH’s target customers include major players in aerospace, power electronics, optical communication, Artificial Intelligence, photovoltaics, electric vehicles, and sensors.
Industrial diamonds can be produced in a matter of weeks, at a lower cost and with greater environmental friendliness. The cooperation with CSMH aligns with Heraeus’ vision of co-developing next-generation semiconductor solutions and preparing them for use. The combination of CSMH’s specialized expertise in diamond materials and Heraeus’ global market access promises a successful expansion into international markets.
Original – Heraeus
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LATEST NEWS / SiC / WBGAxcelis Technologies to Deliver Purion M™ SiC Implanters to Several Power Device Chipmakers in China
March 20, 2024
2 Min ReadAxcelis Technologies, Inc. announced multiple shipments of the Company’s Purion M™ SiC medium current implanter to several leading power device chipmakers located in China. The systems, which shipped in the first quarter, will be used for 150mm production of silicon carbide power devices supporting automotive, industrial, energy, and other power intensive applications.
President and CEO, Russell Low commented, “We look forward to supporting our customers as they expand their manufacturing capabilities in this growing silicon carbide power device segment. To meet market demand, chipmakers need to maximize their yield and add capacity, while meeting a range of technical challenges unique to power devices. The Purion M SiC Power Series platform’s common and flexible architecture, coupled with its uniquely differentiated high temperature capability, makes it ideally suited for this expanding application.”
Executive Vice President of Marketing and Applications, Greg Redinbo added “The Purion M SiC tool provides customers an implanter with a broad dose and energy range perfect for the early phases of a fab production ramp. The Purion M SiC sets the stage for the future introduction of the Purion H200™ SiC and Purion XE™ SiC. Use of the full Purion Power Series family enables higher fab productivity, lower cost of ownership and the ability to manufacture more advanced silicon carbide power devices.”
Original – Axcelis Technologies
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Recently the European Space Agency (ESA) started its search for the technological advantage to improve their systems. Lead by research fellow Dr. Antxon Arrizabalaga, the project is aimed at studying the latest semiconductor technologies and exploring the impact they can have in the future of the space industry.
During its research, Dr. Antxon Arrizabalaga is looking forward to answer the following questions:
- Which are the next system-level figures the space power industry wants to achieve?
- Can the wide bandgap semiconductors help to achieve these figures?
- Which semiconductor ratings are demanded by the space power industry for each application?
At the moment the research project lead by Dr. Arrizabalaga is focusing on the silicon carbide (SiC) power semiconductor devices, as they are better suited for the requirements of the high-power applications. The team has already had several meetings with the main European space power companies discussing the points of interest mentioned above.
As a result, ESA received rich feedback with industry requirements and new ideas. And as anticipated, most of the companies are looking to the ways to increase power of their systems.
Thus, the following applications were mentioned the most:
- Latching current limiters (LCL) for high power distribution
- High-voltage (HV), increasing the traditional bus voltage, and high-power (HP) DC-DC converters
- Rectification and synchronous rectification
- HP motor drives
- Very HV applications, around and over 1 kV
Figure 1. The ratings of the semiconductor devices required by the industry for each application
According to Dr. Arrizabalaga, ESA classifies innovations in three categories, according to the degree of innovation they bring when compared to the state-of-the-art:
- Enhancing. It brings a substantial improvement to the state-of-the-art system.
- Based on a technology replacement
- For SiC devices it means replacing the Si devices in an existing application and optimizing the system to get system-level benefits
- Low risk, development time and cost for manufacturers
- Straightforward adoption by industry and high probability of success
- Enabling. It will allow a new feature, new application, or even a new mission.
- Critical technologies for a certain feature, application or mission
- For SiC devices it means that without the adoption of such devices, the new desired feature, application or mission is no longer possible
- Medium-high risk for manufacturers, higher development cost and effort, since it has never been done before
- More challenging adoption by industry, and lower probability of success
- Game-changing. It promises to bring entirely new capabilities (not considered for this study).
Figure 2. Classification of the applications mentioned by the industry and the main drivers needed to be optimized for each application.
The European Space Agency research team is looking forward to support the successful adoption of the wide bandgap (WBG) power semiconductor devices by the European space power industry, giving the European industry a competitive edge.
Original – Dr. Antxon Arrizabalaga
