Silicon Carbide Semiconductor Companies

Silicon carbide semiconductors have gained increasing recognition across a range of applications due to their reduced switching losses and higher efficiency, in addition to greater reliability at higher temperatures and voltages.

Major players in the industry are developing technological innovations to strengthen their position in the market. Allegro diodes and MOSFETs, for instance, reduce switching loss at data centers and EV charging stations.

Fiven

Fiven is an industry leader in producing silicon carbide. Their products can be found across a wide array of industries and applications; Fiven produces powders and grains used for technical ceramics as well as composite materials; additionally they serve as raw material for power semiconductors and lithium-ion batteries. Fiven’s headquarters can be found in Oslo, Norway.

This company offers high-purity silicon carbide in the form of granules and powders for technical, refractory, abrasive and other applications. Furthermore, they provide toll processing as an optional service; technological innovation, customer relationships and ESG are also priorities of theirs.

In 2022, the company announced their plans to produce silicon carbide ingots and substrates for use by electronics industry customers, helping reduce defect density and energy efficiency of power semiconductors. They have also invested in widebandgap power device technologies; as well as developing a pilot furnace capable of producing high-purity silicon carbide from pot scrap with greater variability than geological quartz.

Silicon Carbide Semiconductors have seen tremendous growth due to the rising popularity of electric vehicles that require high-performance silicon carbide chips that allow longer range, faster charging speeds, and enhanced fuel economy. This growth trend can also be attributed to an increasing need for silicon carbide semiconductors in consumer electronics products like smartphones.

Silicon carbide semiconductor companies employ both organic and inorganic growth strategies in their pursuit of market leadership, including product launches, agreements, partnerships and expansions. One key competitor in the silicon carbide semiconductors sector is AKHAN Semiconductor founded in Hawaii and now serving customers throughout North America from their Lihue headquarters – such as United States and Canada customers.

SiCreate GmbH

Silicon carbide is a key element in high-performance composite materials, providing heat dissipation and cooling to extend their lifespan. CARBOREX silicon carbide powder additives enable superior stress tolerance and thermal management of complex composite structures allowing customers to meet today’s high performance standards and requirements.

SICREATE’s green silicon carbide product is used in technical ceramics and aerospace components production. Their patented process uses an ultra-high vacuum and solid state flash reaction to produce it, without post-treatment requirements – offering an environmentally sustainable alternative to traditional ceramics. Their products feature a crystal structure with exceptionally high purity levels and uniform granulometry; additionally their metallurgical grade silicon carbide resists moisture absorption as well as radiation damage, making it an excellent option for use in basic oxygen furnaces.

The company offers an array of services and solutions tailored specifically for the semiconductor industry, from design engineering platforms to product lifecycle management tools. Their cloud-based platform aggregates real-time data from multiple sources into one central place, simplifying management of complex supply chains and supporting business transformation efforts. Analytics and predictive modeling capabilities provided by this company enable customers to better identify opportunities for growth and profitability. Their team of experts are focused on helping customers improve performance and drive innovation; often working side-by-side with customers, learning their processes and requirements in order to develop an innovative business model which has revolutionized how companies conduct their businesses.

CoolCAD Electronics

CoolCAD Electronics designs and fabricates wide bandgap silicon carbide semiconductor transistors and integrated circuits, offering research & development, computer-aided design & simulation services as well as cryogenic testing services for cryogenic applications and radiation testing – serving customers from aerospace & defense, automotive, data communications, green energy and military markets.

CoolCAD has been working with new electronics based on the unique properties of silicon carbide (SiC) for more than a decade, using this new technology to operate under conditions where traditional silicon-based devices fail. By designing and fabricating SiC-based power, optoelectronic, and high temperature devices and circuits in collaboration with University of Maryland NanoCenter FabLab it has achieved this.

CoolCAD’s SiC MOSFETs can be utilized in power converters that will help improve efficiency, reliability and heat tolerance in advanced EV battery and charging systems. These power converters convert DC electricity from batteries into AC electricity for charging purposes.

CoolCAD’s product portfolio extends well beyond EV systems; in addition to developing them, its silicon carbide products will transform transportation and energy infrastructures worldwide. Working closely with NASA on optoelectronics that will enable spacecraft to detect molecules in outer space or planets is one such effort.

CoolCAD Electronics was established as a private firm in 2006 with six patents, and funded through grants from NASA and Defense Advanced Research Projects Agency grants. Since the inception of their business operations, their revenue has experienced over 2000% growth annually! Based out of College Park Maryland for further inquiries about CoolCAD visit their website: CoolCAD Electronics

Free Form Fibers

Free Form Fibers of Saratoga Springs, New York has developed a process using laser-driven chemical vapor deposition (LCVD) to produce inorganic high performance fibers (HPFs). HPFs are typically used when an unusual combination of extreme material properties is required that cannot be satisfied by existing metal, carbon, glass vegetal or mineral fibers; applications include military/aerospace applications (turbo machinery/rockets/advanced structures), automobile, biomedical and energy industries.

Silicon Carbide Market Outlook The products produced by this company are tailored for use with wide bandgap power devices found in electric vehicles. As opposed to traditional geared cars, electric cars require much higher voltage power to function efficiently – this demand should increase the size of silicon carbide market over time.

Free Form Fibers has built relationships with New York state suppliers to assist their transition from research and development to commercialization, and has received several prime federal contracts through Small Business Innovation Research (SBIR) or other funding mechanisms.

By form, the silicon carbide fibers market can be divided into continuous and woven segments. Of these types, continuous is expected to lead during the forecast period due to its superior performance in high radiation environments as used for nuclear power generation applications, light weight strength properties being key factors contributing to its dominance.

This report also segments the market by usage, with composites and non-composites serving as key application segments. Composites are projected to experience the fastest compounded compound annual compound annual compound annual compounded compound annual compound compound annual compound annual compound growth during 2024-2032 due to their ability to withstand harsh environmental conditions and stressors; on the other hand, woven silicon carbide fibers require additional materials and have slower projected compound annual compound annual compound annual compound annual compound annual compound compound compound annual compound compound growth rates.

GeneSiC

GeneSiC Semiconductor is an industry-leading silicon carbide power semiconductor company, producing products ranging from MOSFETs and Schottky MPS diodes rated up to 6.5kV in various packages or as bare die. They serve applications from automotive to energy storage and renewable power generation.

At GeneSiC, they understand the challenge of increasing efficiency and reliability is paramount to meeting consumer demands for energy services. Their silicon carbide solutions help power converters operate cooler, faster and more reliably while their devices help power systems remain cool in operation.

Silicon Carbide (SiC) MOSFETs from their silicon carbide MOSFET range feature the lowest on-state voltage drop available commercially and thus allow higher switching frequencies to be reached. Furthermore, their temperature coefficient is excellent and they can withstand surge currents to make these ideal components for continuous current mode PFC circuits where voltage-frequency conversion plays an integral part.

GeneSiC also provides Schottky diodes that boast superior avalanche capability, making them suitable for use in DC/DC converters in AC/AC voltage-frequency conversion topologies. Their low VF of 1.3 V and minimized capacitive charge helps minimize power losses for improved system performance; their 100% production tested avalanche capacity ensures robustness and ruggedness compared to comparable products on the market.

GeneSiC’s silicon carbide-based power semiconductors are an indispensable element in renewable energy systems and other high-power electronics, serving both renewable energy harvesting systems as well as electric utility and military hardware more efficiently, thus saving costs and decreasing waste. They play a crucial role in efficiently harvesting renewables as well as cutting global emissions by lowering energy needs to operate these systems efficiently, as well as helping electric utility and military hardware reduce energy use while saving costs and waste reduction.