English

RTX Raytheon Company will develop ultra wide bandgap semiconductors for ultraviolet lasers

196
2024-09-30 14:11:00
See translation

The UWBGS program will develop and optimize ultra wide bandgap materials and manufacturing processes for the next revolution in the semiconductor electronics field.

US military researchers need to develop new integrated circuit substrates, device layers, junctions, and low resistance electrical contacts for the new generation of ultra wide bandgap semiconductors. They found a solution from RTX company.

On September 13, 2024, personnel from the Defense Advanced Research Projects Agency (DARPA) located in Arlington, Virginia, announced a $5.3 million contract with the RTX Raytheon division in Arlington, Virginia, for the Ultra Wide Bandgap Semiconductor (UWBGS) project.

The UWBGS project will focus on developing and optimizing ultra wide bandgap materials and manufacturing processes to embrace the next revolution in the semiconductor electronics field. Ultra wide bandgap technology represents a new type of semiconductor that can be used for future RF and high-power electronics, deep ultraviolet electro-optic, quantum electronics, and system applications that must operate in harsh environments.

UWBGS will lay the foundation for producible and reliable high-performance ultra bandgap devices for various defense and commercial applications, such as high-power RF switches; High power density RF amplifier; High power RF protection device; High voltage switch; High temperature electronic devices; And deep ultraviolet lasers and light-emitting diodes.

This project will address some key technical challenges, such as achieving high-quality ultra wide bandgap materials, customizing the electrical properties of ultra wide bandgap materials, creating homogeneous and heterogeneous structures with abrupt junctions and low defect density, and ultra-low resistance electrical contacts. UWBGS will produce device testing structures to quantify improvements in these areas. To achieve the goal, the plan will fully utilize the latest developments in ultra wide bandgap materials.

Experts from the DARPA Microsystems Technology Office are focusing on two types of ultra wide bandgap devices: low defect density substrates with diameters greater than 100 millimeters; A device layer with high doping efficiency, mutated homojunctions and heterojunctions, low junction defect density, and ultra-low resistance electrical contacts.

DARPA researchers have stated that ultra wide bandgap materials such as aluminum nitride, cubic boron nitride, and diamond have the potential to revolutionize the application of semiconductor electronic devices, such as high-power RF switches and limiters, high-power density RF amplifiers for radar and communication systems, high-voltage switches for power electronics, high-temperature electronic devices and sensors for extreme environments, deep ultraviolet light emitting diodes (LEDs), and lasers.

However, the poor quality of ultra wide bandgap materials today limits their performance, and scientists must overcome multiple technical challenges to make this technology a success.

During the three-year UWBGS program, Raytheon engineers will focus on improving the material quality of device layers and junctions, as well as enhancing the electrical quality of metal contacts.

To this end, Raytheon Company will focus on three areas: large-area ultra wide bandgap substrates; Doping agents for ultra wide and wide forbidden homojunctions and heterojunctions; And a mixture of ultra-low resistance electrical contacts and ultra wide width forbidden materials.

Source: Yangtze River Delta Laser Alliance

Related Recommendations
  • SEI and Matik showcase the latest laser technology at a joint printing exhibition

    SEI Laser, a leading manufacturer of laser cutting systems, and its North American distributor Matik, Inc. will showcase SEI Laser's three most popular machines at the upcoming Joint Printing Expo. Visit booth C2811 on the C floor of the Joint Printing Expo to watch live demonstrations of MERCURY, X-TYPE, and Labelmaster.MERCURY is the ideal choice for cutting everything from paper and cardboard t...

    2023-10-17
    See translation
  • Researchers have proposed a new idea for quasi particle driven ultra bright light sources, which can be used in various applications from non-destructive imaging to chip manufacturing

    An international team of scientists is rethinking the fundamental principles of radiation physics, aiming to create ultra bright light sources. In a new study published in Nature Photonics, researchers from the Higher Institute of Technology in Lisbon, Portugal, the University of Rochester, the University of California, Los Angeles, and the Optical Applications Laboratory in France proposed the us...

    2023-10-24
    See translation
  • FGI utilizes Fraunhofer's LiDAR technology for maritime surveying

    The highly respected Finnish Institute of Geospatial Studies will utilize the advanced LiDAR system developed by the Fraunhofer Institute of Physical Measurement Technology for future ocean surface surveys. Significant progress is expected in data quality and on-site measurement efficiency, and the state-owned research department is collaborating with Fraunhofer IPM on a joint project. They are jo...

    2024-02-14
    See translation
  • Eurotech launches BestNet fiber rack mounting housing

    Fiber optic solution provider Eurotech announced the launch of a series of fiber optic rack mounting enclosures. The BestNet 19 inch top opening fiber optic interconnect unit is a fiber optic patch panel and cabinet, ideal for wiring, terminating, and managing fiber optic terminations, suitable for interconnect, cross connect, or splice applications in LAN environments. Modular fiber optic interco...

    2024-05-16
    See translation
  • Breakthrough in Silicon Based Room Temperature Continuous Wave Topological Dirac Vortex Microcavity Laser

    With the explosive growth of data traffic, the market is extremely eager for hybrid photonic integrated circuits that can combine various optical components on a single chip.Silicon is an excellent material for photonic integrated circuits (PICs), but achieving high-performance laser sources in silicon still poses challenges. The monolithic integration of III-V quantum dot (QD) lasers on silicon i...

    2023-10-26
    See translation