How GaN is revolutionising power supply design Gallium Nitride (GaN) is presently in a position that will see it, alongside Silicon Carbide (SiC), revolutionise power supply design as a whole, moving away from traditional purely silicon (Si)-based analogue designs. So how is this design revolution happening, and where is GaN having the most impact? Read more here 👉 https://bit.ly/4c4juM6 #ElectronicSpecifier #Engineering #Tech #GaN #Electronics #GalliumNitride #SiliconCarbide
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Gallium Nitride (GaN) offers significant advantages over traditional silicon-based systems — from improved thermal management to faster switching speeds, #GaN is already being adopted across various industries and applications. As with any new, rapidly-adopted technology, there are “teething” problems that must be overcome. One challenge is that compound #semiconductor materials like GaN are traditionally difficult to manufacture. This difficulty arises from crystal and thermal coefficient mismatches within the substrate which create stresses at the interface and propagate through the wafer, causing cracks and other defects that complicate manufacturing. This thorny manufacturing problem is something we are trying to solve with our MST film; I’m hopeful it will help accelerate the adoption of GaN! Electronic Specifier Ltd did a wonderful job breaking down how GaN will revolutionize power supply design and its advantages over #silicon.
How GaN is revolutionising power supply design Gallium Nitride (GaN) is presently in a position that will see it, alongside Silicon Carbide (SiC), revolutionise power supply design as a whole, moving away from traditional purely silicon (Si)-based analogue designs. So how is this design revolution happening, and where is GaN having the most impact? Read more here 👉 https://bit.ly/4c4juM6 #ElectronicSpecifier #Engineering #Tech #GaN #Electronics #GalliumNitride #SiliconCarbide
How GaN is revolutionising power supply design
electronicspecifier.com
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Gallium nitride (GaN) technology offers many advantages over traditional silicon-based MOSFETs like higher efficiency and higher power density power supplies. When deciding to switch from silicon to GaN technology, a big question is how to get started. Read about the process to learn more:
Moving On to GaN Switches in Switch-Mode Power Supplies
analog.com
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Gallium nitride (GaN) technology offers many advantages over traditional silicon-based MOSFETs like higher efficiency and higher power density power supplies. When deciding to switch from silicon to GaN technology, a big question is how to get started. Read about the process to learn more:
Moving On to GaN Switches in Switch-Mode Power Supplies
analog.com
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Gallium nitride (GaN) technology offers many advantages over traditional silicon-based MOSFETs like higher efficiency and higher power density power supplies. When deciding to switch from silicon to GaN technology, a big question is how to get started. Read about the process to learn more:
Moving On to GaN Switches in Switch-Mode Power Supplies
analog.com
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Gallium nitride (GaN) technology offers many advantages over traditional silicon-based MOSFETs like higher efficiency and higher power density power supplies. When deciding to switch from silicon to GaN technology, a big question is how to get started. Read about the process to learn more:
Moving On to GaN Switches in Switch-Mode Power Supplies
analog.com
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Silicon Carbide (SiC) MOSFETs (Metal-Oxide-Semiconductor Field-Effect Transistors) have gained popularity in #power_electronics due to their superior performance compared to traditional silicon-based MOSFETs. Here are the advantages and disadvantages of #SiC MOSFETs in terms of reliability, cost, efficiency, and other factors: Advantages of SiC MOSFETs 1. Higher Efficiency: Low Switching Losses: SiC MOSFETs can operate at higher frequencies with reduced switching losses due to lower energy required for switching, improving overall efficiency in high-frequency applications. Lower Conduction Losses: SiC MOSFETs have lower on-resistance compared to silicon MOSFETs, especially at high temperatures, reducing conduction losses and improving efficiency in power conversion. 2. Higher Thermal Conductivity: SiC has higher thermal conductivity than silicon, allowing better heat dissipation. This enables SiC devices to operate at higher temperatures without the need for large heatsinks, reducing cooling requirements and increasing reliability. 3. Higher Breakdown Voltage: SiC MOSFETs can withstand much higher breakdown voltages, making them ideal for high-voltage applications, such as inverters and power supplies, where silicon devices may struggle to perform efficiently. 4. Smaller Size: Because of their higher efficiency and thermal conductivity, SiC MOSFETs can be used in smaller packages. This allows for compact designs and increased power density, which is valuable for applications like electric vehicles and renewable energy systems. 5. High Reliability at High Temperatures: SiC devices can operate reliably at junction temperatures of up to 200°C, whereas traditional silicon MOSFETs are limited to around 150°C. This makes SiC a better choice for high-temperature environments. 6. Fast Switching Speeds: SiC MOSFETs switch faster than silicon MOSFETs due to their higher electron mobility, enabling them to operate at higher frequencies, which improves performance in applications requiring high-speed switching. Disadvantages of SiC MOSFETs 1. High Cost: Manufacturing Complexity: SiC is harder to fabricate, and the manufacturing process is more complex and expensive than for silicon. This leads to higher upfront costs for SiC devices. High Material Costs: SiC wafers and substrates are more expensive than silicon, further increasing the price of SiC MOSFETs. 2. Gate Driver Complexity: High dV/dt and dI/dt: The high switching speeds (dV/dt and dI/dt) of SiC MOSFETs can lead to increased electromagnetic interference (EMI), which requires careful design of gate drivers and EMI filters, adding to the system cost and design complexity. Positive Turn-On: SiC #MOSFET are more prone to false turn-on due to high dV/dt during switching transitions, which complicates gate drive design and may require additional circuitry to avoid reliability issues. continued in the comment section 👇
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Powering the Future: Switch-mode power supplies are moving on to GaN (Gallium Nitride) switches, offering higher efficiency, faster switching speeds, and reduced heat loss. GaN technology is transforming power electronics with greater energy savings and compact designs. #PowerSupplies #GaNTechnology #EnergyEfficiency #PowerElectronics #electronicsnews #technologynews
Moving On to GaN Switches in Switch-Mode Power Supplies
timestech.in
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Wide bandgap (WBG) technology is revolutionizing power applications. Silicon carbide (SiC) and gallium nitride (GaN) transistors are leading this charge, offering unparalleled performance in various industries. However, with evolving standards and generations of WBG devices, adapting can be challenging. Gate drivers and DC/DC converters face the brunt of this evolution, often requiring costly design changes and safety recertification. RECOM's R24C2T25 2W isolated DC/DC converter is your ultimate solution to simplify SiC selection and evaluation. This innovative converter offers asymmetric regulated outputs, catering to various gate drive biases, from IGBT to SiC and GaN. Learn more! https://bit.ly/4cI0u7B #RECOM #Power #WBG #SiC #GaN #Innovation
New isolated DC/DC converter offers programmable outputs for SiC drive applications
recom-power.com
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IDTechEx explores the impact of engineered substrates on #EV_power #electronics. Their investigation highlights how advanced substrate materials can enhance performance, efficiency, and reliability in #electric_vehicles. #powerelectronics #powermanagements #powersemiconductor
IDTechEx Investigates the Impact of Engineered Substrates for EV Power Electronics
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