5.Silicon Carbide Technology

5-5-1 Choice of Polytype for Devices

5-5-1 Choice of Polytype for Devices As discussed in Section 4, 4H- and 6H-SiC are the far superior forms of semiconductor device quality SiC commercially available in mass-produced wafer form. Therefore, only 4H- and 6H-SiC device processing methods will be explicitly considered in the rest of this section. It should [...]

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5-5-2 SiC-Selective Doping: Ion Implantation

5-5-2 SiC-Selective Doping: Ion Implantation The fact that diffusion coefficients of most SiC dopants are negligibly small (at 1800°C) is excellent for maintaining device junction stability, because dopants do not undesirably diffuse as the device is operated long term at high temperatures. Unfortunately, this characteristic also largely (except for B at extreme temperatures [...]

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5-5-3 SiC Contacts and Interconnect

5-5-3 SiC Contacts and Interconnect All useful semiconductor electronics require conductive signal paths in and out of each device as well as conductive interconnects to carry signals between devices on the same chip and to external circuit elements that reside off-chip. While SiC itself is theoretically capable of fantastic electrical operation under extreme [...]

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5-5-4 Patterned Etching of SiC for Device Fabrication

5-5-4 Patterned Etching of SiC for Device Fabrication At room temperature, there are no known conventional wet chemicals that etch single-crystal SiC. Most patterned etching of SiC for electronic devices and circuits is accomplished using dry etching techniques. The reader should consult References 122–124 which contain summaries of dry SiC etching results obtained [...]

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5-5-5 SiC Insulators: Thermal Oxides and MOS Technology

5-5-5 SiC Insulators: Thermal Oxides and MOS Technology The vast majority of semiconductor-integrated circuit chips in use today rely on silicon metal-oxide– semiconductor field-effect transistors (MOSFETs), whose electronic advantages and operational device physics are summarized in Katsumata’s chapter and elsewhere . Given the extreme usefulness and success of inversion channel MOSFET-based electronics in [...]

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5-5-6 SiC Device Packaging and System Considerations

5-5-6 SiC Device Packaging and System Considerations Hostile-environment SiC semiconductor devices and ICs are of little advantage if they cannot be reliably packaged and connected to form a complete system capable of hostile-environment operation. With proper material selection, modifications of existing IC packaging technologies appear feasible for nonpower SiC circuit [...]

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5-6 SiC Electronic Devices and Circuits

5-6 SiC Electronic Devices and Circuits This section briefly summarizes a variety of SiC electronic device designs broken down by major application areas. SiC process and material technology issues limiting the capabilities of various SiC device topologies are highlighted as key issues to be addressed in further SiC technology maturation. [...]

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5-6-1 SiC Optoelectronic Devices

5-6-1 SiC Optoelectronic Devices The wide bandgap of SiC is useful for realizing short-wavelength blue and ultraviolet (UV) optoelectronics. 6H-SiC-based pn junction light-emitting diodes (LEDs) were the first semiconductor devices to cover the blue portion of the visible color spectrum, and became the first SiC-based devices to reach high-volume commercial sales . Because [...]

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5-6-2 SiC RF Devices

5-6-2 SiC RF Devices The main use of SiC RF devices appears to lie in high-frequency solid-state high-power amplification at frequencies from around 600 MHz (UHF-band) to perhaps as high as a few gigahertz (X-band). As discussed in far greater detail in References 5, 6, 25, 26, 159, and elsewhere, [...]

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5-6-3 SiC High-Temperature Signal-Level Devices

Most analog signal conditioning and digital logic circuits are considered “signal level” in that individual transistors in these circuits do not typically require any more than a few milliamperes of current and <20 V to function properly. Commercially available silicon-on-insulator circuits can perform complex digital and analog signal-level functions up to 300°C [...]

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