A direct-write laser conversion technique was used to produce n-type and p-type doped tracks on SiC substrates. Polycrystalline and single-crystal SiC substrates were investigated. The tracks irradiated in an inert gas exhibit a higher electrical resistance than those generated in dopant-containing atmospheres. The effects of various processing parameters, such as the laser-matter interaction time, laser-beam characteristics, number of exposures to the laser beam, and ambient gas in the laser processing chamber, are examined. The laser conversion technique can be used for selective-area doping of silicon carbide substrates to build semiconductor devices for high-temperature applications
A laser solid phase diffusion technique has been utilized to fabricate endolayers in n-type 6H-SiC s...
Direct write laser doping is used to fabricate a PIN diode in a semi-insulating 6H-SiC wafer compris...
Silicon carbide is a promising semiconductor material for high voltage, high frequency and high temp...
A direct-write laser conversion technique was used to produce n-type and p-type doped tracks on SiC ...
Highly conductive tracks on silicon carbide were produced using a direct conversion technique involv...
A direct conversion technique has been demonstrated to produce highly conductive tracks on silicon c...
Conventional direct write processes are multi-step requiring at least one additional process to chan...
Highly conductive phases have been generated on different polytypes of SiC substrates using a laser ...
Highly conductive phases have been generated on different polytypes of SiC substrates using a laser ...
Laser direct-write and doping technique (LDWD) is used to introduce variations in electric propertie...
Highly conductive tracks are generated in low-doped epilayers on 4H-SiC wafers using a laser-direct ...
Nanosecond pulsed Nd:yttrium-aluminum-garnet laser treatment is applied to alter the electric proper...
Nanosecond pulsed Nd:yttrium-aluminum-garnet laser treatment is applied to alter the electric proper...
Laboratory prototype SiC diodes are fabricated using a combination of gas immersion laser doping (GI...
A laser solid phase diffusion technique has been utilized to fabricate endolayers in n-type 6H-SiC s...
A laser solid phase diffusion technique has been utilized to fabricate endolayers in n-type 6H-SiC s...
Direct write laser doping is used to fabricate a PIN diode in a semi-insulating 6H-SiC wafer compris...
Silicon carbide is a promising semiconductor material for high voltage, high frequency and high temp...
A direct-write laser conversion technique was used to produce n-type and p-type doped tracks on SiC ...
Highly conductive tracks on silicon carbide were produced using a direct conversion technique involv...
A direct conversion technique has been demonstrated to produce highly conductive tracks on silicon c...
Conventional direct write processes are multi-step requiring at least one additional process to chan...
Highly conductive phases have been generated on different polytypes of SiC substrates using a laser ...
Highly conductive phases have been generated on different polytypes of SiC substrates using a laser ...
Laser direct-write and doping technique (LDWD) is used to introduce variations in electric propertie...
Highly conductive tracks are generated in low-doped epilayers on 4H-SiC wafers using a laser-direct ...
Nanosecond pulsed Nd:yttrium-aluminum-garnet laser treatment is applied to alter the electric proper...
Nanosecond pulsed Nd:yttrium-aluminum-garnet laser treatment is applied to alter the electric proper...
Laboratory prototype SiC diodes are fabricated using a combination of gas immersion laser doping (GI...
A laser solid phase diffusion technique has been utilized to fabricate endolayers in n-type 6H-SiC s...
A laser solid phase diffusion technique has been utilized to fabricate endolayers in n-type 6H-SiC s...
Direct write laser doping is used to fabricate a PIN diode in a semi-insulating 6H-SiC wafer compris...
Silicon carbide is a promising semiconductor material for high voltage, high frequency and high temp...
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