PYNMAX TECHNOLOGY CO., LTD. Patent applications |
Patent application number | Title | Published |
20120205773 | SCHOTTKY DIODE WITH LOWERED FORWARD VOLTAGE DROP - A Schottky diode with a lowered forward voltage drop has an N− type doped drift layer formed on an N+ type doped layer. The N− type doped drift layer has a surface formed with a protection ring inside which is a P-type doped layer. The surface of the N− type doped drift layer is further formed with an oxide layer and a metal layer. The contact region between the metal layer and the N− type doped drift layer within the P-type doped layer forms a Schottky barrier. An upward extending N type doped layer is formed on the N+ type doped layer and under the Schottky barrier to reduce the thickness of the N− type doped drift layer under the Schottky barrier. This lowers the forward voltage drop of the Schottky diode. | 08-16-2012 |
20120205771 | SCHOTTKY DIODE WITH LOW FORWARD VOLTAGE DROP - A Schottky diode with a low forward voltage drop has an N− type doped drift layer formed on an N+ type doped layer. The N− type doped drift layer has a first surface with a protection ring inside which is a P-type doped area. The N− type doped drift layer surface is further formed with an oxide layer and a metal layer. The contact region between the metal layer and the N− type doped drift layer and the P-type doped area forms a Schottky barrier. The height of the Schottky barrier is lower than the surface of the N− type doped drift layer, thereby reducing the thickness of the N− type doped drift layer under the Schottky barrier. This configuration reduces the forward voltage drop of the Schottky barrier. | 08-16-2012 |
20120205770 | SCHOTTKY DIODE WITH HIGH ANTISTATIC CAPABILITY - A Schottky diode with high antistatic capability has an N− type doped drift layer formed on an N+ type doped layer. The N− type doped drift layer has a surface formed with a protection ring. Inside the protection ring is a P-type doped area. The N− type doped drift layer surface is further formed with an oxide layer and a metal layer. The contact region between the metal layer and the N− type doped drift layer and the P-type doped area forms a Schottky contact. The P-type doped area has a low-concentration lower layer and a high-concentration upper layer, so that the surface ion concentration is high in the P-type doped area. The Schottky diode thus has such advantages of lowered forward voltage drop and high antistatic capability. | 08-16-2012 |