| THIRD DIMENSION (3D) SEMICONDUCTOR, INC. Patent applications |
| Patent application number | Title | Published |
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| 20120040521 | VOLTAGE SUSTAINING LAYER WIHT OPPOSITE-DOPED ISLAND FOR SEMINCONDUCTOR POWER DEVICES - A semiconductor high-voltage device comprising a voltage sustaining layer between a n+-region and a p+-region is provided, which is a uniformly doped n (or p)-layer containing a plurality of floating p (or n)-islands. The effect of the floating islands is to absorb a large part of the electric flux when the layer is fully depleted under high reverse bias voltage so as the peak field is not increased when the doping concentration of voltage sustaining layer is increased. Therefore, the thickness and the specific on-resistance of the voltage sustaining layer for a given breakdown voltage can be much lower than those of a conventional voltage sustaining layer with the same breakdown voltage. By using the voltage sustaining layer of this invention, various high voltage devices can be made with better relation between specific on-resistance and breakdown voltage. | 02-16-2012 |
| 20090130828 | Method for Forming Voltage Sustaining Layer with Opposite-Doped Islands for Semiconductor Power Devices - A semiconductor high-voltage device comprising a voltage sustaining layer between a n+-region and a p+-region is provided, which is a uniformly doped n (or p)-layer containing a plurality of floating p (or n)-islands. The effect of the floating islands is to absorb a large part of the electric flux when the layer is fully depleted under high reverse bias voltage so as the peak field is not increased when the doping concentration of voltage sustaining layer is increased. Therefore, the thickness and the specific on-resistance of the voltage sustaining layer for a given breakdown voltage can be much lower than those of a conventional voltage sustaining layer with the same breakdown voltage. By using the voltage sustaining layer of this invention, various high voltage devices can be made with better relation between specific on-resistance and breakdown voltage. | 05-21-2009 |
| 20080315327 | TUNGSTEN PLUG DRAIN EXTENSION - A power metal-oxide-semiconductor field effect transistor (MOSFET) cell includes a semiconductor substrate. A first electrode is disposed on the semiconductor substrate. A voltage sustaining layer is formed on the semiconductor substrate. A highly doped active zone of a first conductivity type is formed in the voltage sustaining layer opposite the semiconductor substrate. The highly doped active zone has a central aperture and a channel region that is generally centrally located within the central aperture. A terminal region of the second conductivity type is disposed in the voltage sustaining layer proximate the highly doped active zone. The terminal region has a central aperture with an opening dimension generally greater than an opening dimension of the central aperture of the highly doped zone. An extension region is disposed in the voltage sustaining region within the central aperture of the highly doped active zone. | 12-25-2008 |
| 20080290442 | PROCESS FOR HIGH VOLTAGE SUPERJUNCTION TERMINATION - A method of manufacturing a semiconductor device having an active region and a termination region includes providing a semiconductor substrate having first and second main surfaces opposite to each other. The semiconductor substrate has an active region and a termination region surrounding the active region. The first main surface is oxidized. A first plurality of trenches and a first plurality of mesas are formed in the termination region. The first plurality of trenches in the termination region are filled with a dielectric material. A second plurality of trenches in the termination region. The second plurality of trenches are with the dielectric material. | 11-27-2008 |
| 20080283956 | PROCESS FOR HIGH VOLTAGE SUPERJUNCTION TERMINATION - A method of manufacturing a semiconductor device having an active region and a termination region includes providing a semiconductor substrate having first and second main surfaces opposite to each other. The semiconductor substrate has an active region and a termination region surrounding the active region. The first main surface is oxidized. A first plurality of trenches and a first plurality of mesas are formed in the termination region. The first plurality of trenches in the termination region are filled with a dielectric material. A second plurality of trenches in the termination region. The second plurality of trenches are with the dielectric material. | 11-20-2008 |
| 20080265317 | TECHNIQUE FOR FORMING THE DEEP DOPED COLUMNS IN SUPERJUNCTION - A method of manufacturing a semiconductor device is disclosed and starts with a semiconductor substrate having a heavily doped N region at the bottom main surface and having a lightly doped N region at the top main surface. There are a plurality of trenches in the substrate, with each trench having a first extending portion extending from the top main surface towards the heavily doped region. Each trench has two sidewall surfaces in parallel alignment with each other. A blocking layer is formed on the sidewalls and the bottom of each trench. Then a P type dopant is obliquely implanted into the sidewall surfaces to form P type doped regions. The blocking layer is then removed. The bottom of the trenches is then etched to remove any implanted P type dopants. The implants are diffused and the trenches are filled. | 10-30-2008 |
