Low voltage power MOSFET device and process for its manufacture
First Claim
1. A trench type MOSgated power semiconductor device comprising a water of silicon of one conductivity type;
- a plurality of spaced trenches formed into the top surface of said wafer and extending therein to a given depth;
an insulation coating lining the side walls and bottom of said trench;
a conductive gate body filling the interior of each of said trenches;
a channel region of a second conductivity type extending into the top of said wafer to a first depth which is less than said given depth;
a source region of said one conductivity type extending into said channel region to a second depth from the top of said wafer to define invertable channels along the sides of said trench in said channel region which extends between said first and second depths;
a source electrode formed on the top surface of said wafer and connected to said source and channel regions;
a drain electrode connected to the bottom of said wafer; and
a shallow diffusion of the second conductivity type surrounding the bottom of each of said trenches, said shallow diffusion having a concentration substantially less than that of said channel region and being at all times depleted by the built-in junction voltage at its junction to the surrounding one conductivity type material of said wafer.
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Accused Products
Abstract
A trench type power MOSFET has a thin vertical gate oxide along its side walls and a thickened oxide with a rounded bottom at the bottom of the trench to provide a low RDSON and increased VDSMAX and VGSMAX and a reduced Miller capacitance. The walls of the trench are first lined with nitride to permit the growth of the thick bottom oxide to, for example 1000 Å to 1400 Å and the nitride is subsequently removed and a thin oxide, for example 320 Å is regrown on the side walls. In another embodiment, the trench bottom in amorphized and the trench walls are left as single crystal silicon so that oxide can be grown much faster and thicker on the trench bottom than on the trench walls during an oxide growth step. A reduced channel length of about 0.7 microns is used. The source diffusion is made deeper than the implant damage depth so that the full 0.7 micron channel is along undamaged silicon. A very lightly doped diffusion of 1000 Å to 2000 Å in depth could also be formed around the bottom of the trench and is depleted at all times by the inherent junction voltage to further reduce Miller capacitance and switching loss.
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Citations
22 Claims
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1. A trench type MOSgated power semiconductor device comprising a water of silicon of one conductivity type;
- a plurality of spaced trenches formed into the top surface of said wafer and extending therein to a given depth;
an insulation coating lining the side walls and bottom of said trench;
a conductive gate body filling the interior of each of said trenches;
a channel region of a second conductivity type extending into the top of said wafer to a first depth which is less than said given depth;
a source region of said one conductivity type extending into said channel region to a second depth from the top of said wafer to define invertable channels along the sides of said trench in said channel region which extends between said first and second depths;
a source electrode formed on the top surface of said wafer and connected to said source and channel regions;
a drain electrode connected to the bottom of said wafer; and
a shallow diffusion of the second conductivity type surrounding the bottom of each of said trenches, said shallow diffusion having a concentration substantially less than that of said channel region and being at all times depleted by the built-in junction voltage at its junction to the surrounding one conductivity type material of said wafer. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16)
- a plurality of spaced trenches formed into the top surface of said wafer and extending therein to a given depth;
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17. In a MOSgated power semiconductor device comprising a drain conductor region of one conductivity type, a source conductive region of said one conductivity type, and a channel conductor region of the opposite conductivity type;
- a gate oxide layer extending from said source conductive region, across said channel conductive region and to said drain conductive region and a conductive gate electrode disposed on a surface of said gate oxide and operable to produce an inversion layer in said channel region to permit conduction between said source and drain regions;
a shallow, lightly doped diffusion of said opposite conductivity type in said drain conductor region adjacent said gate oxide, said shallow diffusion being doped only enough to deplete by the inherent junction voltage of the junction between said shallow diffusion and said drain region. - View Dependent Claims (18, 19, 20, 21, 22)
- a gate oxide layer extending from said source conductive region, across said channel conductive region and to said drain conductive region and a conductive gate electrode disposed on a surface of said gate oxide and operable to produce an inversion layer in said channel region to permit conduction between said source and drain regions;
Specification