In one general aspect, an apparatus can include a first trench disposed in a semiconductor region and including a gate electrode and a second trench disposed in the semiconductor region. The apparatus can include a mesa region disposed between the first trench and the second trench. The apparatus can include a source region segment of a first conductivity type disposed in a first side of the mesa region where the source region segment is included in a plurality of source region segments and where the plurality of source region segments are aligned along the longitudinal axis. The apparatus can include a body region segment of a second conductivity type disposed in a second side of the mesa region opposite the first side of the mesa region and having a portion disposed above the source region segment where the body region segment is included in a plurality of body region segments.

A semiconductor device includes a semiconductor layer with a thickness of at most 50 μm. A first metallization structure is disposed on a first surface of the semiconductor layer. The first metallization structure includes a first copper region with a first thickness. A second metallization structure is disposed on a second surface of the semiconductor layer opposite to the first surface. The second metallization structure includes a second copper region with a second thickness.

A semiconductor device according to the present disclosure includes: a gate electrode provided in a gate trench and provided so as to oppose a source region via a gate insulating film; a first bottom protection region of a second conductivity type provided below the gate insulating film; a plurality of first connection regions of the second conductivity type provided at a first interval in an extension direction of the gate trench and electrically connecting the first bottom protection region and a body region; a Schottky electrode provided in a Schottky trench; a second bottom protection region of the second conductivity type provided below the Schottky electrode; and a plurality of second connection regions of the second conductivity type provided at a second interval smaller than the first interval in an extension direction of the Schottky trench and electrically connecting the second bottom protection region and the body region.

A semiconductor device includes a semiconductor chip having a device forming surface on which a device structure is formed, a first conductive layer formed on the device forming surface of the semiconductor chip, a second conductive layer formed on the first conductive layer, a first wire that is connected to the second conductive layer and that is made of a material composed mainly of copper, and a third conductive layer that is formed between the first conductive layer and the second conductive layer and that includes a material harder than copper.

Disclosed is a manufacturing method of a trench-type power device. The manufacturing method comprises: forming a drift region; forming a first trench and a second trench in the drift region; forming a gate stack in the first trench; forming a doped region and a well region of P type in the drift region by performing first ion implantation; forming a source region of N type in the well region by performing second ion implantation. The well region in which a dopant concentration gradually decreases with depth is formed by the first ion implantation, an upper part of the well region is inverted by the second ion implantation to form the source region. The doped region and well region can be formed by self-alignment in a common ion implantation step, improving power device performance, reducing numbers of process steps of ion implantation and masks, reducing manufacturing cost.

Disclosed is a trench-type power device and a manufacturing method thereof. The trench-type power device comprises: a semiconductor substrate; a drift region located on the semiconductor substrate; a first trench and a second trench located in the drift region; a gate stack located in the first trench; and Schottky metal located on a side wall of the second trench, wherein the Schottky metal and the drift region form a Schottky barrier diode. The trench-type power device adopts a double-trench structure, which combines a trench-type MOSFET with the Schottky barrier diode and forms the Schottky metal on the side wall of the trench, so that the performance of the power device can be improved, and the unit area of the power device can be reduced.

A shielded gate MOSFET device and a manufacturing method thereof is provided. In the method, the shielded gate thick dielectric layers are formed with the thick oxide layer process at the bottoms in the trenches, poly is deposited in each trench and is back etched to leave gate poly on the side wall of each trench, whereas the portion, right in the center of each trench, of the thin poly layer is removed to be filled with the contact hole dielectric layer, which achieves the effect of streamlining the process flow.

A face-down mountable chip-size package semiconductor device includes a semiconductor layer and N (N is an integer greater than or equal to three) vertical MOS transistors in the semiconductor layer. Each of the N vertical MOS transistors includes, on an upper surface of the semiconductor layer, a gate pad electrically connected to a gate electrode of the vertical MOS transistor and one or more source pads electrically connected to a source electrode of the vertical MOS transistor. The semiconductor layer includes a semiconductor substrate. The semiconductor substrate functions as a common drain region for the N vertical MOS transistors. For each of the N vertical MOS transistors, a surface area of the vertical MOS transistor in a plan view of the semiconductor layer increases with an increase in a maximum specified current of the vertical MOS transistor.

The present invention introduces a new shielded gate trench SBR (Super Barrier Rectifier) wherein an epitaxial layer having special MSE (multiple stepped epitaxial) layers with different doping concentrations decreasing in a direction from a substrate to a top surface of the epitaxial layer, wherein each of the MSE layers has an uniform doping concentration as grown. Forward voltage V.sub.f is significantly reduced with the special MSE layers. An integrated circuit comprising a SGT MOSFET and a SBR formed on a single chip obtains benefits of low on-resistance, low reverse recovery time and high avalanche capability from the special MSE layers.

A semiconductor device includes: a semiconductor layer; a gate trench formed in the semiconductor layer; an insulating layer formed on the semiconductor layer; a gate electrode buried in the gate trench via the insulating layer; a gate wiring formed on the insulating layer and electrically connected to the gate electrode; and a protection trench formed in the semiconductor layer, wherein the semiconductor layer includes an outer peripheral region including outer edges of the semiconductor layer in a plan view and an inner region surrounded by the outer peripheral region, wherein the gate trench includes an outer peripheral gate trench portion arranged in the outer peripheral region and surrounded by the protection trench in a plan view, and wherein the outer peripheral gate trench portion and the protection trench are formed in a closed annular shape along the outer edges of the semiconductor layer in the outer peripheral region.