Abstract: A trench power MOSFET and a manufacturing method thereof are provided. The gate of the trench power MOSFET includes an upper doped region, a lower doped region and a middle region interposed therebetween. The upper has a conductive type reverse to that of the lower doped region, and the middle region is an intrinsic or lightly-doped region to form a PIN, P+/N? or N+/P? junction. As such, when the trench power MOSFET is in operation, a junction capacitance formed at the PIN, P+/N? or N+/P? junction is in series with the parasitic capacitance. Accordingly, the gate-to-drain effective capacitance may be reduced.

Abstract: A termination structure of a semiconductor device is provided. The semiconductor device includes an active area and a termination area adjacent to the active area, in which the termination area has the termination structure. The termination structure includes a substrate, an epitaxy layer, a dielectric layer, a conductive material layer and a conductive layer. The epitaxy layer is disposed on the substrate and has a voltage-sustaining region. The voltage-sustaining region has trenches parallel to each other. The dielectric layer is disposed in the trenches and on a portion of the epitaxy layer. The conductive material layer is disposed on the dielectric layer in the trenches. The conductive layer covers the trenches, and is in contact with the conductive material layer and a portion of the epitaxy layer, and is electrically connected between the active area and the termination area. A method for manufacturing the termination structure is also provided.

Abstract: A trench power MOSFET and a manufacturing method thereof are provided. The gate of the trench power MOSFET includes an upper doped region and a lower doped region which have different types of doping to form a PN junction. As such, when the trench power MOSFET is in operation, a junction capacitance formed at the PN junction is in series with the intrinsic gate-to-drain capacitance. Accordingly, the effective capacitance between the gate and the drain may be reduced.

Abstract: A manufacturing method of wafer level chip scale package structure is provided. Firstly, a wafer including a plurality of semiconductor devices is provided. An active surface of one of the semiconductor devices has an active an active region and an outer region. A first electrode and a second electrode are arranged on the active region, and the outer region has a cutting portion and a channel portion. Next, a patterned protecting layer having a plurality of openings is formed on the active surface to respectively expose the first and second electrodes and channel portion. Subsequently, a wafer back thinning process is performed and then a back electrode layer is deposited. Subsequently, the channel portion is etched to form a trench exposing the back electrode layer, and a conductive structure connected to the back electrode layer is formed through the trench. Thereafter, the wafer is cut along the cutting portion.

Abstract: A package structure and a packaging method of wafer level chip scale package are provided. The packaging method includes: providing a carrier, and disposing a plurality of chips on the carrier; forming a plurality of adhesive layers on a surface of the corresponding chips; covering a conductive cover plate, bonding the conductive cover plate with the chips through the adhesive layers, and dividing out a plurality of packaging spaces by the conductive cover plate for disposing the chips respectively; and providing an insulation material to fill the packaging spaces through via holes on the conductive cover plate to form a first insulation structure; finally, removing the carrier.

Abstract: A package structure and a packaging method of wafer level chip scale package are provided. The packaging method includes: providing a carrier, and disposing a plurality of chips on the carrier; forming a plurality of adhesive layers on a surface of the corresponding chips; covering a conductive cover plate, bonding the conductive cover plate with the chips through the adhesive layers, and dividing out a plurality of packaging spaces by the conductive cover plate for disposing the chips respectively; and providing an insulation material to fill the packaging spaces through via holes on the conductive cover plate to form a first insulation structure; finally, removing the carrier.

Abstract: A trench power MOSFET and a manufacturing method thereof are provided. The trench power MOSFET has a buried oxide layer formed in the epitaxial layer, wherein the buried oxide layer is located under a body region for changing a vertical electric field distribution to increase a breakdown voltage of the MOSFET, thereby obtaining a lower on-state resistance.

Abstract: A trench power MOSFET structure and fabrication method thereof is provided. The fabrication method comprises following process. First, form an isolating trench. Then, form at least two doped regions around the isolating trench. The doped regions are adjacent and the doping concentrations of two doped regions are different. Form an isolating structure in the isolating trench. Wherein, the junction profiles of the two doped regions are made by on implantation method for moderate the electric field distribution and decreasing the conduction loss.

Abstract: A power transistor having a top-side drain and a forming method thereof are provided. Firstly, a body layer is formed. An epitaxial layer is subsequently formed on the body layer. Then a gate trench is formed in the body layer and the epitaxial layer. Afterward, a gate structure is formed in the gate trench. Then, a doped drain layer is formed within the epitaxial layer. Next, a source is formed in contact with the body layer. Lastly, a drain is formed in contact with the dope drain layer. The structure and forming method disclosed can through arranging the drain at the top of the power transistor integrate with the newly high performance packaging design structure. Accordingly, the efficiency of the power transistor can be greatly enhanced.

Abstract: A trenched power semiconductor device on a lightly doped substrate is provided. The device has a base, a plurality of trenches including at least a gate trench, a plurality of first heavily doping regions, a body region, a source doped region, a contact window, a second heavily doped region, and a metal layer. The trenches are formed in the base. The first heavily doped regions are beneath the trenches respectively and spaced from the bottom of the respective trench with a lightly doped region. The body region encircles the trenches and is away from the first heavily doped region with a predetermined distance. The source doped region is in an upper portion of the body region. The contact window is adjacent to the edge of the base. The second heavily doped region is below the contact window filled by the metal layer for electrically connecting the second heavily doped region.

Abstract: A power transistor having a top-side drain and a forming method thereof are provided. Firstly, a body layer is formed. An epitaxial layer is subsequently formed on the body layer. Then a gate trench is formed in the body layer and the epitaxial layer. Afterward, a gate structure is formed in the gate trench. Then, a doped drain layer is formed within the epitaxial layer. Next, a source is formed in contact with the body layer. Lastly, a drain is formed in contact with the dope drain layer. The structure and forming method disclosed can through arranging the drain at the top of the power transistor integrate with the newly high performance packaging design structure. Accordingly, the efficiency of the power transistor can be greatly enhanced.

Abstract: A trench power MOSFET structure and fabrication method thereof is provided. The fabrication method comprises following process. First, form an isolating trench. Then, form at least two doped regions around the isolating trench. The doped regions are adjacent and the doping concentrations of two doped regions are different. Form an isolating structure in the isolating trench. Wherein, the junction profiles of the two doped regions are made by on implantation method for moderate the electric field distribution and decreasing the conduction loss.

Abstract: A closed cell trenched power semiconductor structure is provided. The closed cell trenched power semiconductor structure has a substrate and cells. The cells are arranged on the substrate in an array. Every cell has a body and a trenched gate. The trenched gate surrounds the body. A side wall of the trenched gate facing body has a concave.

Abstract: A trench power MOSFET structure and fabrication method thereof is provided. The fabrication method comprises following process. First, form an isolating trench. Then, form at least two doped regions around the isolating trench. The doped regions are adjacent and the doping concentrations of two doped regions are different. Form an isolating structure in the isolating trench. Wherein, the junction profiles of the two doped regions are made by ion implantation method for moderate the electric field distribution and decreasing the conduction loss.

Abstract: A method of manufacturing a trench power semiconductor structure is provided. The method comprising the steps of: providing a base, forming a dielectric pattern layer on the base to define an active region and a terminal region, wherein a portion of the base in the active region and the terminal region is covered by the dielectric pattern layer; selectively forming a first epitaxial layer on the base without being covered by the dielectric pattern layer; removing the dielectric pattern layer in the active region to form a gate trench on the base, and forming a gate dielectric layer on the first epitaxial layer and on the inner surface of the gate trench; forming the gate structure in the gate trench; utilizing the dielectric pattern layer to forming a body on or in the first epitaxial layer; and forming a source on the upper portion of the body.

Abstract: A fabrication method of a power semiconductor device is provided. Firstly, a plurality of trenched gate structures is formed in the base. Then, a body mask is used for forming a pattern layer on the base. The pattern layer has at least a first open and a second open for forming at least a body region and a heavily doped region in the base respectively. Then, a shielding structure is formed on the base to fill the second open and line at least a sidewall of the first open. Next, a plurality of source doped regions is formed in the body region by using the pattern layer and the shielding structure as the mask. Then, an interlayer dielectric layer is formed on the base and a plurality of source contact windows is formed therein to expose the source doped regions.

Abstract: A method of manufacturing a trench power semiconductor structure is provided. The method comprising the steps of: providing a base, forming a dielectric pattern layer on the base to define an active region and a terminal region, wherein a portion of the base in the active region and the terminal region is covered by the dielectric pattern layer; selectively forming a first epitaxial layer on the base without being covered by the dielectric pattern layer; removing the dielectric pattern layer in the active region to form a gate trench on the base, and forming a gate dielectric layer on the first epitaxial layer and on the inner surface of the gate trench; forming the gate structure in the gate trench; utilizing the dielectric pattern layer to forming a body on or in the first epitaxial layer; and forming a source on the upper portion of the body.

Abstract: A fabrication method of a trench power semiconductor structure is provided. First, a substrate with a first epitaxial layer is provided. Then, a dielectric layer is formed on the first epitaxial layer. A shielding layer is formed on the dielectric layer. Next, a portion of the shielding and the dielectric layers are removed to form a shielding structure and a dielectric structure on the first epitaxial layer, wherein the shielding structure is stacked on the dielectric structure. A selective epitaxial growth technique is utilized to form a second epitaxial layer surrounding the dielectric and the shielding structures on the exposed surface of the first epitaxial layer and the second epitaxial layer. Afterward, the shielding structure is removed to form a trench on the dielectric structure. A gate oxide layer is further formed on the inner surface of the trench. Lastly, a conducting structure is formed in the trench.

Abstract: A fabrication method of a power semiconductor device is provided. Firstly, a plurality of trenched gate structures is formed in the base. Then, a body mask is used for forming a pattern layer on the base. The pattern layer has at least a first open and a second open for forming at least a body region and a heavily doped region in the base respectively. Then, a shielding structure is formed on the base to fill the second open and line at least a sidewall of the first open. Next, a plurality of source doped regions is formed in the body region by using the pattern layer and the shielding structure as the mask. Then, an interlayer dielectric layer is formed on the base and a plurality of source contact windows is formed therein to expose the source doped regions.

Abstract: A closed cell trenched power semiconductor structure is provided. The closed cell trenched power semiconductor structure has a substrate and cells. The cells are arranged on the substrate in an array. Every cell has a body and a trenched gate. The trenched gate surrounds the body. A side wall of the trenched gate facing body has a concave.