Patent application number | Description | Published |
20090181520 | Method and Structure for Dividing a Substrate into Individual Devices - A method for obtaining individual dies from a semiconductor structure is disclosed. The semiconductor structure includes a device layer, and the device layer in turn includes active regions separated by predefined spacings. Thick metal is selectively formed on backside of the device layer such that thick metal is formed on backside of active regions but not on backside of the predefined spacings. The semiconductor structure is then cut along the predefined spacings to separate the active regions with thick metal on their backside into individual dies. | 07-16-2009 |
20090273082 | METHODS AND DESIGNS FOR LOCALIZED WAFER THINNING - Methods for localized thinning of wafers used in semiconductor devices and the structures formed from such methods are described. The methods thin localized areas of the backside of the semiconductor wafer to form recesses with a bi-directional channel design that is repeated within the wafer (or die) so that no straight channel line crosses the wafer (or die). The bi-directional pattern design keeps the channels from being aligned with the crystal orientation of the wafer. The recesses are then filled by a solder ball drop process by dropping proper size solder balls into the recesses and then annealing the wafer to reflow the solder balls and flatten them out. The reflow process begins to fill in the recesses from the bottom up, thereby avoiding void formation and the resulting air traps in the reflowed solder material. Other embodiments are also described. | 11-05-2009 |
20100006928 | Structure and Method for Forming a Shielded Gate Trench FET with an Inter-electrode Dielectric Having a Low-k Dielectric Therein - A shielded gate trench field effect transistor (FET) comprises trenches extending into a semiconductor region. A shield electrode is disposed in a bottom portion of each trench. The shield electrode is insulated from the semiconductor region by a shield dielectric. A gate electrode is disposed in each trench over the shield electrode, and an inter-electrode dielectric (IED) comprising a low-k dielectric extends between the shield electrode and the gate electrode. | 01-14-2010 |
20100044785 | HIGH ASPECT RATIO TRENCH STRUCTURES WITH VOID-FREE FILL MATERIAL - A field effect transistor (FET) includes a trench extending into a semiconductor region. A conductive electrode is disposed in the trench, and the conductive electrode is insulated from the semiconductor region by a dielectric layer. The conductive electrode includes a conductive liner lining the dielectric layer along opposite sidewalls of the trench. The conductive liner has tapered edges such that a thickness of the conductive liner gradually increases from a top surface of the conductive electrode to a point in lower half of the conductive electrode. The conductive electrode further includes a conductive fill material sandwiched by the conductive liner. The FET further includes a drift region of a first conductivity type in the semiconductor region, and a body region of a second conductivity type extending over the drift region. Source regions of the first conductivity type extend in the body region adjacent the trench. | 02-25-2010 |
20100123225 | Semiconductor Die Structures for Wafer-Level Chipscale Packaging of Power Devices, Packages and Systems for Using the Same, and Methods of Making the Same - Disclosed are semiconductor die structures that enable a die having a vertical power device to be packaged in a wafer-level chip scale package where the current-conducting terminals are present at one surface of the die, and where the device has very low on-state resistance. In an exemplary embodiment, a trench and an aperture are formed in a backside of a die, with the aperture contacting a conductive region at the top surface of the die. A conductive layer and/or a conductive body may be disposed on the trench and aperture to electrically couple the backside current-conducting electrode of the device to the conductive region. Also disclosed are packages and systems using a die with a die structure according to the invention, and methods of making dice with a die structure according to the invention. | 05-20-2010 |
20100148325 | Semiconductor Dice with Backside Trenches Filled With Elastic Material For Improved Attachment, Packages Using the Same, and Methods of Making the Same - Disclosed are semiconductor dice with backside trenches filled with elastic conductive material. The trenches reduce the on-state resistances of the devices incorporated on the dice. The elastic conductive material provides a conductive path to the backsides of the die with little induced stress on the semiconductor die caused by thermal cycling. Also disclosed are packages using the dice, and methods of making the dice. | 06-17-2010 |
20100244126 | Structure and Method for Forming a Salicide on the Gate Electrode of a Trench-Gate FET - A method for forming a trench-gate FET includes the following steps. A plurality of trenches is formed extending into a semiconductor region. A gate dielectric is formed extending along opposing sidewalls of each trench and over mesa surfaces of the semiconductor region between adjacent trenches. A gate electrode is formed in each trench isolated from the semiconductor region by the gate dielectric. Well regions of a second conductivity type are formed in the semiconductor region. Source regions of the first conductivity type are formed in upper portions of the well regions. After forming the source regions, a salicide layer is formed over the gate electrode in each trench abutting portions of the gate dielectric. The gate dielectric prevents formation of the salicide layer over the mesa surfaces of the semiconductor region between adjacent trenches. | 09-30-2010 |
20100267200 | SEMICONDUCTOR DIE PACKAGES USING THIN DIES AND METAL SUBSTRATES - A semiconductor die package is disclosed. The semiconductor die package comprises a metal substrate, and a semiconductor die comprising a first surface comprising a first electrical terminal, a second surface including a second electrical terminal, and at least one aperture. The metal substrate is attached to the second surface. A plurality of conductive structures is on the semiconductor die, and includes at least one conductive structure disposed in the at least one aperture. Other conductive structures may be disposed on the first surface of the semiconductor die. | 10-21-2010 |
20110006409 | NICKEL-TITANUM CONTACT LAYERS IN SEMICONDUCTOR DEVICES - Semiconductor devices containing nickel-titanium (NiTi or TiNi) compounds (or alloys) and methods for making such devices are described. The devices contain a silicon substrate with an integrated circuit having a drain on the backside of the substrate, a TiNi contact layer contacting the drain on the backside of the substrate, a soldering layer on the contact layer, an oxidation reducing layer on the soldering layer, a solder bump on the soldering layer, and a lead frame attached to the solder bump. The combination of the Ti and Ni materials in the contact layer exhibits many features not found in the Ti and Ni materials alone, such as reduced backside on-resistance, ability to form a silicide with the Si substrate at lower temperatures, reduced wafer warpage, increased ductility for improved elasticity, and good adhesion properties. Other embodiments are described. | 01-13-2011 |
20110031596 | NICKEL-TITANUM SOLDERING LAYERS IN SEMICONDUCTOR DEVICES - Semiconductor devices containing nickel-titanium (NiTi or TiNi) compounds or alloys and methods for making such devices are described. The devices contain a silicon substrate with an integrated circuit, a contact layer contacting the substrate, a TiNi-containing soldering layer on the contact layer, an oxidation prevention layer on the soldering layer, a solder bump on the soldering layer, and a lead frame or PCB attached to the solder bump. The combination of the Ti and Ni materials in the soldering layer exhibits many features not found in the Ti and Ni materials alone, such as reduced wafer warpage, increased ductility for improved elasticity, decreased consumption of the Ni in the soldering layer, and decreased manufacturing costs. Other embodiments are described. | 02-10-2011 |
20110127601 | Semiconductor Devices and Methods for Making the Same - Semiconductor devices and methods for making such devices that are especially suited for high-frequency applications are described. The semiconductor devices combine a SIT (or a junction field-effect transistor [JFET]) architecture with a PN super-junction structure. The SIT architecture can be made using a trench formation containing a gate that is sandwiched between thick dielectric layers. While the gate is vertically sandwiched between the two isolating regions in the trench, it is also connected to a region of one conductivity type of the super-junction structure, thereby allowing control of the current path of the semiconductor device. Such semiconductor devices have a lower specific resistance and capacitance relative to conventional planar gate and recessed gate SIT semiconductor devices. Other embodiments are described. | 06-02-2011 |
20110201179 | METHOD AND STRUCTURE FOR DIVIDING A SUBSTRATE INTO INDIVIDUAL DEVICES - A method for obtaining individual dies from a semiconductor structure is disclosed. The semiconductor structure includes a device layer, and the device layer in turn includes active regions separated by predefined spacings. Thick metal is selectively formed on backside of the device layer such that thick metal is formed on backside of active regions but not on backside of the predefined spacings. The semiconductor structure is then cut along the predefined spacings to separate the active regions with thick metal on their backside into individual dies. | 08-18-2011 |
20110230046 | SEMICONDUCTOR DICE WITH BACKSIDE TRENCHES FILLED WITH ELASTIC MATERIAL FOR IMPROVED ATTACHMENT, PACKAGES USING THE SAME, AND METHODS OF MAKING THE SAME - Disclosed are semiconductor dice with backside trenches filled with elastic conductive material. The trenches reduce the on-state resistances of the devices incorporated on the dice. The elastic conductive material provides a conductive path to the backsides of the die with little induced stress on the semiconductor die caused by thermal cycling. Also disclosed are packages using the dice, and methods of making the dice. | 09-22-2011 |
20110244641 | Shielded Gate Trench FET with an Inter-electrode Dielectric Having a Low-k Dielectric Therein - A method for forming a shielded gate trench field effect transistor (FET) includes forming trenches in a semiconductor region, forming a shield electrode in a bottom portion of each trench, and forming an inter-electrode dielectric (IED) extending over the shield electrode. The IED may comprise a low-k dielectric. The method also includes forming a gate electrode in an upper portion of each trench over the IED. | 10-06-2011 |
20120142155 | HIGH ASPECT RATIO TRENCH STRUCTURES WITH VOID-FREE FILL MATERIAL - A field effect transistor (FET) includes a trench extending into a semiconductor region. A conductive electrode is disposed in the trench, and the conductive electrode is insulated from the semiconductor region by a dielectric layer. The conductive electrode includes a conductive liner lining the dielectric layer along opposite sidewalls of the trench. The conductive liner has tapered edges such that a thickness of the conductive liner gradually increases from a top surface of the conductive electrode to a point in lower half of the conductive electrode. The conductive electrode further includes a conductive fill material sandwiched by the conductive liner. The FET further includes a drift region of a first conductivity type in the semiconductor region, and a body region of a second conductivity type extending over the drift region. Source regions of the first conductivity type extend in the body region adjacent the trench. | 06-07-2012 |
20120168947 | Methods and Designs for Localized Wafer Thinning - Methods for localized thinning of wafers used in semiconductor devices and the structures formed from such methods are described. The methods thin localized areas of the backside of the semiconductor wafer to form recesses with a bi-directional channel design that is repeated within the wafer (or die) so that no straight channel line crosses the wafer (or die). The bi-directional pattern design keeps the channels from being aligned with the crystal orientation of the wafer. The recesses are then filled by a solder ball drop process by dropping proper size solder balls into the recesses and then annealing the wafer to reflow the solder balls and flatten them out. The reflow process begins to fill in the recesses from the bottom up, thereby avoiding void formation and the resulting air traps in the reflowed solder material. Other embodiments are also described. | 07-05-2012 |
20120220091 | METHODS OF MAKING POWER SEMICONDUCTOR DEVICES WITH THICK BOTTOM OXIDE LAYER - A method for forming thick oxide at the bottom of a trench formed in a semiconductor substrate includes forming a conformal oxide film by a sub-atmospheric chemical vapor deposition process that fills the trench and covers a top surface of the substrate. The method also includes etching the oxide film off the top surface of the substrate and inside the trench to leave a substantially flat layer of oxide having a target thickness at the bottom of the trench. | 08-30-2012 |