Abstract: A surface mount area-array integrated circuit package is disclosed. The package consists of a package substrate having conductive vias and internal and external conductive traces, a semiconductor die electrically and mechanically connected to the top surface of package substrate, an area-array of conductive surface mount terminations electrically and mechanically connected to the bottom of the package substrate, and at least one adhesive mass. The at least one adhesive mass is located on the bottom of the package substrate and replaces the conductive terminations in the area(s) where the joint strain energy density is calculated to be the greatest. When mounted on a substrate, the at least one adhesive mass adheres the package to the substrate. Increased mechanical and electrical reliability is thus achieved.

Abstract: The present invention discloses an organic light-emitting diode (LED). The organic light emitting diode is supported on an indium/tin oxide 110 (ITO) coated glass substrate 105. The organic light-emitting diode includes an amorphous-silicon (&agr;-Si) resistive layer 115 covering the ITO 110 coated glass substrate 105. The organic light-emitting diode 100 further includes a polyaniline (PANI) layer 120 covering the amorphous silicon (&agr;-Si) resistive layer 115 and an organic light emitting layer 125 overlying the PANI layer 120. And, the organic light-emitting diode 100 further has a conductive electrode layer 130 covering the light emitting layer 125. In a preferred embodiment, the amorphous silicon (&agr;-Si) resistive layer 115 functioning as a current limiting layer for limiting a current density conducted between the ITO 110 coated glass substrate 105 and the conductive electrode layer 130 under a maximum allowable current density of 1000 mA/cm2.

Abstract: A power transistor includes a plurality of emitter regions and a plurality of base contacts. In order to decrease base resistance, each of the plurality of emitter regions is adjacent to at least four base contacts. The entire transistor includes multiple emitter regions, e.g., greater than or equal to about 1,000 with no upper limit wherein the actual number of emitter regions is dependent on the desired current carrying capacity. The emitter regions are directly connected in parallel to the high current carrying metal layer of the transistor through vias or metal contact studs. The size of the emitter regions should be made as small as the process design rules will allow in order to allow an increase in the perimeter to area ratio of the emitter region which, for a given current, decreases the peak current density.

Abstract: A method is described of manufacturing a semiconductor material having a zone (200) with p-conductivity type and n-conductivity type regions with dopant concentrations and dimensions such that, when the n- and p-conductivity type regions are depleted of free charge carriers the space charge per unit area of the regions balances at least to the extent that the resulting electric field is lower than that at which avalanche breakdown would occur in the area. The method starts with a semiconductor body having adjacent a first major surface (10b) a first semiconductor region (2) of one conductivity type. A mask (3, 4, 5) is provided on the first major surface, having at least one mask area masking a part (2a) of the first region. At least a part of the unmasked first region (2) is then removed to provide at least one opening (7) in the first region.

Abstract: An insulator film provided on a region for arranging a Zener diode has a plurality of groove portions successively arranged in a direction D1 of extension of each semiconductor region forming the diode. Each groove potion extends in a width direction D2 of each semiconductor region, and has a depth T3. Each semiconductor region is arranged on the upper surface of the insulator film. Therefore, it follows that each semiconductor region has a plurality of irregular shapes arranged in the direction D1 of extension and the Zener diode has a peripheral length not only in the transverse direction D1 but also in a vertical direction D3, so that a p-n junction area in the Zener diode is increased. Thus, parasitic resistance of an input protection Zener diode is reduced for improving a gate insulator film protective function of the diode.

Abstract: A semiconductor device comprises a semiconductor element having electrodes and metal bumps are attached to the electrodes. The metal bumps include copper cores and gold surface layers covering the cores. In addition, the metal bumps may include gold bump elements and solder bump elements connected together.

Abstract: In a light irradiation device in which a light emitting element is attached to a printed circuit board, the heat radiation properties are enhanced, and improvement of the light emitting efficiency and reduction of the size and weight are realized. A Cu pattern covered with Ni is formed on a metal substrate 11. Light emitting elements 11 are mounted on the pattern in the form of a series circuit. Metal substrates in each of which the series connection is formed are connected to one another in parallel. Since Ni has excellent corrosion resistance and a high reflection efficiency, the surfaces of the substrates themselves can be used as reflective plates. A lens 37 is formed for each of the light emitting elements, whereby the emission efficiency can be further improved. Flow-stopping means 36 made of a brazing material is formed around each of the light emitting diodes 10. Also the surface of the brazing material is used as a reflecting surface.

Abstract: A first insulating layer is embedded within a semiconductor film formed on a base insulating film, a second insulating layer is formed on a portion of the semiconductor film, and a laser beam is irradiated from the top side (or from both the top side and the bottom side) of the substrate. A thermal gradient develops in the semiconductor film due to the thermal insulating effect of the base insulating film, due to the thermal insulating effect of the first insulating layer, and due to the antireflection effect and thermal insulating effect of the second insulating layer. The location and direction of lateral growth of crystal nuclei are controlled by utilizing these effects, and large size crystal grains can be obtained.

Abstract: A SRAM memory cell including an access device formed on a storage device is described. The storage device has at least two stable states that may be used to store information. In operation, the access device is switched ON to allow a signal representing data to be coupled to the storage device. The storage device switches to a state representative of the signal and maintains this state after the access device is switched OFF. When the access device is switched ON, the state of the storage device may be sensed to read the data stored in the storage device. The memory cell may be formed to be unusually compact and has a reduced power supply requirements compared to conventional SRAM memory cells. As a result, a compact and robust SRAM having reduced standby power requirements is realized.

Abstract: An integrated circuit structure is provided with a local interconnect layer and a first metal interconnect layer which are both capable of bridging over underlying conductive regions. The structure comprises a first dielectric layer formed to a height or thickness equal to or preferably exceeding the height of the highest conductive regions of the underlying integrated circuit devices; a second dielectric layer formed above the first dielectric layer; one or more local interconnects formed in the second dielectric layer; and a thin third dielectric layer formed over the second dielectric layer and the local interconnects therein. The thin third dielectric layer has a thickness not exceeding about 2000 Å, and preferably ranging from about 1000 Å to about 1500 Å. A first layer of metal interconnects is formed over the thin third dielectric layer.

Abstract: In a first aspect of the invention, a modified semiconductor substrate is provided. The modified substrate comprises: (1) a semiconductor substrate; (2) at least one buffer layer provided over at least a portion of the substrate; and (3) a plurality of trenches comprising (a) a plurality of internal trenches that extend into the semiconductor substrate and (b) at least one shallow peripheral trench that extends into the at least one buffer layer but does not extend into the semiconductor substrate. In another aspect, a method of selectively providing trenches in a semiconductor substrate is provided. According to a further aspect of the invention, a trench DMOS transistor structure that includes at least one peripheral trench and a plurality of internal trenches is provided.

Abstract: A semiconductor memory device which can suppress the occurrence of corner rounding through the resist patterning process to achieve a reduction in cell size and higher integration. A relationship between a channel width DT.W of the drive transistor, a channel length DT.L of the drive transistor, a channel width WT.W of the word transistor and a channel length WT.L of the word transistor is given by: (DT.W/WT.W)/(WT.L/DT.L)<1.2. The channel width DT.W of the drive transistor is equal to the channel width WT.W of the word transistor, to reduce steps in the patterns of p-type active regions. The channel length WT.L of the word transistor is larger than the channel length DT.L of the drive transistor, that is, (WT.L/DT.L)>1.

Abstract: A memory cell is provided. The memory cell includes a field-effect transistor having a source region, a drain region and a gate coupled to a wordline. The memory cell also includes a vertical bipolar junction transistor that is biased for use of the reverse base current effect to store data. The bipolar junction transistor has an emitter region formed within a source/drain region of the field-effect transistor. The emitter region is self-aligned with a minimum dimension isolation region adjacent to the memory cell and is coupled to a ground line. A portion of the source/drain region acts as the base of the bipolar junction transistor.

Abstract: Improved methods of packaging external fuses together with integrated circuit devices are described. A pair of frame strips are provided that each have an associated set of contact pads. A resistor paste is applied to one of the contact pad sets and the frame strips are laminated together by curing the resistor paste which is positioned between the contact pad sets. Dice are mounted to the opposite sides of the second contact pads to form integrated circuit devices having integrally packaged external fuses. The packaged devices are eventually singulated for use. In some embodiments, the contact pads each have downturned tabs that form wings on opposite sides of each die. When the dice are flip chips, a device may be attached to a substrate board by soldering both the bumps on the die and the tab wing tips to the substrate board. In a preferred embodiment, the resistor paste is a positive temperature coefficient resistor paste.

Abstract: There is provided a field effect transistor including a semi-insulating semiconductor substrate formed with a recess at a region in which a gate is to be formed, a gate base layer formed on the recess and composed of one of an InP layer and a plurality of layers including an InP layer, and a gate electrode formed on the gate base layer. The InP layer may be replaced with an InGaP layer, an AlXGa1−XAs (0≦X≦1) layer, an InXGa1−XAs (0≦X≦1) layer, or an InXAl1−XAs (0≦X<0.4 or 0.6<X≦1) layer. The above-mentioned field effect transistor prevents thermal instability thereof caused by impurities such as fluorine entering a donor layer to thereby inactivate donor. As a result, there is presented a highly reliable compound field effect transistor.

Abstract: A semiconductor apparatus and method for producing shallow trench isolation. The method includes the steps providing a semiconductor substrate member fabricated having a thin barrier oxide layer on which are fabricated a plurality of spaced apart silicon nitride pads. The regions between the spaced apart nitride pads delineate U-shaped regions for forming shallow isolation trenches and are layered with silicon oxide and polysilicon. The U-shaped regions provide a buffer region of oxide and polysilicon material adjacent opposing silicon nitride pads that prevent erosion of the nitride during etch formation of the isolation trench. The polysilicon is further etched to form a wider, second U-shaped region having sloped sidewalls that provide opposing spacer-forming buffer material that facilitates forming a V-shaped isolation trench region into the semiconductor substrate member a predetermined depth without eroding the silicon nitride pads.

Abstract: A wafer-scale assembly apparatus for integrated circuits and method for forming the wafer-scale assembly. A semiconductor wafer including a plurality of circuits is provided with a plurality of metal contact pads as electrical entry and exit ports. A first wafer-scale patterned polymer film carrying solder balls for each of the contact pads on the wafer is positioned opposite the wafer, and the wafer and the film are aligned. The film is brought into contact with the wafer. Radiant energy in the near infrared spectrum is applied to the backside of the wafer, heating the wafer uniformly and rapidly without moving the semiconductor wafer. Thermal energy is transferred through the wafer to the surface of the wafer and into the solder balls, which reflow onto the contact pads, while the thermal stretching of the polymer film is mechanically compensated. The uniformity of the height of the liquid solder balls is controlled either by mechanical stoppers or by the precision linear motion of motors.

Abstract: The as-deposited thickness of at least one of the oxide layers of a composite ONO dielectric film between a floating gate and a control gate of a non-volatile semiconductor device is deposited to a sufficient thickness such that, after the top oxide layer is cleaned, the control gate is spaced apart from the floating gate a distance corresponding to at least a minimum design data retention. Deposition is facilitated by forming one or more oxide layers at a thickness greater than the design rule by employing a relatively high dielectric constant material for the oxide layer or layers, such as aluminum oxide, titanium oxide or tantalum oxide. In this way, the capacitance of the ONO film between the floating gate and the control gate is maintained per design rule, avoiding a change in operating voltage. Embodiments include depositing a relatively thick top oxide layer to enable thorough cleaning without adversely reducing the total thickness of the ONO stack and, hence, achieving design data retention.

Abstract: Interconnections carrying the greatest currents within a semiconductor circuit are formed by an interconnect having at least one and commonly two or more ribs extending generally orthogonally from the interconnect line. The interconnect line is generally horizontal with the rib or ribs extending generally vertically downward from the interconnect line. The resulting interconnect occupies a surface area corresponding to that of the interconnect line yet includes the conductive material of both the interconnect line and the rib or ribs so that the interconnect has substantially less resistance than the interconnect line alone or the rib or ribs alone. The rib or ribs and interconnect line are produced from a conductive layer formed over an insulation layer after the insulation layer has been appropriately masked and etched.

Abstract: A lead frame has an array of mounting portions connected by joint bars, and each of the mounting portions has an island serving as an external connection terminal and a plurality of lead terminals extending from the island and serving as external connection terminals for a semiconductor chip to be mounted on an adjacent island along the array. An electrically conductive paste is applied to the island, and a semiconductor chip is mounted on the island. Then, the semiconductor chip is electrically connected to the lead terminals by wires. A resin layer is deposited over the semiconductor chip, a principal surface of the island, and principle surfaces the lead terminals, while leaving opposite surfaces of the island and the lead terminals exposed. A region surrounding the island and the lead terminals electrically connected to the island is cut off into a package.