Abstract: A lower electrode of a capacitor for use in a semiconductor device includes a first semiconductor layer having a predetermined impurity concentration and a second semiconductor layer having an impurity concentration higher than that of the first semiconductor layer. As a result, intensification of an electric field at an end portion of the capacitor can be reduced. In addition, a word line is formed of a buffer layer and a main conductor layer to reduce a parasitic capacitance between the lower electrode of the capacitor and the word line.

Abstract: In a semiconductor integrated circuit device having cells comprising circuit elements including MISFETs, and a multi-layer wiring structure, wirings of a first layer connected to semiconductor regions of the MISFETs (source and drain regions) are formed almost in the entire area over the regions to shunt the regions. Power supply wiring are formed of second layer wirings. First layer wirings and the semiconductor regions are connected through a plurality of contact holes. The power supply wirings are formed to cover at least part of the semiconductor regions. In accordance with another aspect, macro-cells are formed by basic cells, including a plurality of MISFETs with the direction of gate length aligned in a first direction, regularly arranged in the first direction and in a second intersecting direction.

Abstract: A method is provided for forming a polysilicon buried contact of an integrated circuit, and an integrated circuit formed according to the same. A field oxide region is formed over a portion of a substrate leaving an exposed active region. An oxide layer is formed over the active region. A first photoresist layer is formed and patterned over the first silicon layer. The first silicon layer is then etched to form an opening therethrough to expose a portion of the oxide layer. The oxide layer is etched through the opening to expose a portion of the substrate. a conductive etch stop layer is formed over the exposed portion of the substrate and the first photoresist layer. The first photoresist layer and the etch stop layer overlying the first photoresist layer are then removed. A second silicon layer is formed over the first silicon layer and the remaining etch stop layer. A second photoresist layer is formed and patterned over the second silicon layer.

Abstract: A semiconductor memory of the invention includes a semiconductor substrate having a plurality of transistors, a plurality of stacked capacitors connected to portions of the plurality of transistors, a plurality of first level interconnection layers connected to other portions of the plurality of transistors, and a plurality of second level interconnection layers disposed above the stacked capacitors and the first level interconnection layers. Each of the plurality of stacked capacitors includes a first electrode layer, a capacitance insulating film formed on top of the first electrode layer, and a second electrode layer formed on top of the capacitance insulating film. The second electrode layer is connected to a portion of one of the plurality of second level interconnection layers. At least portions of the plurality of first level interconnection layers are connected to other portions of the plurality of second level interconnection layers.

Abstract: An improved device fabrication method and transistor structure 36 provide shallow, heavily doped, source/drain junction regions 64 and a uniformly doped lower gate region 50 having a high concentration of dopants efficiently distributed near the gate electrode/gate interface 51. The gate, source, and drain terminals of transistor 36 may be interconnected to other neighboring or remote devices through the use of reacted refractory metal interconnect segments 98 and 100. Transistor structure 36 of the present invention may be constructed in an elevated source/drain format to include elevated source/drain junction regions 87 which may be fabricated simultaneous with a primary upper gate electrode region 88. This elevated source/drain junction feature is provided without added device processing complexity.

Abstract: A MOSFET constituting a flip-flop circuit and a MOSFET for control of reading and writing data out of and into a memory cell are formed on a semiconductor. The gate electrode of the first MOSFET and the gate electrode of the second MOSFET are formed by layers of different levels. The gate electrodes have an overlapped portion R. The first and second MOSFETs are arranged symmetrically with respect to a certain point P. By virtue of the above structure, the degree of integration of a static RAM is enhanced.

Abstract: A method of producing a ROM device wherein parallel spaced bit line regions are formed in a semiconductor substrate, blanket layers of (1) polysilicon, (2) etch stop material, and (3) polysilicon, are deposited, the layers etched to form orthogonal parallel word lines on the surface of the substrate, a thick insulating layer deposited over the word lines, a resist layer deposited, exposed and developed to define a desired code implant pattern, the exposed areas of the thick layer removed, and the underlie upper polysilicon layer of the bit line removed, and ion implanted into the substrate to form a code implant.

Abstract: A semiconductor memory device includes a semiconductor substrate, a memory cell formed on the semiconductor substrate and including first and second transfer transistors, first and second driver transistors and first and second thin film transistor loads, and first and second word lines extending generally parallel to each other along a predetermined direction and respectively coupled to gate electrodes of the first and second transfer transistors. Each of the first and second thin film transistor loads include first and second impurity regions which sandwich a channel region formed by a semiconductor layer provided on the semiconductor substrate, and a gate electrode formed by confronting conductor layers and isolated from the channel region.

Abstract: Provided is a semiconductor memory device wherein nonvolatile memory elements are arranged in a matrix configuration, each of the memory elements having a field effect transistor including a floating gate, an interlayer insulating film and a control gate electrode which are stacked on an insulating film covering a semiconductor substrate, and a source region and a drain region which are respectively formed in the semiconductor substrate on both sides of the gate electrode, the floating gate, interlayer insulating film and control gate electrode being formed in a recess provided in the semiconductor substrate. The semiconductor device of such a structure is reduced in size and highly integrated with its high-performance characteristics maintained.

Abstract: A semiconductor device and a method of manufacturing a semiconductor device includes the steps of forming a first conductivity type layer on one surface of a work piece comprising a semiconductor substrate. A gate oxide is formed on the surface of the substrate. A first conductive structure is formed on the gate oxide consisting essentially of polysilicon. An insulating structure is formed in contact with the first conductive structure. Material is removed from the surface of the first conductive structure to expose at least a portion of the surface of the first layer, and to form on the remaining structure on the workpiece a second conductive structure consisting essentially of polysilicon. The polysilicon is in electrical contact with the first conductive structure. Thus, a compound conductive structure is provided on the work piece.

Abstract: A static random access memory with a double vertical channel structure capable of providing a highly integrated memory element and a method of the same. On a substrate of a first conductivity type, first and second layers of the same conductivity type are formed, in order. On respective surfaces of the three layers, impurity diffusion regions are formed, centers of which are located on a vertical line. The first layer having the second impurity diffusion region and the second layer having the third impurity diffusion region are removed at their center portions, except for their opposite side portions, thereby forming trenches. In these trenches, gate electrodes and a ground electrode are formed. Accordingly, the first impurity diffusion region and the remaining opposite side portions of second and third impurity diffusion regions become source/drain regions, while the remaining opposite side portions of first and second layers become a double vertical channel region.

Abstract: A method of fabricating a semiconductor device, in particular of forming a polysilicon film on a step portion of an insulation film made by a trench or a contact hole is disclosed which includes the steps of depositing an amorphous silicon film on the step portion while doping impurities into the amorphous silicon film and carrying out heat treatment to convert the amorphous silicon film into a polycrystalline silicon film, thereby the polysilicon film on a step portion being formed.

Abstract: A semiconductor device having a bonding pad region, and a method of its fabrication. A conductive layer is formed on an isolation layer separating transistors of the device, to anchor the interconnection layer on the bonding region. The conductive layer may be formed from the same layer of material that gate electrodes of the transistors are formed. An oxide insulation layer covers the conductive layer and has at least one opening exposing the conductive layer in the bonding pad region. A barrier metal layer, formed on the diffusion regions and the insulation layer, extends into the opening where it makes a firm direct connection with the exposed conductive layer. A bonding pad is formed on the barrier metal layer by providing the interconnection layer on the barrier metal layer. Since the conductive layer and the barrier metal layer are firmly connected, and secures the interconnection layer in the bonding pad structure.

Abstract: A semiconductor memory device of the type having a test circuit incorporated integrally therewith generates test data to be batch written into the device's memory cells. The memory device includes at least one memory block to which there may be connected sense amplifiers through which read/write operations can be effected. A test circuit is also provided which function is to test each memory block. A peripheral circuit is formed electrically connected to any memory blocks. Accordingly, memory blocks as well as the peripheral circuit are formed on a semiconductor substrate onto which there is formed a `single` layer having both high (undoped thin poly-Si current paths-108CH) and low (doped thin poly-Si joint path-108SD) resistivity regions therein. The inherent properties of the undoped high-resistivity current paths 108 CH are such that in response to control signals from control gate electrodes, an electrical conductance of the current paths can be altered.

Abstract: An apparatus and method for integrating a submicron CMOS device and a non-volatile memory, wherein a thermal oxide layer is formed over a semiconductor substrate and a two layered polysilicon non-volatile memory device formed thereon. A portion of the thermal oxide is removed by etching, a thin gate oxide and a third layer of polysilicon having a submicron depth is deposited onto the etched region. The layer of polysilicon is used as the gate for the submicron CMOS device. In so doing a submicron CMOS device may be formed without subjecting the device to the significant re-oxidation required in formation processes for dual poly non-volatile memory devices such as EPROMs and EEPROMs, and separate device optimization is achieved.

Abstract: A semiconductor device of the present invention includes a semiconductor substrate, a p-type impurity diffused region formed in the semiconductor substrate, and a polycide interconnection electrically connected to the p-type impurity diffused region. In the semiconductor device, the polycide interconnection includes a first polysilicon film, a refractory metal silicide film formed on the first polysilicon film, and a second polysilicon film formed on the refractory metal silicide film.

Abstract: A semiconductor memory device includes a semiconductor substrate, a memory cell provided on the semiconductor substrate and including first and second transfer transistors, first and second driver transistors and first and second thin film transistor loads, where each of the first and second transfer transistors, the first and second driver transistors and the first and second thin film transistor loads have a source, a drain and a gate electrode, and a connecting region in which the drain of the second thin film transistor load, the gate electrode of the first thin film transistor load and the gate electrode of the first driver transistor are connected.

Abstract: A semiconductor memory device having a double-stacked capacitor, and methods for manufacturing the same, are disclosed. Such memory device has a first stacked capacitor and a second stacked capacitor, which are formed respectively over and below a bit line and run in parallel and are connected in order to increase the capacity of the capacitors and to prevent contact faults caused by a step occurring.

Abstract: A CMOS SRAM memory cell, and a method of making the same, is disclosed. The disclosed cell is configured as cross-coupled CMOS inverters, with the n-channel pull-down transistors in bulk, and with the p-channel load devices being accumulation mode p-channel transistors in a thin polysilicon film. The cross-coupling connection is made by way of an intermediate layer, which may include polysilicon at its top surface for performance enhancement, each of which makes contact to the drain region of an n-channel transistor, and to the opposite gate electrode, via a buried contact. The intermediate layer also serves as the gate for the thin-film p-channel transistor, which has its channel region overlying the intermediate layer. The p-channel transistors may be formed so as to overlie part of the n-channel transistor in its inverter, thus reducing active chip area required for implementation of the memory cell.

Abstract: The invention provides an improved BiCMOS device and a method of fabricating such a BiCMOS device which requires fewer process steps than known fabrication methods. In one embodiment, the invention provides a method of forming an interpoly capacitor in a BiCMOS device which maintains the thickness of the interpoly dielectric in the capacitor while a window is etched for the emitter in a bipolar transistor. The method includes the use of a thin polysilicon layer overlying the oxide layer, which protects the oxide from etching while the emitter window is etched.

Abstract: A semiconductor device is disclosed that can form contacts with ease even if the distance between adjacent gate electrodes is reduced in accordance with larger scale integration of semiconductor devices. The semiconductor device includes a polysilicon pad 8c connected to impurity implanted layers 5a and 7a, formed over sidewalls 6a and 6b of gate electrodes 3a and 3b and insulating films 4a and 4b; and a polysilicon pad 11a connected to impurity implanted layers 5b and 7b, formed over polysilicon pad 8c with an insulating film 9 and sidewalls 10b therebetween. Even if elements are miniaturized to have reduced gate electrode length and gate electrode distance in accordance with larger scale integration of a semiconductor device, polysilicon pads 8c and 11a can be formed with ease between impurity implanted layers 5a, 7a and an upper layer wiring 13a, and between impurity implanted layers 5b, 7b and an upper layer wiring 13b, respectively.

Abstract: The present invention relates to a semiconductor device used as a gate electrode or interconnection, in which a polysilicon layer in a laminate comprising a polysilicon layer doped with an impurity and a refractory metal silicide layer has an impurity concentration that is reduced close to a boundary between the polysilicon layer and the refractory metal silicide layer. With this structure, the difference in oxidation speed between the polysilicon layer and the silicide layer is smaller in comparison with a conventional structure, and thus peeling due to bird's beaks can be prevented. The semiconductor device of this structure can be realized by a two-layer polysilicon structure in which the upper layer in contact with the refractory metal silicide layer has a lower impurity concentration, or by a structure in which the peak of the impurity concentration profile is set to be deep within the polysilicon layer during ion implantation.

Abstract: A MOSFET Static Random Access Memory (SRAM) cell has a symmetrical construction, with a pair of word lines. The word lines are in second level polysilicon, so that they may overlap the driving transistor gates which are in first level polysilicon.

Abstract: An upper electrode of a capacitor is structured to have its end surface recessed from an end surface of an interlayer insulating layer covering a surface of said electrode layer, at a position where the upper electrode faces a bit line contact portion. The upper electrode layer and the first interlayer insulating layer are patterned to have the same end surface shape. Subsequently, only a side surface of the upper electrode layer is etched and recedes by isotropic etching. The receding surface of the upper electrode layer and a side surface of said interlayer insulating layer are covered with a sidewall insulating layer. The bit line contact portion or a pad layer for a bit line contact is formed along a surface of the sidewall insulating layer. The sidewall insulating layer is formed thick by a receding amount of the upper electrode of the capacitor from the first interlayer insulating layer.

Abstract: In a semiconductor memory of the invention, the source or drain of a transfer gate MOS transistor is electrically connected to a charge storage first conductive layer through a third conductive layer.

Abstract: A semiconductor device including a semiconductor substrate of a first conductivity type. An insulative film and metal films are sequentially formed on the main top surface of the semiconductor substrate. Impurity diffusion layers of a second conductivity type are selectively formed on the main top surface of the semiconductor substrate. The semiconductor device further includes metal compound layers consisting of constituting elements of the semiconductor substrate and a metal element. The metal compound layers are formed in the impurity diffusion layers in such a manner that they do not contact the insulative film, and the metal compound layers on the main back surface side of the semiconductor substrate have faces formed in parallel to the top surface of the semiconductor substrate.