Abstract: A new class of CMOS integrated circuits, wherein the PMOS and NMOS devices are both configured as vertical transistors. One trench can contain a PMOS device, an NMOS device, and a gate which is coupled to control both the PMOS device and the NMOS device. Latchup problems do not arise, and n+ to p+ spacing rules are not required.

Abstract: A semiconductor wafer (32) is patterned to have gettering areas (36-38) selectively positioned proximate devices (44-46) which require gettering. The areas (36-38) comprise germanium-doped silicon having a germanium concentration of approximately 1.5%-2.0%. The germanium creates a lattice mismatch between the substrate (32) and an epitaxial layer (34) which is sufficient to produce defects capable of gettering contaminants. The gettering areas (36-38) may be formed by selective deposition, selective etching, ion-implantation or selective diffusion techniques.

Abstract: A dRAM cell and array of cells, together with a method of fabrication, are disclosed wherein the cell includes one field effect transistor and one storage capacitor with both the transistor and the capacitor formed in a trench in a substrate. The transistor source, channel and drain and one capacitor plate are formed essentially vertically in the bulk substrate sidewalls of the trench, and the gate and other capacitor plate are formed in two regions of material inserted into the trench and isolated from the bulk by an insulating layer. Signal charge is stored on the capacitor material inserted into the trench by an electrical connection of the bulk substrate source to the capacitor material through the insulating layer. In preferred embodiments word lines on the substrate surface connect to the upper of the inserted regions which forms the gate, and bit lines on the substrate surface form the drains.

Abstract: A new class of CMOS integrated circuits, wherein the PMOS and NMOS devices are both configured as vertical transistors. One trench can contain a PMOS device, an NMOS device, and a gate which is coupled to control both the PMOS device and the NMOS device. Latchup problems do not arise, and n+ to p+ spacing rules are not required.

Abstract: A baseboard for orthogonal mounting of integrated circuit chips thereto is described. Plural channels (14) are anisotropically etched in a silicon baseboard (10). A corresponding plurality of integrated circuit chips (12) are inserted into the channels (14). A number of baseboard contact pads (18) are formed adjacent each channel (14), and are solder bonded to corresponding chip conductor pads (16). Interconnect conductors (20, 28) provide connection of each baseboard pad (18) either to other chips (12) or to connector pads (22) located adjacent an edge (26) of the baseboard chip mount (10). A coating (30) of silicon carbide over the surface of the baseboard chip mount (10) improves the thermal efficiency of the assembly.

Abstract: The present invention is described in conjunction with the fabrication of a dRAM cell which an important application of the present invention. The described cell provides a one-transistor/one-capacitor dRAM cell structure and array in which the cell transistor is formed on the sidewalls of a substrate trench containing the cell capacitor; the word and bit lines cross over this trench. This stacking of the transistor on top of the capacitor yields a cell with minimal area on the substrate and solves a problem of dense packing of cells.One capacitor plate and the transistor channel and source region are formed in the bulk sidewall of the trench and the transistor gate and the other plate of the capacitor are both formed in polysilicon in the trench but separated from each other by an oxide layer inside the trench.

Abstract: A baseboard for orthogonal mounting of integrated circuit chips is described. Plural channels (14) are anisotropically etched in a silicon baseboard (10). A corresponding plurality of integrated circuit chips (12) are inserted into the channels (14). A number of baseboard contact pads (18) are formed adjacent each channel (14), and are solder bonded to corresponding chip conductor pads (16). Interconnect conductors (20, 28) provide connection of each baseboard pad (18) either to other chips (12) or to connector pads (22) located adjacent an edge (26) of the baseboard chip mount (10). A coating (30) of silicon carbide over the surface of the baseboard chip mount (10) improves the thermal efficiency of the assembly.

Abstract: The present invention is described in conjunction with the fabrication of a dRAM cell which an important application of the present invention. The described cell provides a one-transistor/one-capacitor dRAM cell structure and array in which the cell transistor is formed on the sidewalls of a substrate trench containing the cell capacitor; the word and bit lines cross over this trench. This stacking of the transistor on top of the capacitor yields a cell with minimal area on the substrate and solves a problem of dense packing of cells. One capacitor plate and the transistor channel and source region are formed in the bulk sidewall of the trench and the transistor gate and the other plate of the capacitor are both formed in polysilicon in the trench but separated from each other by an oxide layer inside the trench. The signal charge is stored on the polysilicon capacitor plate by an electrical connection of the source region with the polysilicon capacitor plate.

Abstract: A dRAM cell and array of cells, together with a method of fabrication, are disclosed wherein the cell includes one field effect transistor and one capacitor with both the transistor and the capacitor formed in a trench in a substrate. One capacitor plate and the transistor source are common and are formed in the lower portion of the trench sidewall. The transistor drain is formed in the upper portion of the trench sidewall to connect to a bit line on the substrate surface, and the channel is the vertical portion of the trench sidewall between the source and drain. The transistor gate fills the upper portion of the trench, and a heavily doped other plate of the capacitor fills the lower portion of the trench and makes contact with the substrate through the bottom of the trench.

Abstract: A dynamic random access memory cell (14) is disclosed which is characterized by a high capacity storage element and small lateral wafer area. The cell (14) is constructed with a word line (40) overlying a split bit line (48, 50), with an underlying transistor 30, and yet thereunder a high capacitance capacitor (34). The word line (40) includes a member (42) isolated from the bit line (36) and formed therethrough to provide the transistor gate conductor. The transistor gate insulator (44) covers the gate conductor (42), and is encircled by a transistor semiconductor region (46) forming a vertical transistor conduction channel. The split bit line elements (48, 50) are in electrical contact with an underlying transistor drain region (126). The transistor conduction channel (46) is also in contact with an underlying transistor source region forming one plate (52) of the capacitor (34). The capacitor plate (52) is a core which is enclosed annularly by dielectric isolation (54).

Abstract: A dRAM cell and array of cells, together with a method of fabrication, are disclosed wherein the cell includes one field effect transistor and one storage capacitor with both the transistor and the capacitor formed in a trench in a substrate. The transistor source, channel, and drain and one capacitor plate are formed essentially vertically in the sidewalls of the trench, and the gate and other capacitor plate are formed in two regions of material inserted into the trench. Signal charge is stored on the material inserted into the trench. In preferred embodiments word lines on the substrate surface connect to the upper of the inserted regions which forms the gate, and bit lines on the substrate surface are formed as diffusions in the substrate which also form the drains. The trenches and cells are formed at the crossings of bit lines and word lines; the bit lines and the word lines form perpendicular sets of parallel lines.

Abstract: A dRAM cell and array of cells, together with a method of fabrication, are disclosed wherein the cell includes one field effect transistor and one storage capacitor with both the transistor and the capacitor formed in a trench in a substrate. The transistor source, channel and drain and one capacitor plate are formed essentially vertically in the bulk substrate sidewalls of the trench, and the gate and other capacitor plate are formed in two regions of material inserted into the trench and isolated from the bulk by an insulating layer. Signal charge is stored on the capacitor material inserted into the trench by an electrical connection of the bulk substrate source to the capacitor material through the insulating layer. In preferred embodiments word lines on the substrate surface connect to the upper of the inserted regions which forms the gate, and bit lines on the substrate surface form the drains.

Abstract: The present invention is described in conjunction with the fabrication of a dRAM cell which an important application of the present invention. The described cell provides a one-transistor/one-capacitor dRAM cell structure and array in which the cell transistor is formed on the sidewalls of a substrate trench containing the cell capacitor; the word and bit lines cross over this trench. This stacking of the transistor on top of the capacitor yields a cell with minimal area on the substrate and solves a problem of dense packing of cells. One capacitor plate and the transistor channel and source region are formed in the bulk sidewall of the trench and the transistor gate and the other plate of the capacitor are both formed in polysilicon in the trench but separated from each other by an oxide layer inside the trench. The signal charge is stored on the polysilicon capacitor plate by an electrical connection of the source region with the polysilicon capacitor plate.

Abstract: A method for forming CMOS device wherein the NMOS devices are bulk devices and the PMOS devices are SOI devices. The PMOS devices are formed with their channel regions in a silicon-on-insulator layer, preferably a laterally recrystallized annealed-polysilicon layer over a silicon dioxide layer.

Abstract: A CMOS device wherein the NMOS devices are bulk devices and the PMOS devices are SOI devices. The PMOS devices are formed with their channel regions in a silicon-on-insulator layer, preferably a laterally recrystallized annealed-polysilicon layer over a silicon dioxide layer.

Abstract: A dRAM cell and array of cells, together with a method of fabrication, are disclosed wherein the cell includes one field effect transistor and one capacitor with both the transistor and the capacitor formed in a trench in a substrate. One capacitor plate and the transistor source are common and are formed in the lower portion of the trench sidewall. The transistor drain is formed in the upper portion of the trench sidewall to connect to a bit line on the substrate surface, and the channel is the vertical portion of the trench sidewall between the source and drain. A ground line runs past the transistor gate in the upper portion of the trench down into the lower portion of the trench to form the other capacitor plate.