| Patent application number | Description | Published |
|---|
| 20080205133 | Capacitor-less volatile memory cell, device, system and method of making same - A capacitor-less memory cell, memory device, system and process of forming the capacitor-less memory cell includes forming the memory cell in an active area of a substantially physically isolated portion of the bulk semiconductor substrate. A pass transistor is formed on the active area for coupling with a word line. The capacitor-less memory cell further includes a read/write enable transistor vertically configured along at least one vertical side of the active area and operable during a reading of a logic state with the logic state being stored as charge in a floating body area of the active area, causing different determinable threshold voltages for the pass transistor. | 08-28-2008 |
| 20090129167 | SEMICONDUCTOR MAGNETIC MEMORY INTEGRATING A MAGNETIC TUNNELING JUNCTION ABOVE A FLOATING-GATE MEMORY CELL - A semiconductor magnetic memory device has a magnetic tunneling junction formed over a memory cell. The memory cell has a control gate surrounded by a floating gate. The floating gate is coupled to the magnetic tunneling junction through a pinning layer that maintains the magnetic orientation of the lower magnetic layer of the junction. A current through a selected word line, coupled to the control gate, generates a first magnetic field. A current through a cell select line generates a second magnetic field that is orthogonal to the first magnetic field. This changes the magnetic orientation of the upper magnetic layer of the junction to lower its resistance, thus allowing a write/erase voltage on a program/erase line to program/erase the floating gate. | 05-21-2009 |
| 20090218656 | METHODS OF MAKING SEMICONDUCTOR STRUCTURES INCLUDING VERTICAL DIODE STRUCTURES - Semiconductor structures and methods of making a vertical diode structure are provided. The vertical diode structure may have associated therewith a diode opening extending through an insulation layer and contacting an active region on a silicon wafer. A titanium silicide layer may be formed over the interior surface of the diode opening and contacting the active region. The diode opening may initially be filled with an amorphous silicon plug that is doped during deposition and subsequently recrystallized to form large grain polysilicon. The silicon plug has a top portion that may be heavily doped with a first type dopant and a bottom portion that may be lightly doped with a second type dopant. The top portion may be bounded by the bottom portion so as not to contact the titanium silicide layer. In one embodiment of the vertical diode structure, a programmable resistor contacts the top portion of the silicon plug and a metal line contacts the programmable resistor. | 09-03-2009 |
| 20090239343 | Methods Of Forming Lines Of Capacitorless One Transistor DRAM Cells, Methods Of Patterning Substrates, And Methods Of Forming Two Conductive Lines - This invention includes a capacitorless one transistor DRAM cell that includes a pair of spaced source/drain regions received within semiconductive material. An electrically floating body region is disposed between the source/drain regions within the semiconductive material. A first gate spaced is apart from and capacitively coupled to the body region between the source/drain regions. A pair of opposing conductively interconnected second gates are spaced from and received laterally outward of the first gate. The second gates are spaced from and capacitively coupled to the body region laterally outward of the first gate and between the pair of source/drain regions. Methods of forming lines of capacitorless one transistor DRAM cells are disclosed. | 09-24-2009 |
| 20090311843 | CONTAINER CAPACITOR STRUCTURE AND METHOD OF FORMATION THEREOF - Disclosed is a container capacitor structure and method of constructing it. An etch mask and etch are used to expose portions of an exterior surface of electrode (“bottom electrodes”) of the container capacitor structure. The etch provides a recess between proximal pairs of container capacitor structures, which recess is available for forming additional capacitance. Accordingly, a capacitor dielectric and a top electrode are formed on and adjacent to, respectively, both an interior surface and portions of the exterior surface of the first electrode. Advantageously, surface area common to both the first electrode and second electrodes is increased over using only the interior surface, which provides additional capacitance without a decrease in spacing for clearing portions of the capacitor dielectric and the second electrode away from a contact hole location. Furthermore, such clearing of the capacitor dielectric and the second electrode portions may be done at an upper location of a substrate assembly in contrast to clearing at a bottom location of a contact via. | 12-17-2009 |
| 20100012995 | LOCALIZED BIASING FOR SILICON ON INSULATOR STRUCTURES - A silicon-on-insulator device has a localized biasing structure formed in the insulator layer of the SOI. The localized biasing structure includes a patterned conductor that provides a biasing signal to distinct regions of the silicon layer of the SOI. The conductor is recessed into the insulator layer to provide a substantially planar interface with the silicon layer. The conductor is connected to a bias voltage source. In an embodiment, a plurality of conductor is provided that respectively connected to a plurality of voltage sources. Thus, different regions of the silicon layer are biased by different bias signals. | 01-21-2010 |
| 20100273309 | METHOD FOR FORMING A SELF ALIGNED ISOLATION TRENCH - The present invention relates to methods for forming microelectronic structures in a semiconductor substrate. The method includes selectively removing dielectric material to expose a portion of an oxide overlying a semiconductor substrate. Insulating material may be formed substantially conformably over the oxide and remaining portions of the dielectric material. Spacers may be formed from the insulating material. An isolation trench etch follows the spacer etch. An optional thermal oxidation of the surfaces in the isolation trench may be performed, which may optionally be followed by doping of the bottom of the isolation trench to further isolate neighboring active regions on either side of the isolation trench. A conformal material may be formed substantially conformably over the spacer, over the remaining portions of the dielectric material, and substantially filling the isolation trench. Planarization of the conformal material may follow. | 10-28-2010 |
