Abstract: An apparatus for measuring a gate oxide thickness comprises a first active area, first to fifth wordlines, first and second bar-shaped trench capacitors, and first and second gate structures. The first active area with a width of at least 2F is disposed on a substrate. The first to fifth wordline is disposed on the substrate in a first direction, with a first predetermined space between each two wordlines, and first ends of the first to fifth wordlines are electrically connected. The first and second bar-shaped trench capacitors are disposed under the second and the fourth wordlines respectively with a second predetermined space between the first and second bar-shaped trench capacitors, and F is a minimum line width of the wordlines. The first and second gate structure are respectively disposed between the first bar-shaped trench capacitor and the second wordline and between the second bar-shaped trench capacitor and the fourth wordline.

Abstract: A double corner rounding process for a partial vertical cell. A first corner rounding process is performed after etching the substrate to form a shallow trench for device isolation. A second corner rounding process is performed after forming shallow trench isolations (STIs) and exposing the corner of the substrate at the active areas in the memory cell array region.

Abstract: A novel trench-capacitor DRAM cell structure is disclosed. The trench-capacitor DRAM cell of this invention includes an active area island having a horizontal semiconductor surface and a vertical sidewall contiguous with the horizontal semiconductor surface. A pass transistor is disposed at the corner of the active area island. The pass transistor includes a folded gate conductor strip extending from the horizontal semiconductor surface to the vertical sidewall of the active area island, a source formed in the horizontal semiconductor surface, a drain formed in the vertical sidewall, and a gate oxide layer underneath the folded gate conductor strip. The source and drain define a folded channel. The trench-capacitor DRAM cell further includes a trench capacitor that is insulated from the folded gate conductor strip by a trench top oxide (TTO) layer and is coupled to the pass transistor via the drain.

Abstract: The present invention provides a method for eliminating inverse narrow width effects in the fabrication of DRAM devices. A semiconductor substrate is provided having thereon a shallow trench. The shallow trench surrounds an active area. A non-doped silicate glass (NSG) layer is deposited to fill the shallow trench, and is then etched back to a depth of the shallow trench, thereby exposing a portion of the semiconductor substrate at an upper portion of the shallow trench. A doped dielectric layer is deposited over the remaining NSG layer to cover the exposed semiconductor substrate. A thermal process is then carried out to diffuse dopants of the doped dielectric layer into the semiconductor substrate, thereby forming a doped region at the periphery of the active area in a channel width direction.

Abstract: A memory device with vertical transistors and deep trench capacitors. The device includes a substrate containing at least one deep trench and a capacitor deposited in the lower portion of the deep trench. A conducting structure, having a first conductive layer and a second conductive layer, is deposited on the trench capacitor. A ring shaped insulator is deposited on the sidewall and between the substrate and the first conductive layer. The first conductive layer is surrounded by the ring shaped insulator, and the second conductive layer is deposited on the first conductive layer and the ring shaped insulator. A diffusion barrier between the second conductive layer and the substrate of the deep trench is deposited on one side of the sidewall of the deep trench. A TTO is deposited on the conducting structure. A control gate is deposited on the TTO.

Abstract: A partial vertical memory cell and fabrication method thereof. A semiconductor substrate is provided, in which two deep trenches having deep trench capacitors respectively are formed, and the deep trench capacitors are lower than a top surface of the semiconductor substrate. A portion of the semiconductor outside the deep trenches is removed to form a pillar between. The pillar is ion implanted to form an ion-doped area in the pillar corner acting as a S/D area. A gate dielectric layer and a conducting layer are conformally formed on the pillar sequentially. An isolation is formed in the semiconductor substrate beside the conducting layer. The conducting layer is defined to form a first gate and a second gate.

Abstract: A method for fabricating a memory device with a vertical transistor and a trench capacitor. First, a capacitor is formed in a lower portion of a trench formed in a substrate. Next, a wiring structure and a first trench top isolation layer are successively formed overlying the capacitor. Next, a dielectric spacer is formed over the sidewall of the trench and overlying the first trench top isolation layer. Thereafter, the first trench top isolation layer is removed to expose the sidewall of the trench between the dielectric spacer and the wiring structure. Next, a buried strap is formed in the substrate around the exposed sidewall of the trench. Thereafter, the dielectric spacer is removed. Next, a second trench top isolation layer is formed overlying the wiring structure. Finally, a control gate is formed overlying the second trench top isolation layer.

Abstract: A fabrication method for a DRAM cell with dual driving voltages and a vertical transistor. Liquid phase deposition (LPD) is used to integrate an array area process and a support area process in order to simplify steps.

Abstract: Method for preventing sneakage in shallow trench isolation and STI structure thereof. A semiconductor substrate having a pad layer and a trench formed thereon is provided, followed by the formation of a doped first lining layer on the sidewall of the trench. A second lining layer is then formed on the doped first lining layer. Etching is then performed to remove parts of the first lining layer and the second lining layer so that the height of the first lining layer is lower than the second lining layer. A sacrificial layer is then formed on the pad layer and filling the trench. Diffusion is then carried out so that the doped ions in the first lining layer out-diffuse to the substrate and form diffuse regions outside the two bottom corners of the trench.

Abstract: A deep trench self-alignment process for an active area of a partial vertical cell. A semiconductor substrate with two deep trenches is provided. A deep trench capacitor is formed in each deep trench, and an isolating layer is formed thereon. Each trench is filled with a mask layer. A photoresist layer is formed on the semiconductor substrate between the deep trenches, and the photoresist layer partially covers the mask layer. The semiconductor substrate is etched lower than the isolating layer using the photoresist layer and the mask layer as masks. The photoresist layer and the mask layer are removed, such that the pillar semiconductor substrate between the deep trenches functions as an active area.

Abstract: A test device and method for detecting alignment of word lines and deep trench capacitors in DRAM devices. In the test device, parallel first and second bar-type deep trenches capacitors are disposed in the scribe line region. The first and second bar-type deep trenches capacitors extend to the first and second pairs of memory cells in the memory region adjacent to the first active area respectively. The first and second bar-type deep trenches capacitors are electrically coupled to bit line contacts of the first and second pairs of memory cells respectively. First and second transistors have sources coupled to the first and second bar-type deep trenches capacitors respectively. A first bit line contact is electrically coupled to drains of the first and second transistors.

Abstract: A vertical split gate flash memory cell. The memory cell includes a substrate, a floating gate, a control gate, a tunnel layer, a first doping region, and a second doping region. The floating gate is disposed in the lower portion of the trench and insulated from the adjacent substrate by a floating gate oxide layer. The control gate is disposed over the floating gate and insulated from the adjacent substrate by a control gate oxide layer. The inter-gate dielectric layer is disposed between the floating gate and the control gate for insulation of the floating gate and the control gate. The first doping region is formed in the substrate adjacent to the control gate and the second doping region is formed in the substrate below the first doping region and adjacent to the floating gate to serve as source and drain regions with the first doping region.

Abstract: A vertical split gate flash memory cell. The memory cell includes a substrate, a floating gate, a control gate, a tunnel layer, a first doping region, and a second doping region. The floating gate is disposed in the lower portion of the trench and insulated from the adjacent substrate by a floating gate oxide layer. The control gate is disposed over the floating gate and insulated from the adjacent substrate by a control gate oxide layer. The inter-gate dielectric layer is disposed between the floating gate and the control gate for insulation of the floating gate and the control gaze. The first doping region is formed in the substrate adjacent to the control gate and the second doping region is formed in the substrate below the first doping region and adjacent to the control gate to serve as source and drain regions with the first doping region.

Abstract: A method of forming a bottle-shaped trench. A trench is formed in a substrate, wherein the trench has a surface with an upper portion and a lower portion beneath the upper portion. A dielectric layer is formed on the trench surface at the lower portion. Using the dielectric layer as a mask, a nitridation procedure is performed to form a nitride film on the trench surface at the upper portion. The dielectric layer is removed. Using the nitride film as a mask, an isotropic etching procedure is performed to form a space in the trench at the lower portion. Thus, a bottle-shaped trench is formed.

Abstract: A test key disposed on a scribe line of a wafer. The test key includes: two active areas disposed on the substrate; two first deep trench capacitors disposed on the substrate outside the two active areas; a rectangular active word line disposed on the substrate covering the first deep trench capacitors and the active areas; first and second passing word lines disposed on one side of the rectangular active word line and across the parallel active areas; a third passing word line disposed on another side of the rectangular active word line and across another end of the two active areas; two second deep trench capacitors disposed on the substrate under where the two first passing word lines overlap the two active areas; and four contacts disposed on the first active areas between the first and second word lines and between the third and the rectangular active word line.

Abstract: A reflective mechanism for a stage lamp providing an incident light includes a mounting device, a rotary device, a rotary frame, a reflective device rotatably mounted to the rotary frame, and a transmission device. The rotary device is mounted to the mounting device and comprises a fixed outer ring, a middle ring concentrically, rotatably mounted in the fixed outer ring, and an inner ring concentrically, rotatably mounted in the middle ring. The inner ring and the middle ring are driven by a first power device and a second power device, respectively. The rotary frame is attached to the middle ring to turn therewith. The transmission device includes a first transmission member mounted to the inner ring to turn therewith and a second transmission member that is mounted to the reflective device to turn therewith and that is connected to the first transmission member.

Abstract: A two-stage method for making buried strap out-diffusions is disclosed. A substrate having a deep trench is provided. A first conductive layer is deposited at the bottom of the deep trench. A collar oxide is formed on sidewalls of the deep trench. A second conductive layer is deposited within the deep trench atop the first conductive layer. The collar oxide is then etched back to a predetermined depth. A third conductive layer is deposited directly on the second conductive layer. A trench top oxide (TTO) layer is formed on the third conductive layer. A spacer is formed on the sidewalls of the deep trench. A portion of the TTO layer is etched away to form a recess underneath the spacer, which exposing the substrate in the deep trench. Thereafter, a doping process is carried out to form a first diffusion region through the recess, followed by spacer stripping.

Abstract: A test device and method for detecting alignment of word lines and deep trench capacitors in DRAM devices. In the test device, parallel first and second bar-type deep trenches capacitors are disposed in the scribe line region. The first and second bar-type deep trenches capacitors extend to the first and second pairs of memory cells in the memory region adjacent to the first active area respectively. The first and second bar-type deep trenches capacitors are electrically coupled to bit line contacts of the first and second pairs of memory cells respectively. First and second transistors have sources coupled to the first and second bar-type deep trenches capacitors respectively. A first bit line contact is electrically coupled to drains of the first and second transistors.

Abstract: A memory cell with a vertical transistor and a trench capacitor. The memory cell includes a substrate having a trench and a trench capacitor disposed in the lower trench. A control gate, with a p-type polysilicon germanium layer and an overlying p-type polysilicon layer, is disposed in the upper trench and insulated from the substrate. A first insulating layer is disposed between the trench capacitor and the control gate. A first doped region is formed in the substrate around the first insulating layer and a second doped region is formed in the substrate around the second conductive layer.

Abstract: A test key disposed on a scribe line of a wafer. The test key includes: two active areas disposed on the substrate; two first deep trench capacitors disposed on the substrate outside the two active areas; a rectangular active word line disposed on the substrate covering the first deep trench capacitors and the active areas; first and second passing word lines disposed on one side of the rectangular active word line and across the parallel active areas; a third passing word line disposed on another side of the rectangular active word line and across another end of the two active areas; two second deep trench capacitors disposed on the substrate under where the two first passing word lines overlap the two active areas; and four contacts disposed on the first active areas between the first and second word lines and between the third and the rectangular active word line.