Abstract: A single transistor planar DRAM memory cell with improved charge retention and reduced current leakage and a method for forming the same, the method including providing a semiconductor substrate; forming a gate dielectric on the semiconductor substrate; forming a pass transistor structure adjacent a storage capacitor structure on the gate dielectric; forming sidewall spacer dielectric portions adjacent either side of the pass transistor to include covering a space between the pass transistor and the storage capacitor; forming a photoresist mask portion covering the pass transistor and exposing the storage capacitor; and, carrying out a P type ion implantation and drive in process to form a P doped channel region in the semiconductor substrate underlying the storage capacitor.

Abstract: A method for manufacturing a memory device utilizes multi-etching processes to respectively construct isolation trenches in a memory substrate that has a memory array area and a peripheral circuit region, wherein the depth of the trenches in the peripheral circuit region is deeper into the memory substrate than the depth of the trenches in the memory array area. Therefore, possible current leakage caused from the high operating voltage is effectively mitigated, and the performance of the memory device is increased.

Abstract: A novel, low-temperature metal deposition method which is suitable for depositing a metal film on a substrate, such as in the fabrication of metal-insulator-metal (MIM) capacitors, is disclosed. The method includes depositing a metal film on a substrate using a deposition temperature of less than typically about 270 degrees C. The resulting metal film is characterized by enhanced thickness uniformity and reduced grain agglomeration which otherwise tends to reduce the operational integrity of a capacitor or other device of which the metal film is a part. Furthermore, the metal film is characterized by intrinsic breakdown voltage (Vbd) improvement.

Abstract: A single transistor planar RAM memory cell with improved charge retention and a method for forming the same, the method including providing forming a pass transistor structure adjacent a storage capacitor structure separated by a predetermined distance; carrying out a first ion implantation process to form first and second doped regions adjacent either side of the pass transistor structure, the first doped region defined by the predetermined distance; depositing a spacer dielectric layer; etching back the spacer dielectric layer to leave an unetched spacer dielectric layer portion overlying the first doped region while forming a sidewall spacer of a predetermined width overlying a first portion of the second doped region; and, carrying out a second ion implantation process to form a relatively higher dopant concentration in a second portion of the second doped region.

Abstract: A method for manufacturing a memory device utilizes multi-etching processes to respectively construct isolation trenches in a memory substrate that has a memory array area and a peripheral circuit region, wherein the depth of the trenches in the peripheral circuit region is deeper into the memory substrate than the depth of the trenches in the memory array area. Therefore, possible current leakage caused from the high operating voltage is effectively mitigated, and the performance of the memory device is increased.

Abstract: The present invention discloses a simple and convenient method for fabricating a capacitor device with BiCMOS processes. An electrode of the capacitor device formed according to the present invention is an ion doping region formed in an epitaxy layer so that the thickness of the dielectric layer of the capacitor device decreased relative to a specific ion concentration. Accordingly, the capacitor device formed therein has a high capacitance and good performance.

Abstract: The present invention discloses a simple and convenient method for fabricating a capacitor device with BiCMOS processes. An electrode of the capacitor device formed according to the present invention is an ion doping region formed in an epitaxy layer so that the thickness of the dielectric layer of the capacitor device decreased relative to a specific ion concentration. Accordingly, the capacitor device formed therein has a high capacitance and good performance.

Abstract: The present invention discloses a simple and convenient method for fabricating a capacitor device with BiCMOS processes. An electrode of the capacitor device formed according to the present invention is an ion doping region formed in an epitaxy layer so that the thickness of the dielectric layer of the capacitor device decreased relative to a specific ion concentration. Accordingly, the capacitor device formed therein has a high capacitance and good performance.

Abstract: A method is used to fully extract coupling coefficients of a flash memory cell by a GIDL manner. The flash memory cell is composed of a substrate, a drain region, source region, a control gate and a floating gate. The method keeps the source voltage Vs and the substrate voltage Vb fixed. The drain voltage Vd and the control gate voltage are varied. Then, measuring a GIDL current obtains a first coefficient ratio of the drain coupling coefficient ad to the gate coupling &agr;cg, that is, &agr;d/&agr;cg. Similarly, keeping the drain voltage Vd and the substrate voltage Vb fixed and varying the source voltage Vs and the control gate voltage Vcg, a second coefficient ratio of the source coupling coefficient &agr;s to the gate coupling coefficient &agr;cg, that is, &agr;s/&agr;cg.

Abstract: A split-gate flash memory is formed by a method described in the following steps. A tunnelling oxide layer, a first conductive layer, and a hard mask layer are formed on a substrate in sequence. A drain opening and a floating gate opening are formed on the hard mask layer by defining the hard mask layer in order to expose the first conductive layer. A first polyoxide layer and a second polyoxide layer are formed on the first conductive layer exposed by the drain opening and the floating gate opening, respectively. The first polyoxide layer and the first conductive layer beneath the first polyoxide layer are removed to expose the substrate in the drain opening. A drain region is formed in the substrate in the drain opening. The hard mask layer is removed, and the first conductive layer is etched into a floating gate using the second polyoxide layer as a mask. A split-gate oxide layer and a second conductive layer are formed on the resulting structure in sequence.

Abstract: A process is provided for fabricating an integrated circuit in which an oxynitride layer is selectively formed in a first active region without forming an oxynitride layer in a second active region peripheral to the first active region. In one embodiment, the memory cell is fabricated where an oxynitride layer is prevented from forming in a region peripheral to the memory array region. In an alternate embodiment, the memory cell is fabricated where an oxynitride layer formed in a region peripheral to the memory array region is selectively removed.