Abstract: According to embodiments of the present invention, methods of manufacturing a semiconductor device, and semiconductor devices manufactured thereby, are provided. A field region is formed that defines active regions in a semiconductor substrate. Spaced apart gates are formed on the active regions in the semiconductor substrate. The gates have sidewalls that extend away from the semiconductor substrate. First spacers are formed on the sidewalls of the gates. Second spacers are formed on the first spacers and opposite to the gates. Ion impurities are implanted into the active regions in the semiconductor substrate, adjacent to the gates, using the first and second spacers as an ion implantation mask. A portion of the second spacers is removed to widen the gaps between the gates. A dielectric layer is formed on the semiconductor substrate in the gaps between the gates.

Abstract: A ferroelectric memory device along with a method of forming the same are provided. A first interlayer insulating layer is formed on a semiconductor substrate. A buried contact structure is formed on the first interlayer insulating layer. The buried contact structure is electrically connected to the substrate through a first contact hole extending through the first interlayer insulating layer. A blocking layer covers or encapsulates the buried contact structure and the first interlayer insulating layer. A second interlayer insulating layer is formed on the blocking layer. A ferroelectric capacitor formed on the second interlayer insulating layer and is electrically connected to the buried contact structure through a second contact hole that penetrates the second interlayer insulating layer and the blocking layer.

Abstract: A semiconductor memory device and a method for manufacturing the same are provided.

Abstract: An etch-stop layer is selectively provided between layers of a multiple-layered circuit in a selective manner so as to allow for outgassing of impurities during subsequent fabrication processes. The etch-stop layer is formed over an underlying stud so as to serve as an alignment target during formation of an overlying stud formed in an upper layer. In this manner multiple-layered circuits, for example memory devices, can be fabricated in relatively dense configurations.

Abstract: Ferroelectric memory devices and methods for fabricating such devices are provided. The ferroelectric memory device may comprise one or more interlayer dielectric layers on a semiconductor substrate, an oxygen-diffusion barrier pattern on the interlayer dielectric layer(s), and an upper insulating layer that is on the interlayer dielectric layer(s) that at least partially surrounds the oxygen-diffusion barrier pattern. These devices further include a capacitor that has a bottom electrode that is on the oxygen-diffusion barrier layer and on at least a portion of the upper insulating layer, a ferroelectric layer that is on the bottom electrode, and a top electrode that is on the ferroelectric layer. In some embodiments of the present invention, the top surface of the upper insulating layer is higher than the top surface of the oxygen-diffusion barrier pattern.

Abstract: An integrated circuit device structure which avoids misalignment when a contact hole is formed to expose a contact pad and a method of fabricating the same, are provided. The integrated circuit device includes a semiconductor substrate having a conductive region and an insulating region, a contact pad on the conductive region of the semiconductor substrate, an auxiliary pad adjacent to the contact pad, and an interlevel insulating layer on the semiconductor substrate and having a contact hole for exposing both the contact pad and the auxiliary pad.

Abstract: Methods of forming a channel region between isolation regions of an integrated circuit substrate are disclosed. In particular, a mask can be formed on an isolation region that extends onto a portion of the substrate adjacent to the isolation region to provide a shielded portion of the substrate adjacent to the isolation region and an exposed portion of the substrate spaced apart from the isolation region having the shielded portion therebetween. A channel region can be formed in the exposed portion of the substrate. Related integrated circuits are also discussed.

Abstract: Active areas of integrated circuits can be formed by implanting first ions into a first active area of a substrate adjacent to an isolation structure in the substrate and between a source and a drain region of the integrated circuit to provide a first concentration of ions in the first active area. Second ions are implanted into the first active area and a second active area of the substrate adjacent to the first active area and spaced-apart from the isolation structure on the substrate to provide a second concentration of ions in the second active area and a third concentration of ions in the first active area that is greater than the first and second concentrations. As a result, the level of ion concentration can be higher at the edge of an active channel region than at the center of the channel.

Abstract: An etch-stop layer is selectively provided between layers of a multiple-layered circuit in a selective manner so as to allow for outgassing of impurities during subsequent fabrication processes. The etch-stop layer is formed over an underlying stud so as to serve as an alignment target during formation of an overlying stud formed in an upper layer. In this manner multiple-layered circuits, for example memory devices, can be fabricated in relatively dense configurations.

Abstract: A method of fabricating a MOS transistor is provided. According to the method, a rapid thermal anneal is applied to a semiconductor substrate having active regions doped with well impurity ions and channel impurity ions. Thus, during implantation of the well and the channel impurity ions, crystalline defects resulting from the implantation can be cured by the rapid thermal anneal.

Abstract: A ferroelectric memory device and a method for manufacturing the same. The ferroelectric memory device comprises a lower interlayer insulating layer formed on a semiconductor substrate. The ferroelectric memory device further comprises at least two adjacent ferroelectric capacitors disposed on the lower interlayer insulating layer, an interlayer insulation layer formed over the ferroelectric capacitors, leaving a top surface of the ferroelectric capacitors exposed, a patterned via etch-stop layer formed on the interlayer insulation layer, leaving the top surface of the capacitors exposed, an upper interlayer insulating layer formed on the patterned via etch-stop layer, and a plate line commonly connected to the at least two adjacent ferroelectric capacitors. Thus, integration of the ferroelectric memory device can be substantially increased.

Abstract: A ferroelectric memory device along with a method of forming the same are provided. A first interlayer insulating layer is formed on a semiconductor substrate. A buried contact structure is formed on the first interlayer insulating layer. The buried contact structure is electrically connected to the substrate through a first contact hole extending through the first interlayer insulating layer. A blocking layer covers or encapsulates the buried contact structure and the first interlayer insulating layer. A second interlayer insulating layer is formed on the blocking layer. A ferroelectric capacitor formed on the second interlayer insulating layer and is electrically connected to the buried contact structure through a second contact hole that penetrates the second interlayer insulating layer and the blocking layer.

Abstract: A method of manufacturing a semiconductor device including a ferroelectric capacitor is provided. A conductive plug is formed in a first insulating layer on a semiconductor substrate. A first lower metal layer is formed overlying the conductive plug. A lower metal oxide layer is formed on the first lower metal layer. A second lower metal layer is formed on top of the lower metal oxide layer. A ferroelectric layer is formed from a ferroelectric material on the lower electrode layer at a crystallizing temperature of approximately 700° C. A first upper metal layer is formed on top of the ferroelectric layer. Thereafter, a heat treatment higher than the crystallizing temperature is performed. An upper metal oxide layer is formed on top of the first upper metal layer. A second upper metal layer is formed on top of the upper metal oxide layer.

Abstract: A semiconductor memory device and a method for manufacturing the same are provided.

Abstract: A ferroelectric random access memory device according to the present invention includes a pulse generator circuit capable of generating a pulse signal in response to an address transition. A chip enable buffer circuit activates a chip enable flag signal in response to a first transition of the pulse signal. A row selector circuit selects and drives one of the rows in response to the address. The row selector circuit also generates a flag signal indicating a selection of a plate line. A control circuit activates a plate control signal in response to the activation of a write enable signal, and deactivates the plate control signal in response to a second transition of the pulse signal. A plate line of a selected row is re-activated according to activation of the plate control signal and is deactivated according to deactivation of the plate control signal.

Abstract: A ferroelectric memory device and a method for manufacturing the same. The ferroelectric memory device comprises a lower interlayer insulating layer formed on a semiconductor substrate. The ferroelectric memory device further comprises at least two adjacent ferroelectric capacitors disposed on the lower interlayer insulating layer, an interlayer insulation layer formed over the ferroelectric capacitors, leaving a top surface of the ferroelectric capacitors exposed, a patterned via etch-stop layer formed on the interlayer insulation layer, leaving the top surface of the capacitors exposed, an upper interlayer insulating layer formed on the patterned via etch-stop layer, and a plate line commonly connected to the at least two adjacent ferroelectric capacitors. Thus, integration of the ferroelectric memory device can be substantially increased.

Abstract: A memory cell array block has unit memory cells comprised of pairs of memory cells, each of have a memory cell and a complementary memory cell. A second unit memory cell is interleaved with the first unit memory cell, a fourth unit memory cell is interleaved with a third unit memory cell. First and second sense amplifiers are disposed over and under the array block, respectively. The first switch connects bitlines coupled to the first unit memory cell with the first sense amplifier and connects bitlines coupled to the second unit memory cell with the second sense amplifier. The second switch connects bitlines coupled to the third unit memory cell with the first sense amplifier and connects bitlines coupled to the fourth unit memory cell with the second sense amplifier. A selected unit memory cell is selectively connected with a sense amplifier, decreasing the number of sense amplifiers.

Abstract: Methods for forming an electronic device can include forming a capacitor structure on a portion of a substrate with the capacitor structure including a first electrode on the substrate, a capacitor dielectric on the first electrode, a second electrode on the dielectric, and a hard mask on the second electrode. More particularly, the capacitor dielectric can be between the first and second electrodes, the first electrode and the capacitor dielectric can be between the second electrode and the substrate, and the first and second electrodes and the capacitor dielectric can be between the hard mask and the substrate. An interlayer dielectric layer can be formed on the hard mask and on portions of the substrate surrounding the capacitor structure, and portions of the interlayer dielectric layer can be removed to expose the hard mask while maintaining portions of the interlayer dielectric layer on portions of the substrate surrounding the capacitor structure.

Abstract: An integrated circuit device structure which avoids misalignment when a contact hole is formed to expose a contact pad and a method of fabricating the same, are provided. The integrated circuit device includes a semiconductor substrate having a conductive region and an insulating region, a contact pad on the conductive region of the semiconductor substrate, an auxiliary pad adjacent to the contact pad, and an interlevel insulating layer on the semiconductor substrate and having a contact hole for exposing both the contact pad and the auxiliary pad.

Abstract: A method of fabricating a MOS transistor is provided. According to the method, a rapid thermal anneal is applied to a semiconductor substrate having active regions doped with well impurity ions and channel impurity ions. Thus, during implantation of the well and the channel impurity ions, crystalline defects resulting from the implantation can be cured by the rapid thermal anneal.