Abstract: A semiconductor device and a method for fabricating the same are provided. The provided semiconductor device includes a field oxide layer formed in a semiconductor substrate to define an active region; gate structures formed on the active region; source/drain junctions formed on either side of the gate structures on the semiconductor substrate; a channel silicon layer arranged under the gate insulating layer to operate as a channel for connecting sources and drains; and buried junction isolation insulating layers under the channel silicon layer. The buried junction isolation insulating layers isolate source/drain junction regions of a MOS transistor, so that a short circuit in a bulk region under the channel of a transistor due to the high-integration of the device can be prevented.

Abstract: A semiconductor device including storage nodes of a capacitor and a method for manufacturing the same are provided. Bit lines are formed on a semiconductor substrate, and protection layers are formed to cover and protect the bit lines. Conductive contact pads are formed between the bit lines and are level with the top surfaces of the protection layers. A node supporting layer is formed to cover the conductive contact pads and the protection layers. An etching stopper is formed on the node supporting layer. The mold layer, the etching stopper, and the node supporting layer are patterned, thereby forming opening holes exposing the conductive pads. Storage nodes are formed in the opening holes and have the shape of the profile of the opening holes. The mold layer exposed by the storage nodes is removed, thereby exposing the outer wall of each of the storage nodes positioned above the etching stopper.

Abstract: Ferroelectric memory devices include a ferroelectric memory cell. The ferroelectric memory cell has at least one bit line and a plate line. A control circuit drives the at least one bit line with write data substantially concurrently with activation of the plate line during a write operation. The memory devices may also include a sense amplifier coupled to the ferroelectric memory cell and the control circuit may be further configured to deactivate the plate line substantially concurrently with activation of the sense amplifier during a read operation.

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: In one embodiment, a plurality of gate structures including gate electrodes and insulating layers covering the gate electrodes are formed on a semiconductor substrate. Impurity ions at a low dose for forming a source/drain region are implanted into the semiconductor substrate, using the gate structures as a mask. First insulating spacers are formed on the sidewalls of the gate structures and second insulating spacers are formed on the first insulating spacers. Thereafter, impurity ions at a high dose are implanted into the semiconductor substrate, using the first and second insulating spacers as a mask. Then, the second insulating spacers are removed. Therefore, contact resistance and characteristics of the transistors can be improved by adjusting an effective channel length and contact areas.

Abstract: A method for arranging a power supply line in a semiconductor device including a plurality of memory cell array blocks and a semiconductor device are provided in order to supply stable operating voltages, such as a power supply voltage and a ground voltage, to a sense amplifier allocated to each of the plurality of memory cell array blocks.

Abstract: Methods of forming an integrated circuit device may include forming first and second spaced apart source/drain regions on a surface of a semiconductor substrate. A gate insulating layer can be formed on the semiconductor substrate extending between the first and second spaced apart souce/drain regions. The gate insulating layer can have a reduced thickness at a central portion thereof between the first and second spaced apart source/drain regions. A thickness of the gate insulating layer can increase as it extends toward each of the source/drain regions. A gate electrode can be formed on the gate insulating layer such that the gate insulating layer is between the semiconductor substrate and the gate electrode. Related devices are also discussed.

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: Self-aligned contacts in integrated circuits can be formed on an integrated circuit substrate having an active region. A groove can be formed in the insulating layer and a conductive material can be formed in the groove to a level that is recessed in the groove. An insulating material can be formed in the groove on the conductive material that has an etch selectivity with respect to the insulating layer. A contact that is self-aligned to the active region can be then be formed.

Abstract: Ferroelectric integrated circuit devices, such as memory devices, are formed on an integrated circuit substrate. Ferroelectric capacitor(s) are on the integrated circuit substrate and a further structure on the integrated circuit substrate overlies at least a part of the ferroelectric capacitor(s). The further structure includes at least one layer providing a barrier to oxygen flow to the ferroelectric capacitor(s). An oxygen penetration path contacting the ferroelectric capacitor(s) is interposed between the ferroelectric capacitor(s) and the further structure. The layer providing a barrier to oxygen flow may be an encapsulated barrier layer. Methods for forming ferroelectric integrated circuit devices, such as memory devices, are also provided.

Abstract: A method for arranging a power supply line in a semiconductor device including a plurality of memory cell array blocks and a semiconductor device are provided in order to supply stable operating voltages, such as a power supply voltage and a ground voltage, to a sense amplifier allocated to each of the plurality of memory cell array blocks.

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

Abstract: A ferroelectric random access memory device of the present invention includes an access transistor having a gate connected to a word line and a current path connected between a bit line and an internal cell node. A ferroelectric capacitor is connected between the internal cell node and a plate line. A reference voltage generator for generating a reference voltage includes a linear paraelectric capacitor. Data stored in the ferroelectric capacitor is sensed by activating the word line so as to connect the ferroelectric capacitor to the bit line. The plate line is then activated and simultaneously the reference capacitor is connected to a complementary bit line. After a voltage difference between the bit line and the complementary bit line is detected, the reference capacitor is insulated from the complementary bit line.

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: 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: 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: 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.

Abstract: A ferroelectric capacitor with a ferroelectric film having a relatively larger amount of titanium constituent than zirconate constituent improves ferroelectric characteristics. The method for fabricating the ferroelectric capacitor includes the step of performing a heat treatment in an oxygen atmosphere after forming a contact opening in an insulating layer which covers an already formed ferroelectric capacitor. This heat treatment in an oxygen atmosphere can minimize undesirable side effects resulting from a platinum electrode oxidizing the ferroelectric film components.

Abstract: Methods of forming an integrated circuit device may include forming first and second spaced apart source/drain regions on a surface of a semiconductor substrate. A gate insulating layer can be formed on the semiconductor substrate extending between the first and second spaced apart souce/drain regions. The gate insulating layer can have a reduced thickness at a central portion thereof between the first and second spaced apart source/drain regions. A thickness of the gate insulating layer can increase as it extends toward each of the source/drain regions. A gate electrode can be formed on the gate insulating layer such that the gate insulating layer is between the semiconductor substrate and the gate electrode. Related devices are also discussed.

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.