Abstract: A logic device having a vertically extending MIM capacitor between interconnect layers includes a semiconductor substrate. A lower interconnect layer is located over the semiconductor substrate, and an upper interconnect layer is located over the lower interconnect layer. A U-shaped lower metal plate is interposed between the lower interconnect layer and the upper interconnect layer. The U-shaped lower metal plate directly contacts the lower interconnect layer. The capacitor dielectric layer covers the inner surface of the lower metal plate. Further, the capacitor dielectric layer has an extension portion interposed between the brim of the lower metal plate and the upper interconnect layer. An upper metal plate covers the inner surface of the capacitor dielectric layer. The upper metal plate is in contact with the upper interconnect layer and is confined by the capacitor dielectric layer.

Abstract: In some embodiments, an integrated circuit device includes a substrate and an interlevel-insulating layer on the substrate that has a hole therein that exposes the substrate. A unitary lower electrode of a capacitor is disposed on the substrate and has a contact plug portion thereof that is disposed in the hole. A dielectric layer is on the lower electrode and an upper electrode of the capacitor is on the dielectric layer. In other embodiments, an integrated circuit device includes a substrate and an interlevel-insulating layer on the substrate that has a hole therein that exposes the substrate. A barrier layer is disposed on the exposed portion of the substrate and on sidewalls of the interlevel-insulating layer. A contact plug is disposed in the hole on the barrier layer. A lower electrode of a capacitor is disposed on the contact plug and engages the contact plug at a boundary therebetween. A dielectric layer is on the lower electrode and an upper electrode of the capacitor is on the dielectric layer.

Abstract: There are provided an analog capacitor having at least three high-k dielectric layers, and a method of fabricating the same. The analog capacitor includes a lower electrode, an upper electrode, and at least three high-k dielectric layers interposed between the lower electrode and the upper electrode. The at least three high-k dielectric layers include a bottom dielectric layer contacting the lower electrode, a top dielectric layer contacting the upper electrode, and a middle dielectric layer interposed between the bottom dielectric layer and the top dielectric layer. Further, each of the bottom dielectric layer and the top dielectric layer is a high-k dielectric layer, the absolute value of the quadratic coefficient of VCC thereof being relatively low compared to that of the middle dielectric layer, and the middle dielectric layer is a high-k dielectric layer having a low leakage current compared to those of the bottom dielectric layer and the top dielectric layer.

Abstract: A method of forming a carbon nano-material layer may involve a cyclic deposition technique. In the method, a chemisorption layer or a chemical vapor deposition layer may be formed on a substrate. Impurities may be removed from the chemisorption layer or the chemical vapor deposition layer to form a carbon atoms layer on the substrate. More than one carbon atoms layer may be formed by repeating the method.

Abstract: A method for manufacturing a capacitor of a semiconductor memory device by controlling thermal budgets is provided. In the method for manufacturing a capacitor of a semiconductor memory device, a lower electrode is formed on a semiconductor substrate. The lower electrode is heat-treated with a first thermal budget. A dielectric layer is formed on the heat-treated lower electrode. The dielectric layer is crystallized by heat-treating the dielectric layer with a second thermal budget which is smaller than the first thermal budget.

Abstract: Provided is an atomic layer deposition (ALD) method for forming a thin film using two types of reactants that are different in surface adsorptivity for a source material. According to the ALD method, first, a source material is fed into a reaction chamber and then undergoes first purging. Next, a first reactant with good surface adsorptivity for the source material and a second reactant with poor surface adsorptivity for the source material are fed into the reaction chamber. The second reactant may be fed simultaneously with the first reactant or after the purging of the first reactant. Next, a radio frequency is applied to the reaction chamber to thereby transform the second reactant into a plasma state. Next, the reaction chamber is subjected to a second purging. If the thickness of a deposited film is not sufficient, the above-described processes are repeated.

Abstract: In a method of manufacturing a capacitor by performing a multi-stepped wet treatment on the surface of a metal electrode, a lower metal electrode of a capacitor is formed, and a primary wet treatment is performed on the surface of the lower metal electrode to remove unwanted surface oxides that may exist on the surface of the lower metal electrode. A secondary wet treatment is then performed on the surface of the lower metal electrode by using a different etchant than the etchant used in the primary wet treatment, in order to remove unwanted surface organic materials that may exist on the surface of the lower metal electrode. A dielectric layer is then formed on the lower metal electrode using a high-k dielectric material. An upper metal electrode is formed on the dielectric layer.

Abstract: Provided is a capacitor of a semiconductor device. The capacitor includes a capacitor lower electrode disposed on a semiconductor substrate. A first dielectric layer comprising aluminum oxide (Al2O3) is disposed on the capacitor lower electrode. A second dielectric layer comprising a material having a higher dielectric constant than that of aluminum oxide is disposed on the first dielectric layer. A third dielectric layer comprising aluminum oxide is disposed on the second dielectric layer. A capacitor upper electrode is disposed on the third dielectric layer. The capacitor of the present invention can improve electrical properties. Thus, power consumption can be reduced and capacitance per unit area is high enough to achieve high integration.

Abstract: In a method of manufacturing a capacitor of a semiconductor device and an apparatus therefor, dielectric layers are deposited using only a source gas without a reactant gas and a curing process is performed a single time. As a result, process simplification, yield improvement, and equipment simplification are achieved. In a stand-alone memory or an embedded memory, the step coverage is enhanced and oxidation of a storage node contact plug is prevented. Also, in an analog capacitor, an RF capacitor, or a high-voltage capacitor, which uses thicker dielectric layers than the stand-alone capacitor or the embedded capacitor, the manufacturing process is greatly simplified.

Abstract: A capacitor includes an upper electrode formed by physical vapor deposition and chemical vapor deposition. The upper electrode of the capacitor may include a first upper electrode formed by chemical vapor deposition and a second upper electrode formed by physical vapor deposition. Alternatively, the upper electrode may include a first upper electrode formed by physical vapor deposition and a second upper electrode formed by chemical vapor deposition. The upper electrode of the capacitor is formed through two steps using chemical vapor deposition and physical vapor deposition. Therefore, the upper electrode can be thick and rapidly formed, whereby electrical characteristics of the upper electrode are not deteriorated.

Abstract: In a method for forming capacitors of semiconductor devices, a contact plug penetrating an interlayer dielectric (ILD) is formed on a semiconductor substrate. A supporting layer, an etch stop layer, and a molding layer are sequentially formed on the semiconductor substrate where the contact plug is formed. The molding layer is patterned to form a molding pattern. At this time, the molding pattern has an opening exposing an etch stop layer over the contact plug. Next, an adhesive spacer is formed on sidewalls of the opening. The etch stop layer and the supporting layer, which are exposed through the opening where the adhesive spacer is formed, are successively patterned. Thus, the etch stop pattern and the supporting pattern are formed to expose the contact plug. A lower electrode and a sacrificial pattern are formed to sequentially fill a hole region surrounded by sidewalls of the adhesive spacer, the etch stop pattern, and the supporting pattern.

Abstract: A dielectric region for a device such as a memory cell capacitor is formed by depositing a metal oxide, such as tantalum oxide, on a substrate at a first deposition rate in a first atmosphere maintained within a first temperature range and a first pressure range that produce a first tantalum oxide layer with a desirable step coverage. Metal oxide is subsequently deposited on the first metal oxide layer in a second atmosphere maintained within a second temperature range and a second pressure range that produce a second deposition rate greater than the first deposition rate to form a second tantalum oxide layer on the first tantalum oxide layer. For example, the first atmosphere may be maintained at a temperature in a range from about 350° C. to about 460° C. and a pressure in a range from about 0.01 Torr to about 2.0 Torr during formation of a first tantalum oxide layer, and the second atmosphere may be maintained at a temperature in a range from about 400° C. to about 500° C.

Abstract: In a method for forming capacitors of semiconductor devices, a contact plug penetrating an interlayer dielectric (ILD) is formed on a semiconductor substrate. A supporting layer, an etch stop layer, and a molding layer are sequentially formed on the semiconductor substrate where the contact plug is formed. The molding layer is patterned to form a molding pattern. At this time, the molding pattern has an opening exposing an etch stop layer over the contact plug. Next, an adhesive spacer is formed on sidewalls of the opening. The etch stop layer and the supporting layer, which are exposed through the opening where the adhesive spacer is formed, are successively patterned. Thus, the etch stop pattern and the supporting pattern are formed to expose the contact plug. A lower electrode and a sacrificial pattern are formed to sequentially fill a hole region surrounded by sidewalls of the adhesive spacer, the etch stop pattern, and the supporting pattern.

Abstract: In some embodiments, an integrated circuit device includes a substrate and an interlevel-insulating layer on the substrate that has a hole therein that exposes the substrate. A unitary lower electrode of a capacitor is disposed on the substrate and has a contact plug portion thereof that is disposed in the hole. A dielectric layer is on the lower electrode and an upper electrode of the capacitor is on the dielectric layer. In other embodiments, an integrated circuit device includes a substrate and an interlevel-insulating layer on the substrate that has a hole therein that exposes the substrate. A barrier layer is disposed on the exposed portion of the substrate and on sidewalls of the interlevel-insulating layer. A contact plug is disposed in the hole on the barrier layer. A lower electrode of a capacitor is disposed on the contact plug and engages the contact plug at a boundary therebetween. A dielectric layer is on the lower electrode and an upper electrode of the capacitor is on the dielectric layer.

Abstract: A dielectric region for a device such as a memory cell capacitor is formed by depositing a metal oxide, such as tantalum oxide, on a substrate at a first deposition rate in a first atmosphere maintained within a first temperature range and a first pressure range that produce a first tantalum oxide layer with a desirable step coverage. Metal oxide is subsequently deposited on the first metal oxide layer in a second atmosphere maintained within a second temperature range and a second pressure range that produce a second deposition rate greater than the first deposition rate to form a second tantalum oxide layer on the first tantalum oxide layer. For example, the first atmosphere may be maintained at a temperature in a range from about 350° C. to about 460° C. and a pressure in a range from about 0.01 Torr to about 2.0 Torr during formation of a first tantalum oxide layer, and the second atmosphere may be maintained at a temperature in a range from about 400° C. to about 500° C.