Abstract: A cleaning apparatus includes upper and lower nozzle assemblies supplying a cleaning liquid to edge and bottom sections of a semiconductor substrate. The upper nozzle assembly has a first nozzle supplying the cleaning liquid onto the edge section, and second and third nozzles supplying a nitrogen gas for preventing the cleaning liquid from moving into a center portion of the semiconductor substrate. The cleaning liquid supplied to the edge section flows from the edge section towards a side section of the semiconductor substrate due to the rotation of the semiconductor substrate. An ultrasonic wave generator is provided above the edge section for generating ultrasonic waves. The ultrasonic waves are applied to the cleaning liquid supplied onto the edge and bottom sections, thereby improving the cleaning efficiency. The cleaning apparatus has a guide to guide the cleaning liquid supplied to the edge section toward the side section.

Abstract: An apparatus for polishing a wafer is provided. The apparatus comprises a polishing pad for polishing the wafer. The polishing pad is divided into multiple portions that are rotated in a substantially same direction. At least one of the portions of the polishing pad is adapted to rotate at a speed different than the other portions. A driving unit is also provided for moving the polishing pad. A polishing head is employed for maintaining the side of the wafer to be polished engaged with the polishing pad, for contacting the polished surface of the wafer with the polishing pad, and for rotating the wafer.

Abstract: Methods of manufacturing a semiconductor device are provided. A trench is formed in a semiconductor substrate. A first field oxide layer is formed that partially fills the trench. The first field oxide layer defines an active region of the substrate that is adjacent to the trench. An upper portion of sidewalls of the trench extends upward beyond a surface of the first field oxide layer. A first liner is formed on the first field oxide layer and on the portion of the sidewalls of the trench that extend upward beyond the first field oxide layer. A second field oxide layer is formed on the first liner and fills the trench. The second field oxide layer and the first liner are each partially removed to expose a top adjacent surface and upper sidewalls of the trench along the active region of the substrate. A dielectric layer is formed on the exposed top adjacent surface and upper sidewalls of the trench. A gate electrode is formed on the dielectric layer.

Abstract: Methods of forming non-volatile memory devices include the steps of forming a semiconductor substrate having first and second floating gate electrodes thereon and an electrically insulating region extending between the first and second floating gate electrodes. A step is then performed to etch back the electrically insulating region to expose upper corners of the first and second floating gate electrodes. Another etching step is then performed. This etching step includes exposing upper surfaces and the exposed upper corners of the first and second floating gate electrodes to an etchant that rounds the exposed upper corners of the first and second floating gate electrodes. The step of etching back the electrically insulating region includes etching back the electrically insulating region to expose sidewalls of the first and second floating gate electrodes having heights ranging from about 30 ? to about 200 ?.

Abstract: Cleaning solutions for integrated circuit devices and methods of cleaning integrated circuit devices using the same are disclosed. The cleaning solution includes about 30% aqueous ammonia solution, acetic acid by a volume percent higher then a volume percent of the aqueous ammonia solution, and deionized water by a volume percent higher then the volume percent of the acetic acid. Additionally, disclosed are methods wherein the cleaning solution is formed on integrated circuit substrates having an exposed metal pattern formed thereon, and further providing mega-sonic energy to the film of the cleaning solution.

Abstract: A corrosion-inhibiting cleaning composition for semiconductor wafer processing includes an aqueous admixture of at least water, a surfactant and a corrosion-inhibiting compound selected from a group consisting of amino phosphonates, polyamines and polycarboxylic acids. The quantity of the corrosion-inhibiting compound in the admixture is preferably in a range from about 0.0001 wt % to about 0.1 wt % and the quantity of the surfactant is preferably in a range from about 0.001 wt % to about 1.0 wt %. The aqueous admixture may also include sulfuric acid and a fluoride, which act as oxide etchants, and a peroxide, which acts as a metal etchant.

Abstract: A method for fabricating a non-volatile memory device is provided.

Abstract: For planarizing an IC (integrate circuit) material, a first slurry is dispensed for a first planarization of the IC material using the first slurry, and a second slurry is dispensed for a second planarization of the IC material using the second slurry. The first and second slurries are different. For example, the first slurry is silica based for faster planarization during the first planarization. Thereafter, the second planarization is performed with the second slurry that is ceria based with higher planarity for attaining sufficient planarization of the IC material.

Abstract: In one embodiment, an apparatus includes a cleaning bath for containing a cleaning solution, one or more substrate holders configured to support the substrate in the cleaning solution, means for removing the substrate from the cleaning solution, and means for releasing the one or more substrate holders from the substrate while the one or more substrate holders are immersed in the cleaning solution. Therefore, the formation of water spots or chemical stains on a substrate can be prevented.

Abstract: The chemical mechanical polishing (CMP) apparatus includes an insert pad that forms a local step on an upper surface of a polishing pad assembly. The insert pad is interposed between a rotatable platen and the polishing pad assembly.

Abstract: Embodiments of the invention include a megasonic energy cleaning apparatus that has the ability to rotate the wafer to be cleaned, as well as rotate the cleaning probe during the cleaning process. Rotating the cleaning probe while the wafer is being cleaned is effective to increase the cleaning action of the apparatus while also minimizing damage to the wafer. Curved grooves, such as a spiral groove, can be etched into the cleaning probe to minimize forming harmful waves that could potentially cause damage to the wafer surface or to structures already made on the surface. Using a cleaning probe having a curved groove while also rotating the cleaning probe effectively cleans particles from a wafer while also limiting damage to the surface of the wafer.

Abstract: Disclosed is a method for forming a shallow trench isolation. A pad oxide layer is formed on a semiconductor substrate. First and second stopping layers are sequentially formed on the pad oxide layer. The second stopping layer, the first stopping layer, the pad oxide layer and the semiconductor substrate are etched to form a second stopping layer pattern, a first stopping layer pattern, a pad oxide layer pattern and a trench. A trench inner wall oxide layer is formed at an inner surface portion of the trench. A nitride layer liner is formed on a resulted structure. A field oxide layer is formed in the trench. By selectively removing the second stopping layer pattern, the first stopping layer pattern is exposed. Then, the first stopping layer pattern is removed. Since the chemical mechanical polishing is stopped at the second stopping layer pattern, the first stopping layer pattern is prevented from erosion when the chemical mechanical polishing process is carried out.

Abstract: Cleaning solutions for integrated circuit devices and methods of cleaning integrated circuit devices using the same are disclosed. The cleaning solution includes about 30% aqueous ammonia solution, acetic acid by a volume percent higher then a volume percent of the aqueous ammonia solution, and deionized water by a volume percent higher then the volume percent of the acetic acid. Additionally, disclosed are methods wherein the cleaning solution is formed on integrated circuit substrates having an exposed metal pattern formed thereon, and further providing mega-sonic energy to the film of the cleaning solution.

Abstract: A method of fabricating a non-volatile memory device, which has a tunnel insulating layer consisting of two or more portions of different thickness, cell transistors, and auxiliary transistors for applying external voltage and for interfacing with peripheral circuits is described. According to the method, the tunnel insulating layer, a conductive layer, and a first insulating layer are sequentially deposited over a semiconductor substrate. The resultant structure is selectively etched to a given depth to form trenches. A second insulating layer is deposited over the substrate including the trenches, and the second insulating layer is selectively removed so as to form element isolation regions consisting of the trenches filled with the second insulating layer. The first insulating layer is selectively removed, and the second insulating layer is selectively removed by a CMP process to expose the conductive layer. The conductive layer is used as the stopping layer during the CMP process.

Abstract: Disclosed is an organic stripping composition and a method of etching a semiconductor device in which the generation of an Si pitting phenomenon can be prevented. The composition includes a compound including a hydroxyl ion (OH−), a compound including a fluorine ion (F−) and a sufficient amount of an oxidizing agent to control the pH of the composition within the range of from about 6.5 to about 8.0. The method includes dry ethcing an oxide by a dry etching using a plasma, and then ashing the etched oxide using an ashing process to remove an organic material. The method further includes supplying the organic stripping composition to remove residues including any residual organic material, a metal polymer, and an oxide type polymer. The stripping composition is stable onto various metals and does not induce the Si pitting phenomenon.

Abstract: A slurry composition useful for chemical mechanical polishing of the surface of a material layer, e.g., a silicon oxide layer, is disclosed. A first material surface which is exposed to the slurry exhibits hydrophilicity, while a second material layer, e.g., a polysilicon layer, the surface of which is also exposed to the slurry, exhibits hydrophobicity, and accordingly acts as a polishing stopping layer. The slurry composition consists essentially of water, abrasive grains, and a polymer additive having both hydrophilic and hydrophobic functional groups.

Abstract: An apparatus for cleaning a semiconductor substrate has a chuck for rotatably supporting the semiconductor substrate, and a horizontally movable probe for applying ultrasonic vibrations uniformly to cleaning solution supplied onto an upper surface of the semiconductor substrate. The probe makes contact with the cleaning solution supplied and extends vertically from the upper surface of the substrate. The cross-sectional area of the probe gradually increases in a direction towards the semiconductor substrate so that the ultrasonic vibrations are widely distributed to the cleaning solution. The lower surface of the probe has surface features that act to disperse a reflected wavefront of the vibrational energy. Thus, patterns formed on the semiconductor substrate will not be damaged by the ultrasonic vibrations.

Abstract: Disclosed is a method of planarizing a non-volatile memory device. After forming a floating gate structure on a cell area of a semiconductor substrate, a conductive layer, a hard mask layer and a first insulating layer are sequentially formed on the entire surface of the resultant structure. After removing the first insulating layer of the cell area to leave a first insulating layer pattern only on the peripheral circuit area, the hard mask layer of the cell area is removed. A second insulating layer is formed on the conductive layer and the insulating layer pattern to increase the height of the insulating layer on the peripheral circuit area. The second insulating layer and the first insulating layer pattern are removed until the floating gate structure is exposed, thereby planarizing the cell area and the peripheral circuit area.

Abstract: A semiconductor device having multi-gate insulating layers and methods of fabricating the same are provided. The semiconductor device includes an isolation region disposed at a predetermined region of a semiconductor substrate. The isolation region defines at least one first active region and at least one second active region. The first active region is covered with a first gate insulating layer, and the second active region is covered with a second gate insulating layer which is thinner than the first gate insulating layer. Preferably, the top surface of the first gate insulating layer has the same height as the that of the second gate insulating layer. The isolation region is filled with an isolation layer which preferably covers the entire sidewalls of the first and second gate insulating layers. A typical method includes the step of selectively forming a first gate insulating layer at a predetermined region of a semiconductor substrate.

Abstract: A method of fabricating a semiconductor device having a capacitor with a high dielectric constant layer includes a groove for an alignment key is formed together with a contact hole on a substrate; a conductive layer of tungsten is formed to fill the contact hole and cover the inner surface of the groove; a capping layer for use as an oxygen barrier is stacked on the conductive layer of tungsten; a planarization process is performed using CMP to leave the capping layer and the conductive layer of tungsten covering the inner surface of the groove to form a contact plug filling the contact hole; a capacitor bottom electrode layer is stacked to contact the top surface of the contact plug; a high dielectric constant layer is stacked on the bottom electrode layer; and an oxidation treatment is performed at a high temperature to crystallize the high dielectric constant layer.