Abstract: The invention defines a pillar pattern or an island pattern by forming a contact hole and filling the contact hole with a hard mask material by using a spacer formation process, so that the mask pattern formation process margin for island (e.g., pillar) pattern formation is increased. Accordingly, the yield and reliability of the formation process of a semiconductor device are improved.

Abstract: There is provided a method for forming a porous dielectric film stably by: forming a surface densification layer by processing a surface of an SiOCH film formed by a plasma CVD process while using an organic silicon compound source; and releasing CHx groups or OH group from the SiOCH film underneath the surface densification layer by hydrogen plasma processing through the surface densification layer with a controlled rate.

Abstract: Some embodiments include methods of forming isolation regions in which spin-on material (for example, polysilazane) is converted to a silicon dioxide-containing composition. The conversion may utilize one or more oxygen-containing species (such as ozone) and a temperature of less than or equal to 300° C. In some embodiments, the spin-on material is formed within an opening in a semiconductor material to form a trenched isolation region. Other dielectric materials may be formed within the opening in addition to the silicon dioxide-containing composition formed from the spin-on material. Such other dielectric materials may include silicon dioxide formed by chemical vapor deposition and/or silicon dioxide formed by high-density plasma chemical vapor deposition.

Abstract: A method of treating a dielectric layer on a substrate is described. The method comprises forming the dielectric layer on the substrate, wherein the dielectric layer comprises a dielectric constant value less than the dielectric constant of SiO2. A feature pattern is formed in the dielectric layer using an etching process. Following the etching process, the feature pattern is treated using a nitrogen-containing plasma in order to form nitride surface layers by introducing nitrogen to the exposed surfaces of the dielectric layer in the feature pattern. Thereafter, the feature pattern is selectively etched to partially or fully remove the nitride surface layers.

Abstract: A process for producing an insulation structure with openings of a low aspect ratio is disclosed. In one embodiment, a dopant is introduced into the insulation structure with a concentration which on average increases or decreases in the vertical direction from a pre-processed semiconductor surface, the openings are formed in a dry-etching step and the aspect ratio of the openings is reduced by increasing the basic surface area of the openings using a subsequent wet-chemical etching step.

Abstract: A method for forming a fine-pitch pattern on a semiconductor substrate is provided. The method includes patterning the semiconductor substrate to form a plurality of fine lines, forming a thermal oxide layer on the fine lines, polishing the thermal oxide layer to expose a top surface of the fine lines; etching the fine lines using the thermal oxide layer as a mask to expose first portions of the semiconductor substrate, etching a central bottom portion of the thermal oxide layer to expose second portions of the semiconductor substrate, and etching the semiconductor substrate using the etched thermal oxide layer as a mask.

Abstract: A first oxide film and a second oxide film 16 are formed in a first region 13a and a second region 13b, respectively, on the surface of the semiconductor substrate 10, via thermal oxidization method, and the first oxide film is removed while the second oxide film 16 is covered with the resist layer 18 formed thereon, and then the resist layer 18 is removed with a chemical solution containing an organic solvent such as isopropyl alcohol as a main component. Subsequently, a third oxide film 22 having different thickness than the second oxide film 16 is formed in the first region 13a.

Abstract: The present invention relates to semiconductor devices, preferably dynamic random access memory (DRAM) cells, each of which contains at least one trench capacitor with a buried isolation collar. The trench capacitor is located in a trench in a semiconductor substrate, and it comprises inner and outer electrodes and a dielectric layer. The buried isolation collar is recessed into a sidewall of the trench and has a substantially uniform thickness. Such a buried isolation collar is preferably formed by oxygen implantation before trench etching.

Abstract: A method for making a semiconductor device structure, includes: providing a substrate; forming on the substrate: a first layer below and second layers on a gate with spacers, source and drain regions adjacent to the gate, silicides on the gate and source and drain regions; disposing a stress layer over the structure resulting from the forming step; disposing an insulating layer over the stress layer; removing portions of the insulating layer to expose a top surface of the stress layer; removing the top surface and other portions of the stress layer and portions of the spacers to form a trench, and then disposing a suitable stress material into the trench.

Abstract: In methods for smoothing or polishing a surface of a wafer, such as a silicon wafer, a liquid layer is formed on a surface of the wafer. The liquid layer may be an invisible microscopic layer, or a visible macroscopic layer. A flow of an oxidizing gas is directed over, against or onto the liquid layer of the surface of the wafer, in the presence of an etchant. The flow of gas thins the liquid layer at high points or areas on the surface of the wafer more than at low points or areas on the wafer surface. Consequently, the high points are oxidized and etched away more than the low points. As a result, the wafer surface is smoothed and polished.

Abstract: The present invention discloses an etching apparatus comprising an etching bath having an etchant; an etchant recycling part in the etching bath; a DI and undiluted etchant supply part for supplying a DI water and a undiluted etchant; an etchant mixing part for mixing the DI water and the undiluted etchant; and an etchant heating part for heating the mixed etchant.

Abstract: Described herein are methods of forming a thin silicon dioxide layer having a thickness of less than eight angstroms on a semiconductor substrate to form the bottom layer of a gate dielectric. A silicon dioxide layer having a thickness of less than eight angstroms may be formed by two different methods. In one method, a sulfuric acid solution is applied to a semiconductor substrate to grow a silicon dioxide layer of less than eight angstroms. The growth of the silicon dioxide layer by the sulfuric acid solution is self-limiting. In another method, a hydrogen peroxide containing solution is applied to a semiconductor substrate for a time sufficient to grow a silicon dioxide layer having a thickness of greater than eight angstroms and then applying an etching solution to etch the silicon dioxide layer down to a thickness of less than eight angstroms.

Abstract: Provided is a nitride-based semiconductor light emitting device having increased efficiency and power characteristics and method of manufacturing the same. The method may include forming a sacrificial layer on a substrate, forming a passivation layer on the sacrificial layer, forming a plurality of masking dots of a metal nitride on the passivation layer, laterally epitaxially growing a nitride-based semiconductor layer on the passivation layer using the masking dots as masks, forming a semiconductor device on the nitride-based semiconductor layer, and wet etching the sacrificial layer to separate and/or remove the substrate from the semiconductor device.

Abstract: A method and apparatus for fabricating or altering a microstructure use means for heating to facilitate a local chemical reaction that forms or alters the submicrostructure.

Abstract: A method of fabricating a semiconductor device is disclosed. The method includes defining an electrode on a semiconductor substrate; forming a spacer on at least one sidewall of the electrode; performing a process operation on the semiconductor substrate using the spacer as a mask and forming a material layer on the top or the surface of the semiconductor substrate and the electrode; and removing the spacer by steps of performing a wet etching process at a temperature in a range of 100° C. to 150° C. to etch the spacer using an acid solution containing phosphoric acid as an etchant. With respect to another aspect, a method of removing a spacer is also disclosed. The method includes performing a wet etching process at a temperature in a range of 100° C. to 150° C. to etch the spacer using an acid solution containing phosphoric acid as an etchant.

Abstract: Systems and methods for molecular self-assembly are provided. The molecular self-assembly receives a substrate that includes one or more regions of dielectric material. A molecularly self-assembled layer is formed on an exposed surface of the dielectric material. The molecularly self-assembled layer includes material(s) having a molecular characteristic and/or a molecular type that includes one or more of a molecular characteristic and/or a molecular type of a head group of molecules of the material, a molecular characteristic and/or a molecular type of a terminal group of molecules of the material, and a molecular characteristic and/or a molecular type of a linking group of molecules of the material. The molecular characteristic(s) and molecular type(s) are selected according to at least one pre-specified property of the molecularly self-assembled layer.

Abstract: A nanometer-scale post structure and a method for forming the same are disclosed. More particularly, a post structure, a light emitting device using the structure, and a method for forming the same, which is capable of forming a nanometer-scale post structure having a repetitive pattern by using an etching process, are disclosed. The method includes forming unit patterns on a substrate by use of a first material, growing a wet-etchable second material on the substrate formed with the unit patterns, and wet etching the substrate having the grown second material.

Abstract: A mask for laser-crystallizing amorphous silicon into polysilicon is provided. The mask comprises a transparent substrate having a first block, a second block, and a third block with equal sizes. The second block is located between the first block and the third block. The first block includes a plurality of first transmission regions and a plurality of first opaque regions located between the first transmission regions. The second block includes a plurality of second transmission regions correspond to the first opaque regions and a plurality of second opaque regions located between the second transmission regions and corresponds to the first transmission regions. The third block includes a plurality of third transmission regions arranged corresponding to the centers of the first transmission regions and corresponding to centers of the second transmission regions and a plurality of third opaque regions located between the third transmission regions.

Abstract: In a method for removing a nitride layer of a semiconductor device, an etchant including about 15 to about 40 percent by volume of hydrofluoric acid, about 15 to about 60 percent by volume of phosphorous acid, and about 25 to about 45 percent by volume of deionized water is prepared. The etchant is provided onto a nitride layer that is formed on a bevel, a front side or a backside of a substrate to remove the nitride layer. The substrate is rinsed using deionized water, and then the substrate is dried. The etchant rapidly removes the nitride layer at a relatively low temperature to avoid damage to the substrate.

Abstract: A structure, for testing relative to an MOS transistor, closely resembles the MOS transistor of interest. For example, certain dimensions and a number of dopant concentrations typically are substantially the same in the test structure as found in corresponding elements of the MOS transistor of interest. However, the regions of the test structure corresponding to the source and drain of the transistor have no halos or extensions that might cause gate overlap; and in the test structure, these regions are of a semiconductor type opposite the type found in the source and drain of the transistor. The test structure enables accurate measurement of the gate-body current, for modeling floating body effects and/or for direct electrical measurement of gate length.

Abstract: The invention relates to a method of manufacturing a semiconductor device comprising the step of removing a silicon and nitrogen containing material by means of wet etching with an aqueous solution comprising hydrofluoric acid in a low concentration, the aqueous solution being applied under elevated pressure to reach a temperature above 100° C.