Class / Patent application number | Description | Number of patent applications / Date published |
438437000 | Conformal insulator formation | 25 |
20080242046 | Method on Forming an Isolation Film or a Semiconductor Device - A method of forming an isolation film in a semiconductor device is disclosed. The disclosed method includes performing a patterning process on a predetermined region of a semiconductor substrate in which a patterned pad film is formed, forming a trench defining an inactive region and an active region, forming a liner film on the entire surface including the trench, forming an insulating film for trench burial only within the trench, stripping the remaining liner film formed except for the inside of the trench and the patterned pad film formed below the liner film, forming a sacrificial film on the entire surface, and performing a polishing process on the entire surface in which the sacrificial film is formed until the semiconductor substrate of the active region is exposed, thereby forming the isolation film having no topology difference with the semiconductor substrate of the active region. | 10-02-2008 |
20080268612 | METHOD OF FORMING ISOLATION LAYER IN SEMICONDUCTOR DEVICE - The present invention discloses to a method of forming an isolation layer in a semiconductor device. In particular, the method of forming an isolation layer in a semiconductor device of the present invention comprises the steps of providing a semiconductor substrate on which a trench is formed; forming spacers on side walls of the trench; forming a first insulating layer to fill a portion of the trench such that a deposition rate on the semiconductor substrate which is a bottom surface of the trench and exposed between the spacers is higher than that on a surface of the space; and forming a second insulating layer on the first insulating layer so as to fill the trench with the second insulating layer. An O | 10-30-2008 |
20090170283 | Method of Fabricating Non-Volatile Memory Device - A method of fabricating a non-volatile memory device, A tunnel insulating layer, a floating gate, and a pad nitride layer is formed on a semiconductor substrate. A isolation region of the semiconductor substrate is formed by etching to a predetermined depth, and a liner insulating layer is formed on an entire surface of the resulting trench for device isolation. A filling insulation layer is formed on the liner insulating layer to fill the trench and a first etching process is performed on the filling insulation layer and the liner insulating layer. The surface of semiconductor is recessed by performing a second etching process on the filling insulation layer. A capping layer is formed on an entire surface of the result formed by the second etching process. The device isolation layer of a concave shape is formed by performing an etching process on the capping layer. | 07-02-2009 |
20090203190 | Method of forming a mask stack pattern and method of manufacturing a flash memory device including an active area having rounded corners - A method of forming a mask stack pattern and a method of manufacturing a flash memory device including an active area having rounded corners are provided. The method of manufacture including forming a mask stack pattern defining an active region, the mask stack pattern having a pad oxide layer formed on a semiconductor substrate, a silicon nitride layer formed on the pad oxide layer and a stack oxide layer formed on the silicon nitride layer, oxidizing a surface of the semiconductor substrate exposed by the mask stack pattern and lateral surfaces of the silicon nitride layer such that corners of the active region are rounded, etching the semiconductor substrate having an oxidized surface to form a trench in the semiconductor substrate, forming a device isolation oxide layer in the trench, removing the silicon nitride layer from the semiconductor substrate, and forming a gate electrode in a portion where the silicon nitride layer is removed. | 08-13-2009 |
20090233416 | FLASH MEMORY DEVICES COMPRISING PILLAR PATTERNS AND METHODS OF FABRICATING THE SAME - Flash memory devices include pillar patterns formed between selected pairs of floating gates and control gate extensions that penetrate between selected pairs of floating gates are provided. Methods of fabricating the flash memory devices are also provided. | 09-17-2009 |
20090253243 | Methods of Manufacturing Non-Volatile Memory Devices - In a method of manufacturing a non-volatile memory device, a conductive structure is formed on a substrate. The conductive structure includes a tunnel oxide pattern, a first conductive pattern, a pad oxide pattern and a hard mask pattern. A trench is formed on the substrate using the conductive structure as an etching mask. An inner oxide layer is formed on an inner wall of the trench and sidewalls of the tunnel oxide pattern and the first conductive pattern. The inner oxide layer is cured, thereby forming a silicon nitride layer on the inner oxide layer. A device isolation pattern is formed in the trench, and the hard mask pattern and the pad oxide pattern are removed from the substrate. A dielectric layer and a second conductive pattern are formed on the substrate. Accordingly, the silicon nitride layer prevents hydrogen (H) atoms from leaking into the device isolation pattern. | 10-08-2009 |
20090253244 | Nonvolatile Memory Devices Having Gate Structures Doped by Nitrogen and Methods of Fabricating the Same - Nonvolatile memory devices are provided including an integrated circuit substrate and a charge storage pattern on the integrated circuit substrate. The charge storage pattern has a sidewall and a tunnel insulating layer is provided between the charge storage pattern and the integrated circuit substrate. A gate pattern is provided on the charge storage pattern. A blocking insulating layer is provided between the charge storage pattern and the gate pattern. The sidewall of the charge storage pattern includes a first nitrogen doped layer. Related methods of fabricating nonvolatile memory devices are also provided herein. | 10-08-2009 |
20100167496 | METHOD FOR FORMING DEVICE ISOLATION LAYER OF SEMICONDUCTOR DEVICE AND NON-VOLATILE MEMORY DEVICE - A method for forming a device isolation layer of a semiconductor device or a non-volatile memory device is provided. A method for forming a device isolation layer of a semiconductor device includes: forming trenches having a first predetermined depth by etching a substrate; forming a first insulation layer having a second predetermined depth inside the trenches; forming a liner oxide layer having a predetermined thickness on internal walls of the trenches with the first insulation layer formed therein; and forming a second insulation layer for forming a device isolation layer over the substrate with the liner oxide layer formed therein, wherein the second insulation layer has a lower etch rate than that of the first insulation layer. | 07-01-2010 |
20100240194 | Method of fabricating semiconductor device - A method of fabricating a semiconductor device, the method including sequentially forming a pad oxide layer and a nitride layer on a substrate; etching the nitride layer, the pad oxide layer, and the substrate to form a trench; forming a sidewall oxide layer on a sidewall and a bottom of the trench; forming a oxide layer liner including nitrogen on the sidewall oxide layer; and forming a gap fill layer on the oxide layer liner | 09-23-2010 |
20100273309 | METHOD FOR FORMING A SELF ALIGNED ISOLATION TRENCH - The present invention relates to methods for forming microelectronic structures in a semiconductor substrate. The method includes selectively removing dielectric material to expose a portion of an oxide overlying a semiconductor substrate. Insulating material may be formed substantially conformably over the oxide and remaining portions of the dielectric material. Spacers may be formed from the insulating material. An isolation trench etch follows the spacer etch. An optional thermal oxidation of the surfaces in the isolation trench may be performed, which may optionally be followed by doping of the bottom of the isolation trench to further isolate neighboring active regions on either side of the isolation trench. A conformal material may be formed substantially conformably over the spacer, over the remaining portions of the dielectric material, and substantially filling the isolation trench. Planarization of the conformal material may follow. | 10-28-2010 |
20110136319 | Methods Of Forming Isolation Structures, And Methods Of Forming Nonvolatile Memory - Some embodiments include methods of forming isolation structures. A trench may be formed to extend into a semiconductor material. Polysilazane may be formed within the trench, and then exposed to steam. A maximum temperature of the polysilazane during the steam exposure may be less than or equal to about 500° C. The steam exposure may convert all of the polysilazane to silicon oxide. The silicon oxide may be annealed under an inert atmosphere. A maximum temperature of the silicon oxide during the annealing may be from about 700° C. to about 1000° C. In some embodiments, the isolation structures are utilized to isolate nonvolatile memory components from one another. | 06-09-2011 |
20120034757 | METHODS OF FABRICATING SEMICONDUCTOR DEVICES HAVING VARIOUS ISOLATION REGIONS - A method of fabricating a semiconductor device includes forming a first trench and a second trench in a semiconductor substrate, forming a first insulator to completely fill the first trench, the first insulator covering a bottom surface and lower sidewalls of the second trench and exposing upper sidewalls of the second trench, and forming a second insulator on the first insulator in the second trench. | 02-09-2012 |
20120094468 | TWO SILICON-CONTAINING PRECURSORS FOR GAPFILL ENHANCING DIELECTRIC LINER - Aspects of the disclosure pertain to methods of depositing silicon oxide layers on substrates. In embodiments, silicon oxide layers are deposited by flowing a silicon-containing precursor having a Si—O bond, an oxygen-containing precursor and a second silicon-containing precursor, having both a Si—C bond and a Si—N bond, into a semiconductor processing chamber to form a conformal liner layer. Upon completion of the liner layer, a gap fill layer is formed by flowing a silicon-containing precursor having a Si—O bond, an oxygen-containing precursor into the semiconductor processing chamber. The presence of the conformal liner layer improves the ability of the gap fill layer to grow more smoothly, fill trenches and produce a reduced quantity and/or size of voids within the silicon oxide filler material. | 04-19-2012 |
20120149172 | METHOD FOR FABRICATING TRENCH ISOLATION STRUCTURE - A method for fabricating a trench isolation structure is described. A trench is formed in a substrate. A liner layer is formed at least in the trench. A precursor layer is formed at least on the sidewalls of the trench. The precursor layer is converted to an insulating layer that has a larger volume than the precursor layer and fills up the trench. | 06-14-2012 |
20120252188 | PLASMA PROCESSING METHOD AND DEVICE ISOLATION METHOD - A plasma processing method for use in device isolation by shallow trench isolation in which an insulating film is embedded in a trench formed in silicon and the insulating film is planarized to form a device isolation film, the method includes a plasma nitriding the silicon of an inner wall surface of the trench by using a plasma before embedding the insulating film in the trench. The plasma nitriding is performed by using a plasma of a processing gas containing a nitrogen-containing gas under conditions in which a processing pressure ranges from 1.3 Pa to 187 Pa and a ratio of a volumetric flow rate of the nitrogen-containing gas to a volumetric flow rate of the entire processing gas ranges from 1% to 80% such that a silicon nitride film is formed on the inner wall surface of the trench to have a thickness of 1 to 10 nm. | 10-04-2012 |
20130102125 | METHOD FOR CONTROLLING STRUCTURE HEIGHT - Methods for controlling the height of semiconductor structures are disclosed. Amorphous carbon is used as a stopping layer for controlling height variability. In one embodiment, the height of replacement metal gates for transistors is controlled. In another embodiment, the step height of a shallow trench isolation region is controlled. | 04-25-2013 |
20130288452 | CORNER TRANSISTOR SUPPRESSION - The threshold voltage of parasitic transistors formed at corners of shallow trench isolation regions is increased and mobility decreased by employing a high-K dielectric material. Embodiments include STI regions comprising a liner of a high-K dielectric material extending proximate trench corners. Embodiments also include STI regions having a recess formed in the trench, wherein the recess contains a high-K dielectric material, in the form of a layer or spacer, extending proximate trench corners. | 10-31-2013 |
20140017875 | NON-VOLATILE SEMICONDUCTOR MEMORY DEVICE AND PROCESS OF MANUFACTURING THE SAME - In device isolation trenches, a first device-isolation insulator film is formed to have recesses thereon and a second device-isolation insulator film is formed in the recesses. The uppermost portions at both ends of the first device-isolation insulator film are located higher than the uppermost portions at both ends of the second device-isolation insulator film. | 01-16-2014 |
20140030869 | SELF-ALIGNED SEMICONDUCTOR TRENCH STRUCTURES - Methods for forming a semiconductor device include forming self-aligned trenches, in which a first set of trenches is used to align a second set of trenches. Methods taught herein can be used as a pitch doubling technique, and may therefore enhance device integration. Further, employing a very thin CMP stop layer, and recessing surrounding materials by about an equal amount to the thickness of the CMP stop layer, provides improved planarity at the surface of the device. | 01-30-2014 |
20140073111 | Method of Forming Isolation Structure - The present invention provides a method of forming an isolation structure. A substrate is provided, and a trench is formed in the substrate. Next, a semiconductor layer is formed on a surface of the trench. A nitridation is carried out to form a nitridation layer in the semiconductor layer. Lastly, an insulation layer is filled into the trench. | 03-13-2014 |
20140099775 | METHOD FOR FABRICATING SEMICONDUCTOR DEVICE WITH MINI SONOS CELL - A method for fabricating a semiconductor device with mini-SONOS cell is disclosed. The method includes: providing a semiconductor substrate having a first MOS region and a second MOS region; forming a first trench in the semiconductor substrate between the first MOS region and the second MOS region; depositing a oxide liner and a nitride liner in the first trench; forming a STI in the first trench; removing a portion of the nitride liner for forming a second trench between the first MOS region of the semiconductor substrate and the STI and a third trench between the STI and the second MOS region of the semiconductor substrate; and forming a first conductive type nitride layer in the second trench. | 04-10-2014 |
20140127879 | Semiconductor Device and Method of Manufacture - A system and method for forming an isolation trench is provided. An embodiment comprises forming a trench and then lining the trench with a dielectric liner. Prior to etching the dielectric liner, an outgassing process is utilized to remove any residual precursor material that may be left over from the deposition of the dielectric liner. After the outgas sing process, the dielectric liner may be etched, and the trench may be filled with a dielectric material. | 05-08-2014 |
20140134827 | CONFORMAL FILM DEPOSITION FOR GAPFILL - A method and apparatus for conformally depositing a dielectric oxide in high aspect ratio gaps in a substrate is disclosed. A substrate is provided with one or more gaps into a reaction chamber where each gap has a depth to width aspect ratio of greater than about 5:1. A first dielectric oxide layer is deposited in the one or more gaps by CFD. A portion of the first dielectric oxide layer is etched using a plasma etch, where etching the portion of the first dielectric oxide layer occurs at a faster rate near a top surface than near a bottom surface of each gap so that the first dielectric oxide layer has a tapered profile from the top surface to the bottom surface of each gap. A second dielectric oxide layer is deposited in the one or more gaps over the first dielectric oxide layer via CFD. | 05-15-2014 |
20150294904 | METHOD FOR FABRICATING MICROELECTRONIC DEVICES WITH ISOLATION TRENCHES PARTIALLY FORMED UNDER ACTIVE REGIONS - A method of producing a microelectronic device in a substrate including a first semiconductor layer, a first dielectric layer, and a second semiconductor layer, including: etching a trench through the first semiconductor layer, the first dielectric layer, and a part of the second semiconductor layer, defining one active region, and such that, at the level of the second semiconductor layer, a part of the trench extends under a part of the active region; deposition of one second dielectric layer in the trench; etching the second dielectric layer such that remaining portions of the second dielectric layer forms portions of dielectric material extending under a part of the active region; deposition of a third dielectric layer in the trench such that the trench is filled with the dielectric materials of the second and third dielectric layers and forms an isolation trench. | 10-15-2015 |
20150348829 | METHOD FOR FORMING ISOLATION MEMBER IN TRENCH OF SEMICONDUCTOR SUBSTRATE - A method for forming an isolation member in a trench of a substrate may include the following steps: performing a first deposition process to form a first isolation material set, which is at least partially positioned in the trench; partially removing the first isolation material set, such that a remaining portion of the first isolation material set remains in the trench; after the first isolation material set has been partially removed, performing a fluorine-reduction process on at least the remaining portion of the first isolation material set; after the fluorine-reduction process, performing a second deposition process to form a second isolation material set, which is at least partially positioned in the trench, wherein the second isolation material set includes the remaining portion of the first isolation material set; and processing the second isolation material set for forming the isolation member. | 12-03-2015 |