Horng-Huei Tseng

Bio: Horng-Huei Tseng is an academic researcher. The author has contributed to research in topics: Layer (electronics) & Gate oxide. The author has an hindex of 24, co-authored 143 publications receiving 2115 citations.

Method of making increased surface area, storage node electrode, with narrow spaces between polysilicon columns

Abstract: A method of creating an STC structure, used for high density, DRAM designs, has been developed. The process consists of creating a storage node electrode, for the STC structure, consisting of an upper polysilicon shape, comprised of polysilicon columns, with a narrow space between polysilicon columns, and an underlying lower polysilicon shape, residing in a contact hole, and making contact to underlying transistor regions. The polysilicon columns, and the narrow space, between polysilicon columns are formed via creation of a narrow trench in a top portion of a polysilicon layer, followed by an anisotropic etch to create the exterior shape of the storage node electrode. A key feature of this invention is the use of a photoresist plug, in the trench, used to protect the lower portion of the storage node electrode during the exterior shape, patterning process. This storage node electrode configuration results in increased surface area, via use of polysilicon columns, as well as density improvements, resulting from the use of narrow spaces between polysilicon columns.

Method for making improved shallow trench isolation with dielectric studs for semiconductor integrated circuits

Abstract: A method is achieved for making improved shallow trench isolation (STI) regions surrounding and electrically isolating device areas on a substrate using dielectric studs, spin-on-glass (SOG), and an isotropic wet etchback The method consists of forming trenches in a silicon substrate using a pad oxide and silicon nitride mask A thermal oxide is grown in the silicon trenches and a CVD silicon oxide is deposited and chemical/mechanically polished back to the silicon nitride masking layer to form dielectric studs (or plugs) in the silicon trenches that extend above the silicon substrate surface The silicon nitride is removed in hot phosphoric acid, and a thin SOG is deposited to form disposable sidewall spacers on the raised studs The thin SOG and the pad oxide are wet etched in HF acid to the device areas while isotropically etching back the disposable SOG sidewall spacers and dielectric studs to form shallow trench isolation regions having a raised convex surface This eliminates dishing in the STI (concave STI) that results in undesirable variation in FET threshold voltage (Vth) The gradual convex profile also minimizes the polysilicon residue problem when anisotropically etching the gate electrodes over the device areas The use of SOG with wet etchback is more cost effective than the conventional CVD oxide deposition and plasma etchback process

Method of manufacturing a high coupling ratio stacked gate flash memory with an HSG-SI layer

Abstract: A stacked-gate flash memory cell includes a trench formed in a substrate and a tunneling oxide layer formed on the substrate. A first part of the floating gate is formed on the tunneling oxide layer. A protruding isolation filler is formed in the trench and protrudes over the upper surface of the first part of the floating gate, thereby forming a cavity between the two adjacent raised isolation structures. A second part of the floating gate is formed of HSG-Si over the surface of the cavity to have a U-shaped structure in cross sectional view. A dielectric layer is conformably formed on the surface of the second part of the floating gate and the isolation structures, and a control gate is formed on the dielectric layer.

Method of forming a MOSFET with a recessed-gate having a channel length beyond photolithography limit

Abstract: A method of forming a MOSFET having a recessed-gate with a channel length beyond the photolithography limit is disclosed in the present invention. First, a first dielectric layer and a second dielectric layer are formed on a semiconductor substrate. A first opening is next formed in the second dielectric layer. After forming first spacers on sidewalls of the first opening and removing the first dielectric layer within the first opening, a trench is formed in the semiconductor substrate by an anisotropic etching process. After forming second spacers with dopant source material on sidewalls of the trench, a gate dielectric layer is formed within the trench. A conductive layer is formed to refill said trench. After removing the portion of the conductive layer outside the trench, a gate plug is then formed. After removing the second dielectric layer, source and drain regions and source/drain extensions are formed

Method of forming shallow trench isolation

Abstract: A method of fabricating a shallow trench isolation. A pad oxide and a dielectric layer are formed on a substrate. A trench is formed in the substrate penetrating through the pad oxide layer and the dielectric layer. The dielectric layer around the edge of the trench is removed to expose the substrate. The trench is filled to form a T-shaped insulation plug.

Semiconductor device, and manufacturing method thereof

Abstract: An object is to provide a semiconductor device of which a manufacturing process is not complicated and by which cost can be suppressed, by forming a thin film transistor using an oxide semiconductor film typified by zinc oxide, and a manufacturing method thereof. For the semiconductor device, a gate electrode is formed over a substrate; a gate insulating film is formed covering the gate electrode; an oxide semiconductor film is formed over the gate insulating film; and a first conductive film and a second conductive film are formed over the oxide semiconductor film. The oxide semiconductor film has at least a crystallized region in a channel region.

Method for integrated circuit fabrication using pitch multiplication

Abstract: Different sized features in the array and in the periphery of an integrated circuit are patterned on a substrate in a single step. In particular, a mixed pattern, combining two separately formed patterns, is formed on a single mask layer and then transferred to the underlying substrate. The first of the separately formed patterns is formed by pitch multiplication and the second of the separately formed patterns is formed by conventional photolithography. The first of the separately formed patterns includes lines that are below the resolution of the photolithographic process used to form the second of the separately formed patterns. These lines are made by forming a pattern on photoresist and then etching that pattern into an amorphous carbon layer. Sidewall pacers having widths less than the widths of the un-etched parts of the amorphous carbon are formed on the sidewalls of the amorphous carbon. The amorphous carbon is then removed, leaving behind the sidewall spacers as a mask pattern. Thus, the spacers form a mask having feature sizes less than the resolution of the photolithography process used to form the pattern on the photoresist. A protective material is deposited around the spacers. The spacers are further protected using a hard mask and then photoresist is formed and patterned over the hard mask. The photoresist pattern is transferred through the hard mask to the protective material. The pattern made out by the spacers and the temporary material is then transferred to an underlying amorphous carbon hard mask layer. The pattern, having features of difference sizes, is then transferred to the underlying substrate.

Nonplanar transistors with metal gate electrodes

Abstract: A semiconductor device comprising a semiconductor body having a top surface and a first and second laterally opposite sidewalls as formed on an insulating substrate is claimed. A gate dielectric is formed on the top surface of the semiconductor body and on the first and second laterally opposite sidewalls of the semiconductor body. A gate electrode is then formed on the gate dielectric on the top surface of the semiconductor body and adjacent to the gate dielectric on the first and second laterally opposite sidewalls of the semiconductor body. The gate electrode comprises a metal film formed directly adjacent to the gate dielectric layer. A pair of source and drain regions are then formed in the semiconductor body on opposite sides of the gate electrode.

Single spacer process for multiplying pitch by a factor greater than two and related intermediate IC structures

Abstract: Single spacer processes for multiplying pitch by a factor greater than two are provided. In one embodiment, n, where n≧2, tiers of stacked mandrels are formed over a substrate, each of the n tiers comprising a plurality of mandrels substantially parallel to one another. Mandrels at tier n are over and parallel to mandrels at tier n−1, and the distance between adjoining mandrels at tier n is greater than the distance between adjoining mandrels at tier n−1. Spacers are simultaneously formed on sidewalls of the mandrels. Exposed portions of the mandrels are etched away and a pattern of lines defined by the spacers is transferred to the substrate.

Pitch reduced patterns relative to photolithography features

Abstract: Differently-sized features of an integrated circuit are formed by etching a substrate using a mask which is formed by combining two separately formed patterns. Pitch multiplication is used to form the relatively small features of the first pattern and conventional photolithography used to form the relatively large features of the second pattern. Pitch multiplication is accomplished by patterning a photoresist and then etching that pattern into an amorphous carbon layer. Sidewall spacers are then formed on the sidewalls of the amorphous carbon. The amorphous carbon is removed, leaving behind the sidewall spacers, which define the first mask pattern. A bottom anti-reflective coating (BARC) is then deposited around the spacers to form a planar surface and a photoresist layer is formed over the BARC. The photoresist is next patterned by conventional photolithography to form the second pattern, which is then is transferred to the BARC. The combined pattern made out by the first pattern and the second pattern is transferred to an underlying amorphous silicon layer and the pattern is subjected to a carbon strip to remove BARC and photoresist material. The combined pattern is then transferred to the silicon oxide layer and then to an amorphous carbon mask layer. The combined mask pattern, having features of difference sizes, is then etched into the underlying substrate through the amorphous carbon hard mask layer.