Patent application number | Description | Published |
20080290388 | Semiconductor contructions - The invention includes a method in which a semiconductor substrate is provided to have a memory array region, and a peripheral region outward of the memory array region. Paired transistors are formed within the memory array region, with such paired transistors sharing a source/drain region corresponding to a bitline contact location, and having other source/drain regions corresponding to capacitor contact locations. A peripheral transistor gate is formed over the peripheral region. Electrically insulative material is formed over the peripheral transistor gate, and also over the bitline contact location. The insulative material is patterned to form sidewall spacers along sidewalls of the peripheral transistor gate, and to form a protective block over the bitline contact location. Subsequently, capacitors are formed which extend over the protective block, and which electrically connect with the capacitor contact locations. The invention also includes semiconductor constructions. | 11-27-2008 |
20080299753 | Peripheral Gate Stacks and Recessed Array Gates - Methods are provided for simultaneously processing transistors in two different regions of an integrated circuit. Planar transistors are provided in a logic region while recessed access devices (RADs) are provided in an array region for a memory device. During gate stack patterning in the periphery, word lines are recessed within the trenches for the array RADs. Side wall spacer formation in the periphery simultaneously provides an insulating cap layer burying the word lines within the trenches of the array. | 12-04-2008 |
20090239366 | Method Of Forming A Transistor Gate Of A Recessed Access Device, Method Of Forming A Recessed Transistor Gate And A Non-Recessed Transistor Gate, And Method Of Fabricating An Integrated Circuit - Methods and structures are provided for full silicidation of recessed silicon. Silicon is provided within a trench. A mixture of metals is provided over the silicon in which one of the metals diffuses more readily in silicon than silicon does in the metal, and another of the metals diffuses less readily in silicon than silicon does in the metal. An exemplary mixture includes 80% nickel and 20% cobalt. The silicon within the trench is allowed to fully silicide without void formation, despite a relatively high aspect ratio for the trench. Among other devices, recessed access devices (RADs) can be formed by the method for memory arrays. | 09-24-2009 |
20100148249 | Method Of Manufacturing A Memory Device - A memory device comprises an active area comprising a source and at least two drains defining a first axis. At least two substantially parallel word lines are defined by a first pitch, with one word line located between each drain and the source. Digit lines are defined by a second pitch, one of the digit lines being coupled to the source and forming a second axis. The active areas of the memory array are tilted at 45° to the grid defined by the word lines and digit lines. The word line pitch is about 1.5F, while the digit line pitch is about 3F. | 06-17-2010 |
20100273303 | Memory Arrays and Methods of Fabricating Memory Arrays - A memory array includes a plurality of memory cells formed on a semiconductor substrate. Individual of the memory cells include first and second field effect transistors respectively comprising a gate, a channel region, and a pair of source/drain regions. The gates of the first and second field effect transistors are hard wired together. A conductive data line is hard wired to two of the source/drain regions. A charge storage device is hard wired to at least one of the source/drain regions other than the two. Other aspects and implementations are contemplated, including methods of fabricating memory arrays. | 10-28-2010 |
20110081755 | Methods Of Fabricating An Access Transistor Having A Polysilicon-Comprising Plug On Individual Of Opposing Sides Of Gate Material - Fabrication methods for gate transistors in integrated circuit devices enable the formation of recessed access device structures or FinFET structures having P-type workfunctions. The fabrication methods also provide for the formation of access transistor gates of an access device following formation of the periphery transistor gates. Access devices and systems including same are also disclosed. | 04-07-2011 |
20110092062 | Transistor Gate Forming Methods and Transistor Structures - A transistor gate forming method includes forming a metal layer within a line opening and forming a fill layer within the opening over the metal layer. The fill layer is substantially selectively etchable with respect to the metal layer. A transistor structure includes a line opening, a dielectric layer within the opening, a metal layer over the dielectric layer within the opening, and a fill layer over the metal layer within the opening. The metal layer/fill layer combination exhibits less intrinsic less than would otherwise exist if the fill layer were replaced by an increased thickness of the metal layer. The inventions apply at least to 3-D transistor structures. | 04-21-2011 |
20110169086 | Methods of Forming Field Effect Transistors, Pluralities of Field Effect Transistors, and DRAM Circuitry Comprising a Plurality of Individual Memory Cells - A method of forming a field effect transistor includes forming trench isolation material within a semiconductor substrate and on opposing sides of a semiconductor material channel region along a length of the channel region. The trench isolation material is formed to comprise opposing insulative projections extending toward one another partially under the channel region along the channel length and with semiconductor material being received over the projections. The trench isolation material is etched to expose opposing sides of the semiconductor material along the channel length. The exposed opposing sides of the semiconductor material are etched along the channel length to form a channel fin projecting upwardly relative to the projections. A gate is formed over a top and opposing sides of the fin along the channel length. Other methods and structures are disclosed. | 07-14-2011 |
20110183507 | Peripheral Gate Stacks and Recessed Array Gates - Methods are provided for simultaneously processing transistors in two different regions of an integrated circuit. Planar transistors are provided in a logic region while recessed access devices (RADs) are provided in an array region for a memory device. During gate stack patterning in the periphery, word lines are recessed within the trenches for the array RADs. Side wall spacer formation in the periphery simultaneously provides an insulating cap layer burying the word lines within the trenches of the array. | 07-28-2011 |
20110227071 | Semiconductor Constructions, Semiconductor Processing Methods, And Methods Of Forming Isolation Structures - Some embodiments include methods of forming isolation structures. A semiconductor base may be provided to have a crystalline semiconductor material projection between a pair of openings. SOD material (such as, for example, polysilazane) may be flowed within said openings to fill the openings. After the openings are filled with the SOD material, one or more dopant species may be implanted into the projection to amorphize the crystalline semiconductor material within an upper portion of said projection. The SOD material may then be annealed at a temperature of at least about 400° C. to form isolation structures. Some embodiments include semiconductor constructions that include a semiconductor material base having a projection between a pair of openings. The projection may have an upper region over a lower region, with the upper region being at least 75% amorphous, and with the lower region being entirely crystalline. | 09-22-2011 |
20120256244 | Methods of Forming Field Effect Transistors, Pluralities of Field Effect Transistors, and DRAM Circuitry Comprising a Plurality of Individual Memory Cells - A method of forming a field effect transistor includes forming trench isolation material within a semiconductor substrate and on opposing sides of a semiconductor material channel region along a length of the channel region. The trench isolation material is formed to comprise opposing insulative projections extending toward one another partially under the channel region along the channel length and with semiconductor material being received over the projections. The trench isolation material is etched to expose opposing sides of the semiconductor material along the channel length. The exposed opposing sides of the semiconductor material are etched along the channel length to form a channel fin projecting upwardly relative to the projections. A gate is formed over a top and opposing sides of the fin along the channel length. Other methods and structures are disclosed. | 10-11-2012 |
20120329231 | Semiconductor Processing Methods, And Methods Of Forming Isolation Structures - Some embodiments include methods of forming isolation structures. A semiconductor base may be provided to have a crystalline semiconductor material projection between a pair of openings. SOD material (such as, for example, polysilazane) may be flowed within said openings to fill the openings. After the openings are filled with the SOD material, one or more dopant species may be implanted into the projection to amorphize the crystalline semiconductor material within an upper portion of said projection. The SOD material may then be annealed at a temperature of at least about 400° C. to form isolation structures. Some embodiments include semiconductor constructions that include a semiconductor material base having a projection between a pair of openings. The projection may have an upper region over a lower region, with the upper region being at least 75% amorphous, and with the lower region being entirely crystalline. | 12-27-2012 |
20140167131 | THREE DIMENSIONAL MEMORY - A method to fabricate a three dimensional memory structure may include creating a stack of layers including a conductive source layer, a first insulating layer, a select gate source layer, and a second insulating layer, and an array stack. A hole through the stack of layers may then be created using the conductive source layer as a stop-etch layer. The source material may have an etch rate no faster than 33% as fast as an etch rate of the insulating material for the etch process used to create the hole. A pillar of semiconductor material may then fill the hole, so that the pillar of semiconductor material is in electrical contact with the conductive source layer. | 06-19-2014 |