Abstract: The present invention provides a method for fabricating sub-0.05 &mgr;m double-gated MOSFET devices utilizing a damascene-gate process. The damascene-gate process provides sub-0.05 &mgr;m double-gated MOSFET devices which include a frontside poly gate electrode and a backside implant region. The two gates are separated by two gate dielectrics that include a thin (on the order of about 200 Å or less) Si layer which is sandwiched between the gate dielectrics. The Si layer serves as the channel region of the device. Short-channel effects are greatly suppressed in the present double-gate MOSFET device because the two gates terminate the drain filed lines, preventing the drain potential from being felt at the source end of the channel.

Abstract: A sub-0.1 &mgr;m MOSFET device having minimum poly depletion, salicided source and drain junctions and very low sheet resistance poly-gates is provided utilizing a damascene-gate process wherein the source and drain implantation activation annealing and silicidation occurs in the presence of a dummy gate region which is thereafter removed and replaced with a polysilicon gate region.

Abstract: The present invention provides a method for fabricating sub-0.05 &mgr;m double-gated MOSFET devices utilizing a damascene-gate process. The damascene-gate process provides sub-0.05 &mgr;m double-gated MOSFET devices which include a frontside poly gate electrode and a backside implant region. The two gates are separated by two gate dielectrics that include a thin (on the order of about 200 Å or less) Si layer which is sandwiched between the gate dielectrics. The Si layer serves as the channel region of the device. Short-channel effects are greatly suppressed in the present double-gate MOSFET device because the two gates terminate the drain filed lines, preventing the drain potential from being felt at the source end of the channel.

Abstract: Methods of fabricating metal oxide semiconductor field effect transistor (MOSFET) devices having a high dielectric constant (k greater than 7) gate insulator, low overlap capacitance (0.35 fF/&mgr;m or below) and a channel length (sub-lithographic, e.g., 0.1 &mgr;m or less) that is shorter than the lithography-defined gate lengths are provided. The methods include a damascene processing step and a chemical oxide removal (COR) step. The COR step produces a large taper on a pad oxide layer which, when combined with a high-k gate insulator, results in low overlap capacitance, sort channel lengths and better device performance as compared to MOSFET devices that are formed using conventional Complementary Metal Oxide Semiconductor (CMOS) technologies.

Abstract: Methods of fabricating metal oxide semiconductor field effect transistor (MOSFET) devices having a high dielectric constant (k greater than 7) gate insulator, low overlap capacitance (0.35 fF/&mgr;m or below) and a channel length (sub-lithographic, e.g., 0.1 &mgr;m or less) that is shorter than the lithography-defined gate lengths are provided. The methods include a damascene processing step and a chemical oxide removal (COR) step. The COR step produces a large taper on a pad oxide layer which, when combined with a high-k gate insulator, results in low overlap capacitance, sort channel lengths and better device performance as compared to MOSFET devices that are formed using conventional Complementary Metal Oxide Semiconductor (CMOS) technologies.

Abstract: New arrangement of a vertical field effect transistor and a capacitor together forming a memory cell which in turn may be the basic building block of a memory chip, such as a very high density DRAM. The capacitor's first electrode is connected to the drain of the transistor. The transistor's source is connected to the sources of other transistors, the gate is connected to a word line, and the second electrode of said capacitor is connected to a bit line.

Abstract: A method of forming a shallow outdiffused buried bitline in a vertical semiconductor memory device is disclosed which utilizes annealing and oxidation to drive-in and pile-up the dopant atom into an outdiffused region. The anneal/oxidation which is carried out at two different temperature ranges allows for fabricating buried bitlines having the lowest resistance as possible at a maximum dopant concentration, yet being formed near the surface interface of the vertical pillars. Semiconductor memory devices containing the outdiffused buried bitline regions are also disclosed.

Abstract: Methods of fabricating metal oxide semiconductor field effect transistor (MOSFET) devices having a high dielectric constant (k greater than 7) gate insulator, low overlap capacitance (0.35 fF/&mgr;m or below) and a channel length (sub-lithographic, e.g., 0.1 &mgr;m or less) that is shorter than the lithography-defined gate lengths are provided. The methods include a damascene processing step and a chemical oxide removal (COR) step. The COR step produces a large taper on a pad oxide layer which, when combined with a high-k gate insulator, results in low overlap capacitance, sort channel lengths and better device performance as compared to MOSFET devices that are formed using conventional Complementary Metal Oxide Semiconductor (CMOS) technologies.

Abstract: Techniques to fabricate sub−0.05 &mgr;m MOSFET devices with Super-Halo doping profile which provide excellent short-channel characteristics are provided. The techniques utilize a damascene-gate process to obtain MOSFET structures with oxide thickness above the source/drain region independent of the gate-oxide thickness and a disposable-spacer technique for the formation of the Super-Halo doping profile.

Abstract: A method of forming a shallow outdiffused buried bitline in a vertical semiconductor memory device is disclosed which utilizes annealing and oxidation to drive-in and pile-up the dopant atom into an outdiffused region. The anneal/oxidation which is carried out at two different temperature ranges allows for fabricating buried bitlines having the lowest resistance as possible at a maximum dopant concentration, yet being formed near the surface interface of the vertical pillars. Semiconductor memory devices containing the outdiffused buried bitline regions are also disclosed.

Abstract: The present invention relates to a recessed channel/gate MOSFET structure which comprises a semiconductor wafer having a plurality of shallow trench isolation regions embedded therein, wherein between each adjacent shallow trench isolation region is a field effect transistor region which comprises a source and drain region which are spaced apart by a gate region, said gate region comprising a poly gate region which is positioned between oxide spacers, said poly gate region having a metal contact region on its top surface and a gate oxide region on its bottom surface embedded in said semiconductor wafer and wherein said source and drain regions have an extension which wraps around said oxide spacers and provides a connection with a channel region which is formed below said gate oxide region.

Abstract: A densely packed array of vertical semiconductor devices, having pillars with stack capacitors thereon, and methods of making thereof are disclosed. The pillars act as transistor channels, and are formed between upper and lower doped regions. The lower doped regions are self-aligned and are located below the pillars. The array has columns of bitlines and rows of wordlines. The lower doped regions of adjacent bitlines may be isolated from each other without increasing the cell size and allowing a minimum area of approximately 4 F.sup.2 to be maintained. The array is suitable for Gbit DRAM applications because the stack capacitors do not increase array area. The array may have an open bitline, a folded, or an open/folded architecture with dual wordlines, where two transistors are formed on top of each other in each trench. The lower regions may be initially implanted. Alternatively, the lower regions may be diffused below the pillars after forming thereof.

Abstract: The present invention provides a process of fabricating high aspect ratio holes (H/L is 2 or greater) in a semiconductor structure wherein a masked gate-like reactive ion etch process is employed. The high aspect ratio holes have perfectly vertical sidewalls thus they are particularly useful in fabricating gate electrodes of sub-0.05 .mu.m MOSFETs using a damascene process.

Abstract: A densely packed array of vertical semiconductor devices having pillars and methods of making thereof are disclosed. The array has columns of bitlines and rows of wordlines. The gates of the transistors act as the wordlines, while the source or drain regions acts as the bitlines. The array also has vertical pillars, each having a channel formed between source and drain regions. Two transistors are formed per pillar. This is achieved by forming two gates per pillar formed on opposite pillar sidewalls which are along the bitline direction. This forms two wordlines or gates per pillar arranged in the wordline direction. The source regions are self-aligned and located below the pillars. The source regions of adjacent bit lines are isolated from each other without increasing the cell size.

Abstract: A densely packed array of vertical semiconductor devices, having pillars and deep trench capacitors, and methods of making thereof are disclosed. The pillars act as transistor channels, and are formed between upper and lower doped regions. The lower doped regions are self-aligned and are located below the pillars. The array has columns of bitlines and rows of wordlines. The lower doped regions of all the cells are isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained. The array is suitable for Gbit DRAM applications because the deep trench capacitors do not increase array area. The array may have an open bitline, a folded, or an open/folded architecture with dual wordlines, where two transistors are formed on top of each other in each trench. The lower regions may be initially implanted. Alternatively, the lower regions may be diffused below the pillars after forming thereof.

Abstract: A densely packed array of vertical semiconductor devices and methods of making thereof are disclosed. The array has columns of bitlines and rows of wordlines. The gates of the transistors act as the wordlines, while the source or drain regions acts as the bitlines. The array also has vertical pillars, acting as a channel, formed between source and drain regions. The source regions are self-aligned and located below the pillars. The source regions of adjacent bitlines are isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained. The isolated sources allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. The source may be initially implanted. Alternatively, the source may be diffused below the pillars after forming thereof.

Abstract: A densely packed array of vertical semiconductor devices, having pillars and deep trench capacitors, and methods of making thereof are disclosed. The pillars act as transistor channels, and are formed between upper and lower doped regions. The lower doped regions are self-aligned and are located below the pillars. The array has columns of bitlines and rows of wordlines. The lower doped regions of all the cells are isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained The array is suitable for Gbit DRAM applications because the deep trench capacitors do not increase array area. The array may have an open bitline, a folded, or an open/folded architecture with dual wordlines, where two transistors are formed on top of each other in each trench. The lower regions may be initially implanted. Alternatively, the lower regions may be diffused below the pillars after forming thereof.

Abstract: A densely packed array of vertical semiconductor devices, having pillars with stack capacitors thereon, and methods of making thereof are disclosed. The pillars act as transistor channels, and are formed between upper and lower doped regions. The lower doped regions are self-aligned and are located below the pillars. The array has columns of bitlines and rows of wordlines. The lower doped regions of adjacent bitlines may be isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained. The array is suitable for Gbit DRAM applications because the stack capacitors do not increase array area. The array may have an open bitline, a folded, or an open/folded architecture with dual wordlines, where two transistors are formed on top of each other in each trench. The lower regions may be initially implanted. Alternatively, the lower regions may be diffused below the pillars after forming thereof.

Abstract: A densely packed array of vertical semiconductor devices and methods of making thereof are disclosed. The array has columns of bitlines and rows of wordlines. The gates of the transistors act as the wordlines, while the source or drain regions acts as the bitlines. The array also has vertical pillars, acting as a channel, formed between source and drain regions. The source regions are self-aligned and located below the pillars. The source regions of adjacent bitlines are isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained. The isolated sources allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. The source may be initially implanted. Alternatively, the source may be diffused below the pillars after forming thereof.

Abstract: Method for creating a doped polysilicon layer of accurate shape on a sidewall of a semiconductor structure. According to the present method, a doped polysilicon film covering at least part of said semiconductor structure and of said sidewall is formed. This polysilicon film then undergoes a reactive ion etching (RIE) process providing for a high etch rate of said polysilicon film to approximately define the shape of the polysilicon layer on said sidewall. Then, said polysilicon film undergoes a second reactive ion etching process. This second reactive ion etching process is a low polysilicon etch rate process such that non-uniformities of the surface of said polysilicon film are removed by sputtering.