Abstract: Nanocrystal structures formed using atomic layer deposition (ALD) processes are useful in the formation of integrated circuits such as memory devices. Rather than continuing the ALD process until a continuous layer is formed, the ALD process is halted prematurely to leave a discontinuous formation of nanocrystals which are then capped by a different material, thus forming a layer with a discontinuous portion and a bulk portion. Such nanocrystals can serve as charge-storage sites within the bulk portion, and the resulting structure can serve as a floating gate of a floating-gate memory cell. A floating gate may contain one or more layers of such nanocrystal structures.

Abstract: Nanocrystal structures formed using atomic layer deposition (ALD) processes are useful in the formation of integrated circuits such as memory devices. Rather than continuing the ALD process until a continuous layer is formed, the ALD process is halted prematurely to leave a discontinuous formation of nanocrystals which are then capped by a different material, thus forming a layer with a discontinuous portion and a bulk portion. Such nanocrystals can serve as charge-storage sites within the bulk portion, and the resulting structure can serve as a floating gate of a floating-gate memory cell. A floating gate may contain one or more layers of such nanocrystal structures.

Abstract: Embodiments of the present invention describe a semiconductor device having an buffer structure and methods of fabricating the buffer structure. The buffer structure is formed between a substrate and a quantum well layer to prevent defects in the substrate and quantum well layer due to lattice mismatch. The buffer structure comprises a first buffer layer formed on the substrate, a plurality of blocking members formed on the first buffer layer, and second buffer formed on the plurality of blocking members. The plurality of blocking members prevent the second buffer layer from being deposited directly onto the entire first buffer layer so as to minimize lattice mismatch and prevent defects in the first and second buffer layers.

Abstract: Nanocrystal structures formed using atomic layer deposition (ALD) processes are useful in the formation of integrated circuits such as memory devices. Rather than continuing the ALD process until a continuous layer is formed, the ALD process is halted prematurely to leave a discontinuous formation of nanocrystals which are then capped by a different material, thus forming a layer with a discontinuous portion and a bulk portion. Such nanocrystals can serve as charge-storage sites within the bulk portion, and the resulting structure can serve as a floating gate of a floating-gate memory cell. A floating gate may contain one or more layers of such nanocrystal structures.

Abstract: A tunnel field-effect transistor is provided, which includes a fin-shaped, source-drain circuit structure with a source region and a drain region. The circuit structure is angled in cross-sectional elevation, and includes a first portion and a second portion. The first portion extends away from the second portion, and the source region is disposed in the first or second portion, and the drain region is disposed in the other of the first or second portion. The transistor further includes a gate electrode for gating the circuit structure and a self-aligned tunneling region. The tunneling region is self-aligned to at least a portion of the circuit structure and extends between the gate electrode and the first or second portion of the fin-shaped circuit structure, and the self-aligned tunneling region is at least partially disposed in parallel, spaced opposing relation to a control surface of the gate electrode.

Abstract: Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well.

Abstract: Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well.

Abstract: Several embodiments of a tunneling transistor are disclosed. In one embodiment, a tunneling transistor includes a semiconductor substrate, a source region formed in the semiconductor substrate, a drain region formed in the semiconductor substrate, a gate stack including a metallic gate electrode and a gate dielectric, and a tunneling junction that is substantially parallel to an interface between the metallic gate electrode and the gate dielectric. As a result of the tunneling junction that is substantially parallel with the interface between the metallic gate electrode and the gate dielectric, an on-current of the tunneling transistor is substantially improved as compared to that of a conventional tunneling transistor. In another embodiment, a tunneling transistor includes a heterostructure that reduces a turn-on voltage of the tunneling transistor.

Abstract: Methods of forming dual metal gates and the gates so formed are disclosed. A method may include forming a first metal (e.g., NMOS metal) layer on a gate dielectric layer and a second metal (e.g., PMOS metal) layer on the first metal layer, whereby the second metal layer alters a work function of the first metal layer (to form PMOS metal). The method may remove a portion of the second metal layer to expose the first metal layer in a first region; form a silicon layer on the exposed first metal layer in the first region and on the second metal layer in a second region; and form the dual metal gates in the first and second regions. Since the gate dielectric layer is continuously covered with the first metal, it is not exposed to the damage from the metal etch process.

Abstract: Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well.

Abstract: Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well.

Abstract: In one embodiment, the present invention includes an apparatus having a substrate, a buried oxide layer formed on the substrate, a silicon on insulator (SOI) core formed on the buried oxide layer, a compressive strained quantum well (QW) layer wrapped around the SOI core, and a tensile strained silicon layer wrapped around the QW layer. Other embodiments are described and claimed.

Abstract: In one embodiment, the present invention includes an apparatus having a substrate, a buried oxide layer formed on the substrate, a silicon on insulator (SOI) core formed on the buried oxide layer, a compressive strained quantum well (QW) layer wrapped around the SOI core, and a tensile strained silicon layer wrapped around the QW layer. Other embodiments are described and claimed.

Abstract: Methods of forming dual metal gates and the gates so formed are disclosed. A method may include forming a first metal (e.g., NMOS metal) layer on a gate dielectric layer and a second metal (e.g., PMOS metal) layer on the first metal layer, whereby the second metal layer alters a work function of the first metal layer (to form PMOS metal). The method may remove a portion of the second metal layer to expose the first metal layer in a first region; form a silicon layer on the exposed first metal layer in the first region and on the second metal layer in a second region; and form the dual metal gates in the first and second regions. Since the gate dielectric layer is continuously covered with the first metal, it is not exposed to the damage from the metal etch process.

Abstract: A semiconductor structure may include a semiconductor bulk region with a gate stack on the semiconductor bulk region. The source region and the drain region in the semiconductor bulk region may be located on opposing sides of a channel region below the gate stack. An interfacial layer coupled to the channel region may modify a workfunction of a metal-semiconductor contact. In a MOSFET, the metal-semiconductor contact may be between a metal contact and the source region and the drain region. In a Schottky barrier-MOSFET, the metal-semiconductor contact may be between a silicide region in the source region and/or the drain region and the channel region. The interfacial layer may use a dielectric-dipole mitigated scheme and may include a conducting layer and a dielectric layer. The dielectric layer may include lanthanum oxide or aluminum oxide used to tune the workfunction of the metal-semiconductor contact.

Abstract: Embodiments of the present invention describe a semiconductor device having an buffer structure and methods of fabricating the buffer structure. The buffer structure is formed between a substrate and a quantum well layer to prevent defects in the substrate and quantum well layer due to lattice mismatch. The buffer structure comprises a first buffer layer formed on the substrate, a plurality of blocking members formed on the first buffer layer, and second buffer formed on the plurality of blocking members. The plurality of blocking members prevent the second buffer layer from being deposited directly onto the entire first buffer layer so as to minimize lattice mismatch and prevent defects in the first and second buffer layers.

Abstract: In one embodiment, the present invention includes an apparatus having a substrate, a buried oxide layer formed on the substrate, a silicon on insulator (SOI) core formed on the buried oxide layer, a compressive strained quantum well (QW) layer wrapped around the SOI core, and a tensile strained silicon layer wrapped around the QW layer. Other embodiments are described and claimed.

Abstract: Conductivity improvements in III-V semiconductor devices are described. A first improvement includes a barrier layer that is not coextensively planar with a channel layer. A second improvement includes an anneal of a metal/Si, Ge or SiliconGermanium/III-V stack to form a metal-Silicon, metal-Germanium or metal-SiliconGermanium layer over a Si and/or Germanium doped III-V layer. Then, removing the metal layer and forming a source/drain electrode on the metal-Silicon, metal-Germanium or metal-SiliconGermanium layer. A third improvement includes forming a layer of a Group IV and/or Group VI element over a III-V channel layer, and, annealing to dope the III-V channel layer with Group IV and/or Group VI species. A fourth improvement includes a passivation and/or dipole layer formed over an access region of a III-V device.

Abstract: Devices comprising, and a method for fabricating, a remote doped high performance transistor having improved subthreshold characteristics are disclosed. In one embodiment a field-effect transistor includes a channel layer configured to convey between from a source portion and a drain portion of the transistor when the transistor is in an active state. Further, the field-effect transistor includes a barrier layer adjacent to the channel layer. The barrier layer comprises a delta doped layer configured to provide carriers to the channel layer of the transistor, while preferably substantially retaining dopants in said delta-doped layer.

Abstract: Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well.