Abstract: A method includes: forming a structure on a frontside of a substrate, the structure including a first and a second source/drain body located in a first and a second source/drain region, respectively, and a channel body including a channel layer extending between the first and second source/drain bodies; forming a trench beside the first source/drain region by etching the substrate such that a lower portion of the trench undercuts the first source/drain region; forming a liner on the trench; forming an opening in the liner underneath the first source/drain region; and forming a dummy interconnect in the trench; where the method further includes exposing the dummy interconnect from a backside of the substrate; removing the dummy interconnect selectively to the liner; and forming a buried interconnect of a conductive material in the trench, where the buried interconnect is connected to the first source/drain body via the opening in the liner.

Abstract: An image sensor pixel including a photodiode includes a first dopant region disposed within a semiconductor layer and a second dopant region disposed above the first dopant region and within the semiconductor layer. The second dopant region contacts the first dopant region and the second dopant region is of an opposite majority charge carrier type as the first dopant region. A third dopant region is disposed above the first dopant region and within the semiconductor layer. The third dopant region is of a same majority charge carrier type as the second dopant region but has a greater concentration of free charge carriers than the second dopant region. A transfer gate is positioned to transfer photogenerated charge from the photodiode. The second dopant region extends closer to an edge of the transfer gate than the third dopant region.

Abstract: A transistor may be formed of different layers of silicon germanium, a lowest layer having a graded germanium concentration and upper layers having constant germanium concentrations such that the lowest layer is of the form Si1-xGex. The highest layer may be of the form Si1-yGey on the PMOS side. A source and drain may be formed of epitaxial silicon germanium of the form Si1-zGez on the PMOS side. In some embodiments, x is greater than y and z is greater than x in the PMOS device. Thus, a PMOS device may be formed with both uniaxial compressive stress in the channel direction and in-plane biaxial compressive stress. This combination of stress may result in higher mobility and increased device performance in some cases.

Abstract: A transistor may be formed of different layers of silicon germanium, a lowest layer having a graded germanium concentration and upper layers having constant germanium concentrations such that the lowest layer is of the form Si1-xGex. The highest layer may be of the form Si1-yGey on the PMOS side. A source and drain may be formed of epitaxial silicon germanium of the form Si1-zGez on the PMOS side. In some embodiments, x is greater than y and z is greater than x in the PMOS device. Thus, a PMOS device may be formed with both uniaxial compressive stress in the channel direction and in-plane biaxial compressive stress. This combination of stress may result in higher mobility and increased device performance in some cases.

Abstract: Methods of forming a microelectronic structure are described. Embodiments of those methods include providing a gate structure disposed on a substrate comprising at least one recess, wherein a channel region is in a <110> direction, and then forming a compressive layer in the at least one recess.

Abstract: A transistor may be formed of different layers of silicon germanium, a lowest layer having a graded germanium concentration and upper layers having constant germanium concentrations such that the lowest layer is of the form Si1-xGex. The highest layer may be of the form Si1-yGey on the PMOS side. A source and drain may be formed of epitaxial silicon germanium of the form Si1-zGez on the PMOS side. In some embodiments, x is greater than y and z is greater than x in the PMOS device. Thus, a PMOS device may be formed with both uniaxial compressive stress in the channel direction and in-plane biaxial compressive stress. This combination of stress may result in higher mobility and increased device performance in some cases.