Abstract: Methods and systems for forming a p-type doped silicon germanium layer. The p-type doped silicon germanium layer can include silicon, germanium, gallium, and, in at least some cases, indium.

Abstract: Methods and devices for low-temperature deposition of phosphorous-doped silicon layers. Disilane is used as a silicon precursor, and nitrogen or a noble gas is used as a carrier gas. Phosphine is a suitable phosphorous precursor.

Abstract: Methods for forming structures that include a layer comprising silicon germanium are disclosed. Exemplary embodiments of the disclosure provide improved methods of forming a transition layer on the layer comprising silicon germanium that can mitigate any formation of an interface layer between the layer comprising silicon germanium and a subsequently formed layer comprising silicon.

Abstract: Methods and systems for depositing material, such as doped semiconductor material, are disclosed. An exemplary method includes providing a substrate, forming a first doped semiconductor layer overlying the substrate, and forming a second doped semiconductor layer overlying the first doped semiconductor layer, wherein the first doped semiconductor layer comprises a first dopant and a second dopant, and wherein the second doped semiconductor layer comprises the first dopant. Structures and devices formed using the methods and systems for performing the methods are also disclosed.

Abstract: A method for selectively forming an n-type doped material on a surface of a substrate is disclosed. A system for performing the method and structures and devices formed using the method are also disclosed.

Abstract: Methods and systems for selectively depositing material, such as doped semiconductor material, are disclosed. An exemplary method includes providing a substrate, comprising a first area comprising a first material and a second area comprising a second material, selectively depositing a first doped semiconductor layer overlying the first material relative to the second material and selectively depositing a second doped semiconductor layer overlying the first doped semiconductor layer relative to the second material.

Abstract: Methods and systems for depositing material, such as doped semiconductor material, are disclosed. An exemplary method includes providing a substrate, forming a first doped semiconductor layer overlying the substrate, and forming a second doped semiconductor layer overlying the first doped semiconductor layer, wherein the first doped semiconductor layer comprises a first dopant and a second dopant, and wherein the second doped semiconductor layer comprises the first dopant. Structures and devices formed using the methods and systems for performing the methods are also disclosed.

Abstract: Methods and systems for selectively depositing a p-type doped silicon germanium layer and structures and devices including a p-type doped silicon germanium layer are disclosed. An exemplary method includes providing a substrate, comprising a surface comprising a first area comprising a first material and a second area comprising a second material, within a reaction chamber; depositing a p-type doped silicon germanium layer overlying the surface, the p-type doped silicon germanium layer comprising gallium; and depositing a cap layer overlying the p-type doped silicon germanium layer. The method can further include an etch step to remove the cap layer and the p-type doped silicon germanium layer overlying the second material.

Abstract: Methods and systems for selectively depositing a p-type doped silicon germanium layer and structures and devices including a p-type doped silicon germanium layer are disclosed. An exemplary method includes providing a substrate, comprising a surface comprising a first area comprising a first material and a second area comprising a second material, within a reaction chamber; depositing a p-type doped silicon germanium layer overlying the surface, the p-type doped silicon germanium layer comprising gallium; and depositing a cap layer overlying the p-type doped silicon germanium layer. The method can further include an etch step to remove the cap layer and the p-type doped silicon germanium layer overlying the second material.

Abstract: Methods and devices for epitaxially growing boron doped silicon germanium layers. The layers may be used, for example, as a p-type source and/or drain regions in field effect transistors.

Abstract: Methods and devices for epitaxially growing boron- and gallium-doped silicon germanium layers. The layers may be used, for example, as a p-type source and/or drain regions in field effect transistors.

Abstract: Methods and devices for low-temperature deposition of phosphorous-doped silicon layers. Disilane is used as a silicon precursor, and nitrogen or a noble gas is used as a carrier gas. Phosphine is a suitable phosphorous precursor.

Abstract: Methods and systems for depositing material, such as doped semiconductor material, are disclosed. An exemplary method includes providing a substrate, forming a first doped semiconductor layer overlying the substrate, and forming a second doped semiconductor layer overlying the first doped semiconductor layer, wherein the first doped semiconductor layer comprises a first dopant and a second dopant, and wherein the second doped semiconductor layer comprises the first dopant. Structures and devices formed using the methods and systems for performing the methods are also disclosed.

Abstract: A method for selectively forming an n-type doped material on a surface of a substrate is disclosed. A system for performing the method and structures and devices formed using the method are also disclosed.

Abstract: Methods and systems for selectively depositing material, such as doped semiconductor material, are disclosed. An exemplary method includes providing a substrate, comprising a first area comprising a first material and a second area comprising a second material, selectively depositing a first doped semiconductor layer overlying the first material relative to the second material and selectively depositing a second doped semiconductor layer overlying the first doped semiconductor layer relative to the second material.

Abstract: Methods and systems for selectively depositing a p-type doped silicon germanium layer and structures and devices including a p-type doped silicon germanium layer are disclosed. An exemplary method includes providing a substrate, comprising a surface comprising a first area comprising a first material and a second area comprising a second material, within a reaction chamber; depositing a p-type doped silicon germanium layer overlying the surface, the p-type doped silicon germanium layer comprising gallium; and depositing a cap layer overlying the p-type doped silicon germanium layer. The method can further include an etch step to remove the cap layer and the p-type doped silicon germanium layer overlying the second material.

Abstract: Methods for forming structures that include a layer comprising silicon germanium are disclosed. Exemplary embodiments of the disclosure provide improved methods of forming a transition layer on the layer comprising silicon germanium that can mitigate any formation of an interface layer between the layer comprising silicon germanium and a subsequently formed layer comprising silicon.