A method of forming a self-forming spacer using oxidation. The self-forming spacer may include forming a fin field effect transistor on a substrate, the fin field effect transistor includes a gate on a fin, the gate is perpendicular to the fin; forming a gate spacer on the gate and a fin spacer on the fin, the gate spacer and the fin spacer are formed in a single step by oxidizing an exposed surface of the gate and an exposed surface of the fin; and removing the fin spacer from the fin.

What is proposed is a method of producing at least two differently heavily doped subzones (3, 5) predominantly doped with a first dopant type in a silicon substrate (1), in particular for a solar cell. The method comprises: covering at least a first subzone (3) of the silicon substrate (1) in which a heavier doping with the first dopant type is to be produced with a doping layer (7) of borosilicate glass, wherein at least a second subzone (5) of the silicon substrate (1) in which a lighter doping with the first dopant type is to be produced is not covered with the doping layer (7), and wherein boron as a dopant of a second dopant type differing from the first dopant type and oppositely polarized with respect to the same is included in the layer (7), and; heating the such prepared silicon substrate (1) to temperatures above 300 C., preferably above 900 C., in a furnace in an atmosphere containing significant quantities of the first dopant type. Additionally, at least a third doped subzone (15) doped with the second dopant type may be produced by the method additionally comprising, prior to the heating, a covering of the doping layer (7), above the third doped subzone (15) to be produced, with a further layer (17) acting as a diffusion barrier for the first dopant type. The method uses the observation that a borosilicate glass layer seems to promote an in-diffusion of phosphorus from a gas atmosphere and may substantially facilitate a manufacturing for example of solar cells, in particular back contact solar cells.

A solar cell includes: a semiconductor substrate which includes a first principal surface and a second principal surface; a first semiconductor layer of the first conductivity type disposed above the first principal surface; and a second semiconductor layer of a second conductivity type disposed below the second principal surface. The semiconductor substrate includes: a first impurity region of the first conductivity type; a second impurity region of the first conductivity type disposed between the first impurity region and the first semiconductor layer; and a third impurity region of the first conductivity type disposed between the first impurity region and the second semiconductor layer. A concentration of an impurity in the second impurity region is higher than a concentration of the impurity in the third impurity region, and the concentration of the impurity in the third impurity region is higher than a concentration of the impurity in the first impurity region.

A method for manufacturing a semiconductor device according to an embodiment includes implanting impurity ions into a SiC layer in a direction of <10-11>1 degrees, <10-1-1>1 degrees, <10-12>1 degrees, or <10-1-2>1 degrees.

A FinFET device structure and method for forming the same are provided. The method includes forming a fin structure over a substrate and forming a dummy gate electrode over a middle portion of the fin structure. The method also includes forming a spacer layer on the dummy gate electrode and on the fin structure and performing a plasma doping process on the dummy gate electrode and on the spacer layer. The method further includes performing an annealing process, wherein the annealing process is performed by using a gas comprising oxygen, such that a doped region is formed in a portion of the fin structure, and the spacer layer is doped with oxygen after the annealing process.

A FinFET device structure and method for forming the same are provided. The method includes forming a fin structure over a substrate and forming a dummy gate electrode over a middle portion of the fin structure. The method also includes forming a spacer layer on the dummy gate electrode and on the fin structure and performing a plasma doping process on the dummy gate electrode and on the spacer layer. The method further includes performing an annealing process, wherein the annealing process is performed by using a gas comprising oxygen, such that a doped region is formed in a portion of the fin structure, and the spacer layer is doped with oxygen after the annealing process.

A semiconductor device includes a plurality of base layers. A tunneling layer is disposed on the plurality of base layers. A contact layer is disposed on the tunneling layer. An alloyed metal contact is annealed on to the contact layer. The alloyed metal contact forms a first region and a second region in the contact layer. The first region of the contact layer diffuses into the tunneling layer. The second region of the contact layer resides over the tunneling layer. The tunneling layer facilitates electron mobility of the second region.

A semiconductor device includes a plurality of base layers. A tunneling layer is disposed on the plurality of base layers. A contact layer is disposed on the tunneling layer. An alloyed metal contact is annealed on to the contact layer. The alloyed metal contact forms a first region and a second region in the contact layer. The first region of the contact layer diffuses into the tunneling layer. The second region of the contact layer resides over the tunneling layer. The tunneling layer facilitates electron mobility of the second region.

A method of forming a self-forming spacer using oxidation. The self-forming spacer may include forming a fin field effect transistor on a substrate, the fin field effect transistor includes a gate on a fin, the gate is perpendicular to the fin; forming a gate spacer on the gate and a fin spacer on the fin, the gate spacer and the fin spacer are formed in a single step by oxidizing an exposed surface of the gate and an exposed surface of the fin; and removing the fin spacer from the fin.

A method of forming a self-forming spacer using oxidation. The self-forming spacer may include forming a fin field effect transistor on a substrate, the fin field effect transistor includes a gate on a fin, the gate is perpendicular to the fin; forming a gate spacer on the gate and a fin spacer on the fin, the gate spacer and the fin spacer are formed in a single step by oxidizing an exposed surface of the gate and an exposed surface of the fin; and removing the fin spacer from the fin.