Isotropic silicon and silicon-germanium etching with tunable selectivity is described. The method includes receiving a substrate having a layer of silicon and a layer of silicon-germanium with sidewall surfaces of silicon and silicon-germanium being uncovered, positioning the substrate in a processing chamber configured for etching substrates, and modifying uncovered surfaces of silicon and silicon-germanium by exposing the uncovered surfaces of silicon and silicon-germanium to radical species. The method further includes executing a gaseous chemical oxide removal process that includes flowing a mixture of a nitrogen-containing gas and a fluorine-containing gas at a first substrate temperature to form a fluorine byproduct followed by executing a sublimation process to remove the fluorine byproduct at a second substrate temperature that is higher than the first substrate temperature, and controlling the second substrate temperature to tune the sublimation rate and etch selectivity of a silicon oxide material relative to a silicon-germanium oxide material.

The invention relates to an avalanche diode that can be employed as an ESD protection device. An avalanche ignition region is formed at the p-n junction of the diode and includes an enhanced defect concentration level to provide rapid onset of avalanche current. The avalanche ignition region is preferably formed wider than the diode depletion zone, and is preferably created by placement, preferably by ion implantation, of an atomic specie different from that of the principal device structure. The doping concentration of the placed atomic specie should be sufficiently high to ensure substantially immediate onset of avalanche current when the diode breakdown voltage is exceeded. The new atomic specie preferably comprises argon or nitrogen, but other atomic species can be employed. However, other means of increasing a defect concentration level in the diode depletion zone, such as an altered annealing program, are also contemplated.

The invention provides methods and devices for fabricating printable semiconductor elements and assembling printable semiconductor elements onto substrate surfaces. Methods, devices and device components of the present invention are capable of generating a wide range of flexible electronic and optoelectronic devices and arrays of devices on substrates comprising polymeric materials. The present invention also provides stretchable semiconductor structures and stretchable electronic devices capable of good performance in stretched configurations.

A method for heat-treating a silicon single crystal wafer by an RTA treatment, including: putting a silicon single crystal wafer having an Nv region for the entire plane of the silicon single crystal wafer or an Nv region containing an OSF region for the silicon single crystal wafer entire plane into an RTA furnace, performing pre-heating at temperature lower than temperature at which silicon reacts with NH3 while supplying gas that contains NH3 into the RTA furnace, subsequently stopping the supply of the gas containing NH3 and starting supply of Ar gas to start an RTA treatment under Ar gas atmosphere in which the NH3 gas remains. This provide a method for heat-treating a silicon single crystal wafer that give gettering capability without degrading TDDB properties even to a silicon single crystal wafer in which the entire plane is an Nv region or an Nv region containing an OSF region.

The present invention relates to a thermal processing method for wafer. A wafer is placed in an environment filled with a gas mixture comprising oxygen gas and deuterium gas, and a rapid thermal processing process is performed on a surface of the wafer. As a result, a denuded zone is formed on the surface of the wafer, deuterium atoms, which may be released to improve characteristics at an interface of semiconductor devices in a later fabrication process, are held in the wafer, and bulk micro-defects are formed far from the semiconductor devices.

The present invention relates to a thermal processing method for wafer. A wafer is placed in an environment filled with a non-oxygenated gas mixture comprising deuterium gas and at least one kind of low active gas, and a rapid heating processing process is performed on a surface of the wafer to heat the wafer to a predetermined high temperature. Then, the wafer is placed in an environment filled with an oxygenated gas mixture, and a rapid cooling processing process is performed on a surface of the wafer. As a result, a denuded zone is formed on the surface of the wafer, deuterium atoms, which may be released to improve characteristics at an interface of semiconductor devices in a later fabrication process, are held in the wafer, and bulk micro-defects are formed far from the semiconductor devices.

A method of producing a semiconductor epitaxial wafer is provided. The method includes irradiating a surface of a semiconductor wafer with cluster ions to form a modified layer in a surface portion of the semiconductor wafer, in which the modified layer includes a constituent element of the cluster ions in solid solution. The method further includes forming an epitaxial layer on the modified layer of the semiconductor wafer. The irradiating is performed such that a portion of the modified layer in a thickness direction becomes an amorphous layer, and an average depth of an amorphous layer surface from a semiconductor wafer surface-side of the amorphous layer is at least 20 nm from the surface of the semiconductor wafer.

A representative method of manufacturing a silicon-on-insulator (SOI) substrate includes steps of depositing an etch stop layer on a dummy wafer, growing an epitaxial silicon layer on the etch stop layer, forming a gettering layer on the epitaxial silicon layer, bonding a buried oxide layer of a main wafer to the gettering layer, and removing the dummy wafer and etch stop layer to expose the epitaxial silicon layer. The SOI substrate has an epitaxial silicon layer adjoining the gettering layer, with the gettering layer interposed between the buried oxide layer and the epitaxial silicon layer.

A semiconductor structure and method for forming same are provided. The forming method includes: providing a base; forming a discrete core layer on the base; forming a spacer on a sidewall of the core layer; removing the core layer; after the core layer is removed, patterning the base using the spacer as a mask to form a fin, the fin including a device fin and a dummy fin; removing the spacer; performing doping removal on the dummy fin one or more times to remove the dummy fin, the step of the doping removal including: performing ion doping on the entire dummy fin or a part of the dummy fin in thickness for improving an etching selection ratio of the dummy fin to the device fin; and removing the ion-doped dummy fin. Embodiments and implementations of the present disclosure help increase a process window of a fin cut process.

A semiconductor structure and method for forming same are provided. The forming method includes: providing a base; forming a discrete core layer on the base; forming a spacer on a sidewall of the core layer; removing the core layer; after the core layer is removed, patterning the base using the spacer as a mask to form a fin, the fin including a device fin and a dummy fin; removing the spacer; performing doping removal on the dummy fin one or more times to remove the dummy fin, the step of the doping removal including: performing ion doping on the entire dummy fin or a part of the dummy fin in thickness for improving an etching selection ratio of the dummy fin to the device fin; and removing the ion-doped dummy fin. Embodiments and implementations of the present disclosure help increase a process window of a fin cut process.