A plasma processing apparatus includes a process chamber, a substrate support chuck configured to support a substrate in the process chamber, the substrate support chuck including an upper cooling channel and a lower cooling channel that are symmetrically separated from each other, and a support chuck temperature controller configured to supply a first coolant to the upper cooling channel and to supply a second coolant to the lower cooling channel.

A multipurpose membraneless sample platform for supporting a target material, includes a substrate; a dielectric layer formed over a side of the substrate; first and second electrodes formed over the dielectric layer; and a window formed through the substrate and the dielectric layer. There is no material covering the window.

A method of doping a substrate. The method may include providing a substrate in a process chamber. The substrate may include a semiconductor structure, and a dopant layer disposed on a surface of the semiconductor structure. The method may include maintaining the substrate at a first temperature for a first interval, the first temperature corresponding to a vaporization temperature of the dopant layer. The method may further include rapidly cooling the substrate to a second temperature, less than the first temperature, and heating the substrate from the second temperature to a third temperature, greater than the first temperature.

A method of doping a substrate. The method may include providing a substrate in a process chamber. The substrate may include a semiconductor structure, and a dopant layer disposed on a surface of the semiconductor structure. The method may include maintaining the substrate at a first temperature for a first interval, the first temperature corresponding to a vaporization temperature of the dopant layer. The method may further include rapidly cooling the substrate to a second temperature, less than the first temperature, and heating the substrate from the second temperature to a third temperature, greater than the first temperature.

An optical pyrometer having a coaxial light guide delivers laser radiation through optics to heat a localized area on a sample, and simultaneously collects optical radiation from the sample to perform temperature measurement of the heated area. Inner and outer light guides can comprise the core and inner cladding, respectively, of a double-clad fiber (DCF), or can be formed using a combination of optical fibers in one or more coaxial bundles. Coaxial construction and shared optics facilitate alignment of the centers of the heated and observed areas on the sample. The heated area can be on the order of micrometers when using a single-mode optical fiber core as the inner light guide. The system can be configured to heat small samples within a vacuum system of charged-particle beam microscopes such as electron microscopes. A method for using the invention in a microscope is also provided.

An ion implantation method includes irradiating a wafer having a first temperature with a first ion beam such that a predetermined channeling condition is satisfied and irradiating the wafer having a second temperature different from the first temperature with a second ion beam such that the predetermined channeling condition is satisfied, after the irradiation of the first ion beam.

A method of doping a substrate. The method may include providing a substrate in a process chamber. The substrate may include a semiconductor structure, and a dopant layer disposed on a surface of the semiconductor structure. The method may include maintaining the substrate at a first temperature for a first interval, the first temperature corresponding to a vaporization temperature of the dopant layer. The method may further include rapidly cooling the substrate to a second temperature, less than the first temperature, and heating the substrate from the second temperature to a third temperature, greater than the first temperature.

A method of doping a substrate. The method may include providing a substrate in a process chamber. The substrate may include a semiconductor structure, and a dopant layer disposed on a surface of the semiconductor structure. The method may include maintaining the substrate at a first temperature for a first interval, the first temperature corresponding to a vaporization temperature of the dopant layer. The method may further include rapidly cooling the substrate to a second temperature, less than the first temperature, and heating the substrate from the second temperature to a third temperature, greater than the first temperature.

An ion implantation method includes irradiating a wafer having a first temperature with a first ion beam such that a predetermined channeling condition is satisfied and irradiating the wafer having a second temperature different from the first temperature with a second ion beam such that the predetermined channeling condition is satisfied, after the irradiation of the first ion beam.

A method of doping a substrate. The method may include providing a substrate in a process chamber. The substrate may include a semiconductor structure, and a dopant layer disposed on a surface of the semiconductor structure. The method may include maintaining the substrate at a first temperature for a first interval, the first temperature corresponding to a vaporization temperature of the dopant layer. The method may further include rapidly cooling the substrate to a second temperature, less than the first temperature, and heating the substrate from the second temperature to a third temperature, greater than the first temperature.