The present invention is related to a heating device for heating an object material using a laser beam, the heating device comprising a stage on which the object material is placed; a laser module for generating and outputting a laser beam; an optical module for controlling a path of the laser beam; a polygon mirror rotating around an axis of rotation and having a plurality of reflecting surfaces which reflect the laser beam; and a beam guide module for controlling an incidence range within which the laser beam reflected by the polygon mirror is incident on the object material, and an indirect heating method using a laser beam in a heating device.

The present invention is related to a heating device for heating an object material using a laser beam, the heating device comprising a stage on which the object material is placed; a laser module for generating and outputting a laser beam; an optical module for controlling a path of the laser beam; a polygon mirror rotating around an axis of rotation and having a plurality of reflecting surfaces which reflect the laser beam; and a beam guide module for controlling an incidence range within which the laser beam reflected by the polygon mirror is incident on the object material, and an indirect heating method using a laser beam in a heating device.

A semiconductor device having favorable electrical characteristics is provided. A semiconductor device having stable electrical characteristics is provided. A highly reliable semiconductor device is provided. The semiconductor device includes a semiconductor layer, a first insulating layer, and a first conductive layer. The semiconductor layer includes an island-shaped top surface. The first insulating layer is provided in contact with a top surface and a side surface of the semiconductor layer. The first conductive layer is positioned over the first insulating layer and includes a portion overlapping with the semiconductor layer. In addition, the semiconductor layer includes a metal oxide, and the first insulating layer includes an oxide. The semiconductor layer includes a first region overlapping with the first conductive layer and a second region not overlapping with the first conductive layer. The first insulating layer includes a third region overlapping with the first conductive layer and a fourth region not overlapping with the first conductive layer. Furthermore, the second region and the fourth region contain phosphorus or boron.

A method of manufacturing a semiconductor wafer in a reaction apparatus includes channeling a process gas into a reaction chamber of the reaction apparatus, heating the semiconductor wafer with a high intensity lamp positioned below the reaction chamber, blocking radiant heat from the high intensity lamp from heating a center region of the semiconductor wafer with a cap positioned on a shaft within the reaction chamber, the cap including a tube and a disc attached to the tube, where the disc generates a uniform temperature distribution on the semiconductor wafer, and depositing a layer on the semiconductor wafer with the process gas, where the uniform temperature distribution forms a uniform thickness of the layer on the semiconductor wafer.

The present invention is related to a heating device for heating an object material using a laser beam, the heating device comprising a stage on which the object material is placed; a laser module for generating and outputting a laser beam; an optical module for controlling a path of the laser beam; a polygon mirror rotating around an axis of rotation and having a plurality of reflecting surfaces which reflect the laser beam; and a beam guide module for controlling an incidence range within which the laser beam reflected by the polygon mirror is incident on the object material, and an indirect heating method using a laser beam in a heating device.

A semiconductor device includes a semiconductor layer, a crystal defect region formed in the semiconductor layer, and an insulating layer formed on the semiconductor layer, composed of an insulator containing silicon, and including, in the insulator, an Si—H bond in which a dangling bond of silicon atom is hydrogen-terminated.

A method for treating a wafer is provided with a portion of a semiconductor layer is selectively removed from the wafer so as to create an inactive region of the wafer surrounding a first active region of the wafer. The inactive region of the wafer has an exposed portion of an insulator layer, but none of the semiconductor layer. The first active region of the wafer includes a first portion of the semiconductor layer and a first portion of the insulator layer. At least one conductor is formed in contact with the first portion of the semiconductor layer, such that the conductor and the first portion of the semiconductor layer form a portion of an electrical circuit. The first active region of the wafer is selectively treated to remove a native oxide layer from the first portion of the semiconductor layer. A resulting wafer is also disclosed.

A method for making an article comprising silicon carbide. The method includes producing an article including silicon carbide via additive manufacturing. The method further includes heating via at least one laser beam in a site-selective and locally limited manner a surface of the article so as to cause at least one of ablation and chemical modification of the surface.

An apparatus for treating a substrate is disclosed. The apparatus for treating the substrate includes a housing having a treatment space inside the housing, a plate to support the substrate inside the housing, a heating member provided inside the plate to heat the substrate and including a plurality of heating zones, a temperature measuring member to measure a temperature of the substrate with respect to each of the plurality of heating zones of the heating member, and a control unit to control a temperature for the heating member in a dynamic section of a temperature change graph measured in the temperature measuring member. The control unit performs temperature control with respect to each of the plurality of heating zones of the heating member to uniformize the thickness of the thin film on the substrate.

Described herein is a technique capable of uniformly processing a substrate. According to one aspect of the technique, there is provided a substrate processing apparatus including: a process chamber in which a substrate is processed; a microwave generator configured to supply a microwave to the process chamber to perform a heat treatment on the substrate; a substrate retainer configured to accommodate the substrate and a heat retainer provided above the substrate and retaining a temperature of the substrate heated by the microwave; and a first ring plate provided on an outer circumference of the heat retainer and whose outer diameter is greater than that of the substrate.