A laser irradiation apparatus includes a laser light source which emits a laser beam, a first lens through which the laser beam emitted from the laser light source passes, a first scanner which reflects the laser beam passing through the first lens and changes a direction of the laser beam, a second scanner which reflects the laser beam deflected by the first scanner and changes a direction of the laser beam, a plurality of second lenses through which the laser beam deflected by the second scanner passes, where at least one of the plurality of second lenses is configured to vibrate in one direction, and an optical element through which the laser beam passing through the plurality of second lenses passes, where the optical element is configured to correct an incident angle of the laser beam incident a substrate.

Provided is a physical quantity sensor including: a movable body; a base body; and a lid body, in which the movable body is accommodated in a space between the base body and the lid body, the space is sealed with a melt portion obtained by melting a through hole provided in the lid body, the lid body and the melt portion contain silicon, and the melt portion has a continuous curved surface having unevenness.

An embodiment provides a manufacturing method of a polycrystalline silicon layer, including: forming a first amorphous silicon layer on a substrate; doping an N-type impurity into the first amorphous silicon layer; forming a second amorphous silicon layer on the n-doped first amorphous silicon layer; doping a P-type impurity into the second amorphous silicon layer; and crystalizing the n-doped first amorphous silicon layer and the p-doped second amorphous silicon layer by irradiating a laser beam onto n-doped first amorphous silicon layer and the p-doped second amorphous silicon layer to form a polycrystalline silicon layer.

A laser annealing apparatus (1) according to the embodiment includes: a laser beam source (11) configured to emit a laser beam (L1) to crystallize an amorphous silicon film (101a) on a substrate (100) and to form a poly-silicon film (101b); a projection lens (13) configured to condense the laser beam to irradiate a silicon film (101); a probe beam source configured to emit a probe beam (L2); a photodetector (25) configured to detect the probe beam (L3) transmitted through the silicon film (101); a processing apparatus (26) configured to calculate a standard deviation of detection values of a detection signal output from the photodetector, and to determine a crystalline state of the crystallized film based on the standard deviation.

A manufacturing method of a display apparatus including preparing a substrate, forming an amorphous silicon layer on the substrate, cleaning the amorphous silicon layer with hydrofluoric acid, crystallizing the amorphous silicon layer into a polycrystalline silicon layer, and forming a metal layer directly on the polycrystalline silicon layer.

A semiconductor device production system using a laser crystallization method is provided which can avoid forming grain boundaries in a channel formulation region of a TFT, thereby preventing grain boundaries rom lowering the mobility of the TFT greatly, from lowering ON current, and from increasing OFF current. Rectangular or stripe pattern depression and projection portions are formed on an insulating film. A semiconductor film is formed on the insulating film. The semiconductor film is irradiated with continuous wave laser light by running the laser light along the stripe pattern depression and projection portions of the insulating film or along the major or minor axis direction of the rectangle. Although continuous wave laser light is most preferred among laser light, it is also possible to use pulse oscillation laser light in irradiating the semiconductor film.

To provide a laser annealing device capable of performing annealing whereby electron mobility is different depending on the part, a mask, a thin film transistor, and a laser annealing method. A laser annealing device of the present invention is provided with a mask in which a plurality of openings are formed along the scanning direction, moves a substrate in the scanning direction, and irradiates the substrate with laser light via the openings. The openings respectively have first opening regions, which are aligned in the scanning direction, and which have a same shape, and some of the openings among the openings respectively have second opening regions continuous to the first opening regions in the predetermined direction with respect to the first opening regions.

A laser annealing method is for irradiating an amorphous silicon film formed on a substrate 6 with laser beams and crystalizing the amorphous silicon film, wherein a plurality of first and second TFT formation portions 23, 24 on the substrate 6 are irradiated with laser beams at differing irradiation doses so as to crystalize the amorphous silicon film in the first TFT formation portions 23 into a polysilicon film having a crystalline state and crystalize the amorphous silicon film in the second TFT formation portions 24 into a polysilicon film having another crystalline state that is different from that of the polysilicon film in the first TFT formation portions 23.

Provided are a laser annealing apparatus, a laser annealing method, and a mask with which scan nonuniformity can be decreased. According to the present invention, all or some openings of a plurality of openings are configured so that a partial subregion of a prescribed region is irradiated with laser light. The plurality of openings are configured so that, between prescribed regions irradiated with laser light via a group of openings in one row arranged in a row direction and prescribed regions irradiated with laser light via a group of openings in another row arranged in the row direction, the number of times of laser light radiations in subregions having the same occupying region is the same, and at least two openings of a group of openings arranged in a column direction have different positions or shapes.

The present disclosure is directed to semiconductor structures with source/drain epitaxial stacks having a low-melting point top layer and a high-melting point bottom layer. For example, a semiconductor structure includes a gate structure disposed on a fin and a recess formed in a portion of the fin not covered by the gate structure. Further, the semiconductor structure includes a source/drain epitaxial stack disposed in the recess, where the source/drain epitaxial stack has bottom layer and a top layer with a higher activated dopant concentration than the bottom layer.