Methods of manufacturing a semiconductor structure are provided. One of the methods includes the following operations. A substrate is received, and the substrate includes a first conductive region and a second conductive region. A first laser anneal is performed on the first conductive region to repair lattice damage. An amorphization is performed on the first conductive region and the second conductive region to enhance silicide formation to a desired phase transformation in the subsequent operations. A pre-silicide layer is formed on the substrate. A thermal anneal is performed to the substrate to form a silicide layer from the pre-silicide layer. A second laser anneal is performed on the first conductive region and the second conductive region.

An exemplary device includes a channel layer, a first epitaxial source/drain feature, and a second epitaxial source/drain feature disposed over a substrate. The channel layer is disposed between the first epitaxial source/drain feature and the second epitaxial source/drain feature. A metal gate is disposed between the first epitaxial source/drain feature and the second epitaxial source/drain feature. The metal gate is disposed over and physically contacts at least two sides of the channel layer. A source/drain contact is disposed over the first epitaxial source/drain feature. A doped crystalline semiconductor layer, such as a gallium-doped crystalline germanium layer, is disposed between the first epitaxial source/drain feature and the source/drain contact. The doped crystalline semiconductor layer is disposed over and physically contacts at least two sides of the first epitaxial source/drain feature. In some embodiments, the doped crystalline semiconductor layer has a contact resistivity that is less than about 1×10.sup.−9 Ω-cm.sup.2.

Disclosed are a crystallization process of an oxide semiconductor, a method of manufacturing a thin film transistor including the same, a thin film transistor, a display panel, and an electronic device. The crystallization process of an oxide semiconductor includes forming an amorphous oxide semiconductor layer on a substrate, forming a crystallization auxiliary layer including a light absorbing inorganic material on the amorphous oxide semiconductor layer, and annealing the crystallization auxiliary layer to crystallize the amorphous oxide semiconductor layer.

A method of manufacturing a polycrystalline silicon layer, includes forming an amorphous silicon layer on a substrate; doping the amorphous silicon layer with at least one impurity; cleaning the amorphous silicon layer with hydrofluoric acid; rinsing the amorphous silicon layer with hydrogen-added deionized water; and forming a polycrystalline silicon layer by irradiating a laser beam onto the amorphous silicon layer.

An active device substrate includes a substrate, a first active device, and a second active device. The first active device includes a first gate, a crystallized metal oxide layer, a first insulation layer, a first source, and a first drain. The crystallized metal oxide layer is located on the first gate. The first insulation layer is sandwiched between the crystallized metal oxide layer and the first gate. An area from the top surface of the crystallized metal oxide layer to the bottom surface of the crystallized metal oxide layer is observed via a selected area diffraction mode of a transmission electron microscope, and a diffraction pattern of a crystallized phase can be observed. The second active device includes a second gate, a silicon semiconductor layer, a second source, and a second drain. A manufacturing method of an active device substrate is further provided.

A laser irradiation apparatus (1) according to one embodiment includes a laser generating device (14) that generates a laser beam, a flotation unit (10) that causes a workpiece (16) that is to be irradiated with the laser beam to float, and a conveying unit (11) that conveys the floating workpiece (16). The conveying unit (11) conveys the workpiece (16) with the conveying unit (11) holding the workpiece (16) at a position where the conveying unit (11) does not overlap an irradiation position (15) of the laser beam. The laser irradiation apparatus (1) according to one embodiment makes it possible to suppress uneven irradiation with a laser beam.

Embodiments disclosed herein relate to using an implantation process and a melting anneal process performed on a nanosecond scale to achieve a high surface concentration (surface pile up) dopant profile and a retrograde dopant profile simultaneously. In an embodiment, a method includes forming a source/drain structure in an active area on a substrate, the source/drain structure including a first region comprising germanium, implanting a first dopant into the first region of the source/drain structure to form an amorphous region in at least the first region of the source/drain structure, implanting a second dopant into the amorphous region containing the first dopant, and heating the source/drain structure to liquidize and convert at least the amorphous region into a crystalline region, the crystalline region containing the first dopant and the second dopant.

A laser apparatus includes a laser generator configured to generate a first laser beam proceeding along a first direction, and an inversion module configured to convert the first laser beam to a second laser beam proceeding along the first direction, the inversion module including a splitter configured to form a reflected laser beam by partially reflecting the first laser beam, and a transmitted laser beam by partially transmitting the first laser beam, and a prism configured to reflect the reflected laser beam.

A laser irradiation apparatus (1) according to an embodiment includes a laser generation device (14) configured to generate laser light, and a levitation unit (10) configured to levitate an object to be processed (16) to which the laser light is applied. The levitation unit (10) includes a first area and a second area, and the first and second areas are arranged so that, in a plane view, a focal point of the laser light overlaps the first area and the focal point of the laser light does not overlap the second area. A surface part of the second area is formed of a metal member.

A method of manufacturing a low temperature polysilicon thin film, including: forming a buffer layer on a substrate; forming a silicon layer on the buffer layer; providing a mask; patterning the silicon layer through the mask, wherein the patterned silicon layer includes a plurality of recrystallization growth spaces; and annealing the silicon layer to form a polysilicon layer, and a partial silicon material of the polysilicon layer is formed on the recrystallization growth space.