Abstract: Provided are an etching method for a multi-layered structure of semiconductors in groups III-V and a method of manufacturing a VCSEL using the etching method. According to the etching method, a stacked structure including a first semiconductor layer and a second semiconductor layer is exposed to a plasma of a mixture consisting of Cl2, Ar, CH4, and H2 to etch the stacked structure, so that a mirror layer of the VCSEL is formed. The first semiconductor layer is formed of a semiconductor in groups III-V and the second semiconductor layer is formed of a semiconductor in groups III-V, other than the semiconductor of the first semiconductor layer. At least part of a lower mirror layer, a lower electrode layer, an optical gain layer, an upper electrode layer, and an upper mirror layer is etched using one time of an etching process, so that a clean and smooth etched surface is obtained.

Abstract: Provided is a semiconductor optical device having a current-confined structure. The device includes a first semiconductor layer of a first conductivity type which is formed on a semiconductor substrate and includes one or more material layers, a second semiconductor layer which is formed on the first semiconductor layer and includes one or more material layers, and a third semiconductor layer of a second conductivity type which is formed on the second semiconductor layer and includes one or more material layers. One or more layers among the first semiconductor layer, the second semiconductor, and the third semiconductor layer have a mesa structure. A lateral portion of at least one of the material layers constituting the first semiconductor layer, the second semiconductor layer, and the third semiconductor layer is recessed, and the recess is partially or wholly filled with an oxide layer, a nitride layer or a combination of them.

Abstract: Provided is a method of fabricating a vertical cavity surface emitting laser among semiconductor optical devices, comprising: bonding a dielectric mirror layer to an epi-structure having a mirror layer and an active layer; bonding these on a new substrate using a metal bonded method; removing the existing substrate; and fabricating a vertical cavity surface emitting laser on the new substrate. The method of fabricating the vertical cavity surface emitting laser is performed by moving and attaching a vertical cavity surface emitting laser to a new substrate using an external metallic bonding method, without electrically and optically affecting upper and lower mirrors and an active layer that constitutes the vertical cavity surface emitting laser.

Abstract: Provided is a method for fabricating a semiconductor optical device that can be used as a reflecting semiconductor mirror or an optical filter, in which two or more types of semiconductor layers having different etch rates are alternately stacked, at least one type of semiconductor layers is selectively etched to form an air-gap structure, and an oxide or a nitride having a good heat transfer property is deposited so that the air gap is buried, whereby it is possible to effectively implement the semiconductor reflector or the optical filter having a high reflectance in a small period because of the large index contrast between the oxide or the nitride buried in the air gap and the semiconductor layer.

Abstract: Provided is a method of forming quantum dots in which the quantum dots are formed on a thin InxGa1-xAs strained layer. The In(Ga)As quantum dots can be applied to an active layer of an optical device such as a laser diode or an optical detector.

Abstract: Provided is a semiconductor optical device having a current-confined structure. The device includes a first semiconductor layer of a first conductivity type which is formed on a semiconductor substrate and includes one or more material layers, a second semiconductor layer which is formed on the first semiconductor layer and includes one or more material layers, and a third semiconductor layer of a second conductivity type which is formed on the second semiconductor layer and includes one or more material layers. One or more layers among the first semiconductor layer, the second semiconductor, and the third semiconductor layer have a mesa structure. A lateral portion of at least one of the material layers constituting the first semiconductor layer, the second semiconductor layer, and the third semiconductor layer is recessed, and the recess is partially or wholly filled with an oxide layer, a nitride layer or a combination of them.

Abstract: The present invention relates to a method of fabricating vertical-cavity surface emitting lasers being watched as a light source for long wavelength communication. The present invention includes forming a layer having a high resistance near the surface by implanting heavy ions such as silicon (Si), so that the minimum current injection diameter is made very smaller unlike implantation of a proton. Further, the present invention includes regrowing crystal so that current can flow the epi surface in parallel to significantly reduce the resistance up to the current injection part formed by silicon (Si) ions. Therefore, the present invention can not only effectively reduce the current injection diameter but also significantly reduce the resistance of a device to reduce generation of a heat. Further, the present invention can further improve dispersion of a heat using InP upon regrowth and thus improve the entire performance of the device.

Abstract: The present invention relates to a method of fabricating vertical-cavity surface emitting lasers being watched as a light source for long wavelength communication. The present invention includes forming a layer having a high resistance near the surface by implanting heavy ions such as silicon (Si), so that the minimum current injection diameter is made very smaller unlike implantation of a proton. Further, the present invention includes regrowing crystal so that current can flow the epi surface in parallel to significantly reduce the resistance up to the current injection part formed by silicon (Si) ions. Therefore, the present invention can not only effectively reduce the current injection diameter but also significantly reduce the resistance of a device to reduce generation of a heat. Further, the present invention can further improve dispersion of a heat using InP upon regrowth and thus improve the entire performance of the device.

Abstract: A long-wavelength VCSEL is provided.