Abstract: A first conductive type layer having a band gap energy smaller than that of an under growth layer formed on a substrate is formed by selective growth from an opening portion formed in the under growth layer, and an active layer and a second conductive type layer are stacked on the first conductive type layer, to form a stacked structure. When such a stacked structure for forming a semiconductor device is irradiated with laser beams having an energy value between the band gap energies of the under growth layer and the first conductive type layer, abrasion occurs at a first conductive type layer side interface between the under growth layer and the first conductive type layer, so that the stacked structure is peeled from the substrate and the under growth layer and simultaneously isolated from another stacked structure for forming another semiconductor device.

Abstract: Semiconductor light emitting devices and a method of fabricating the semiconductor light emitting devices are provided. The semiconductor light emitting device includes a growth substrate, a first growth layer formed on the growth substrate, a growth obstruction film formed on the first growth layer, and a second growth layer formed by selective growth from an opening portion formed in the growth obstruction film, wherein device isolation trenches for isolating devices from each other are formed in the first growth layer formed on the growth substrate, and the second growth layer is formed by selective growth after formation of the device isolation trenches.

Abstract: Nitride semiconductor devices and methods of producing same are provided. The present invention includes forming a nitride semiconductor layer on a base body of the nitride semiconductor under selective and controlled crystal growth conditions. For example, the crystal growth rate, the supply of crystal growth source material and/or the crystal growth area can be varied over time, thus resulting in a nitride semiconductor device with enhanced properties.

Abstract: Nitride semiconductor devices and methods of producing same are provided. The present invention includes forming an active layer on a substrate by vapor phase growth at a first temperature and forming thereon one or more nitride semiconductor layers at a temperature which is greater from the first temperature, such as by about 250° C. or less. The nitride semiconductor devices of the present invention can be used in a variety of different applications.

Abstract: A display unit and semiconductor light emitting devices are provided. The display unit includes a number of the semiconductor light emitting devices arrayed on a base body, wherein each of the semiconductor light emitting devices is formed together with dummy devices for setting an emission wavelength of the semiconductor light emitting device, and the semiconductor light emitting device is formed by selective growth, and one conductive layer is formed in self-alignment on planes grown from tilt planes formed by selective growth. Such a display unit has a structure suitable for multi-colors without increasing the number of production steps.

Abstract: Methods of crystal growth for semiconductor materials, such as nitride semiconductors, and methods of manufacturing semiconductor devices are provided. The method of crystal growth includes forming a number of island crystal regions during a first crystal growth phase and continuing growth of the island crystal regions during a second crystal growth phase while bonding of boundaries of the island crystal regions occurs. The second crystal growth phase can include a crystal growth rate that is higher than the crystal growth rate of the first crystal growth phase and/or a temperature that is lower than the first crystal growth phase. This can reduce the density of dislocations, thereby improving the performance and service life of a semiconductor device which is formed on a nitride semiconductor made in accordance with an embodiment of the present invention.

Abstract: Semiconductor light emitting devices and methods of producing same are provided. The semiconductor light emitting devices include a substrate that has a surface including a difference-in-height portion composed of, for example, a wurtzite compound. A crystal growth layer is formed in the substrate surface wherein at least a portion of which is oriented along an inclined plane with respect to a principal plane of the substrate. The semiconductor device includes a first conductive layer, an active layer and a second conductive layer formed on the crystal layer in a stacked arrangement and oriented along the inclined place.

Abstract: Semiconductor light emitting devices are provided. The semiconductor light emitting device includes a base body, a selection mask having a stripe-shaped opening portion, the selection mask being formed on the base body, a semiconductor layer formed by selective growth from the opening portion in such a manner as to have a ridge line substantially parallel to long-sides of the opening portion, and a first conductive type cladding layer, an active layer, and a second conductive type cladding layer, which are formed on the semiconductor layer.

Abstract: Semiconductor light-emitting devices are provided. The semiconductor light-emitting devices include a substrate and a crystal layer selectively grown thereon at least a portion of the crystal layer is oriented along a plane that slants to or diagonally intersect a principal plane of orientation associated with the substrate thereby for example, enhancing crystal properties, preventing threading dislocations, and facilitating device miniaturization and separation during manufacturing and use thereof.

Abstract: Disclosed herein is a process for vapor phase growth of gallium nitride compound semiconductor which yields uniform crystal layers with good reproducibility. The process comprises forming a first nitride semiconductor layer on a substrate, forming thereon a protective film for crystal growth prevention in such a way that it has partly open window regions through which the first nitride semiconductor layer is exposed, forming a second nitride semiconductor layer by selective growth from the first nitride semiconductor layer at a crystal growth starting temperature, and continuing crystal growth at a temperature higher than the crystal growth starting temperature. The vapor phase growth at a low temperature yields a uniform crystal layer, and the ensuing vapor phase growth at a raised temperature yields a uniform crystal layer with good reproducibility in conformity with the first crystal layer.

Abstract: A crystal growth method includes forming a mask layer capable of impeding crystal growth on a substrate in such a way a first nitride semiconductor layer has irregularities at a surface thereof exposed at a window region opened at a part of the mask layer, and growing a second nitride semiconductor layer over a region including the surface of the mask layer through crystal growth from the irregularities. Through-type dislocations can be reliably prevented from propagation due to the discontinuity of crystals at the irregularities and also to lateral crystal growth.