Abstract: An object of the invention is to provide a complete depletion-mode SOI field-effect transistor in which transistors having different threshold voltages are integrated. A SiGe film having a high Ge composition and a SiGe film having a low Ge composition are formed on an insulating film, and strain-Si films are respectively formed thereon. Transistors including channel regions in the strain-Si films obtained as a result of this are formed, so that the transistors having different threshold voltages can be integrated.

Abstract: An undoped Ge sacrificial layer with an uneven surface (about 1 nm), a relaxed undoped Si0.7Ge0.3 buffer layer (50 nm), an n-type Si0.7Ge0.3 carrier supply layer, an undoped Si0.7Ge0.3 spacer layer, an undoped strained Si channel layer (10 nm), an undoped Si0.7Ge0.3 cap layer (20 nm), and an undoped strained Si cap layer (2 nm) are sequentially stacked on a p-type Si substrate. Therefore, a buffer layer can be made thin and of low dislocation density since a semiconductor device has a strained semiconductor layer applied with a tensile strain or a compressive strain.

Abstract: High-speed and low-power-consuming transistors such as field effect transistors having strained Si channels and hetero-bipolar transistors are integrated with each other. Used here is a complex structure in which an MOSFET having a thin-film SiGe buffer layer and a strained Si channel are laminated on an insulating film and an HBT having an SiGe base layer formed on a thin-film SiGe layer by epitaxial growth and an Si emitter layer formed on the SiGe base layer are combined with each other. The thin-film SiGe layer formed on the insulating film of the MOSFET is made thinner than the counterpart of the HBT. The thin-film SiGe layer formed on the insulating film of the MOSFET has Ge concentration higher than that of the counterpart of the HBT.

Abstract: The semiconductor device comprises a first insulating layer formed on the semiconductor substrate, at least one double-deck semiconductor nanocrystal formed on the first insulating layer, the at least one double-deck semiconductor nanocrystal comprising a first semiconductor nanocrystal and a second semiconductor nanocrystal stacked one upon the other via a second insulating layer, and a third insulating layer selectively formed on the first insulating layer so as to cover the at least one double-deck semiconductor nanocrystal.

Abstract: A channel layer and a spacer layer form a heterojunction therebetween. A V-shaped groove is formed in the spacer layer. The sharp bottom of the V-shaped is located above the heterojunction interface. On the bottom of the V-shaped groove a plurality of quantum dots are formed in a line and discretely. A gate electrode is formed above the quantum dots. A source electrode is connected to the heterojunction interface to form an ohmic contact therebetween. A drain electrode is connected to the heterojunction interface to form an ohmic contact therebetween. The quantum dots are arranged between the source and drain electrodes.

Abstract: A semiconductor device comprises a semiconductor substrate, a first semiconductor layer under compressive strain formed on the semiconductor substrate, a p-type MISFET (Metal Insulator Semiconductor Field Effect Transistor) formed in a predetermined region of the first semiconductor layer, a second semiconductor layer in a lattice-relaxation condition formed on the first semiconductor layer in a region other than the predetermined region with an insulating film lying therebetween, wherein the insulating film has an opening and the first and second semiconductor layers are connected through the opening, a third semiconductor layer under tensile strain formed on the second semiconductor layer, and an n-type MISFET (Metal Insulator Semiconductor Field Effect Transistor) formed in the third semiconductor layer.

Abstract: A microcavity semiconductor laser disclosed therein includes a double-heterostructure section including an intermediate active layer sandwiched between a first or lower cladding layer and a second or upper cladding layer above a semiconductive substrate. A first multi-layered reflector section is arranged between the substrate and the double-heterostructure section to have its reflectance which becomes maximum near the oscillation wavelength of the laser. The upper cladding layer is semi-spherically formed. A three-dimensional optical reflector covers the double-heterostructure section, for controlling spontaneous emission obtained in the double-heterostructure section along various directions, and for increasing the coupling ratio of spontaneous emission with a specific laser mode, thereby to decrease the threshold current.

Abstract: A microcavity semiconductor laser disclosed therein includes a double-heterostructure section including an intermediate active layer sandwiched between a first or lower cladding layer and a second or upper cladding layer above a semiconductive substrate. A first multi-layered reflector section is arranged between the substrate and the double-heterostructure section to have its reflectance which becomes maximum near the oscillation wavelength of the laser. The upper cladding layer is semi-spherically formed. A three-dimensional optical reflector covers the double-heterostructure section, for controlling spontaneous emission obtained in the double-heterostructure section along various directions, and for increasing the coupling ratio of spontaneous emission with a specific laser mode, thereby to decrease the threshold current.