Abstract: A bipolar transistor is provided with an emitter layer, a base layer and a collector layer. The emitter layer is formed above a substrate and is an n-type conductive layer including a first nitride semiconductor. The base layer is formed on the emitter layer and is a p-type conductive including a second nitride semiconductor. The collector layer is formed on the base layer and includes a third nitride semiconductor. The collector layer, the base layer and the emitter layer are formed such that a crystal growth direction to the substrate surface is parallel to a substrate direction of [000-1]. The third nitride semiconductor contains InycAlxcGa1-xc-ycN (0•xc•1, 0•yc•1, 0<xc+yc•1). The a-axis length on the side of a surface in the third nitride semiconductor is shorter than the a-axis length on the side of the substrate.

Abstract: There is provided an image processing device including a converter configured to obtain, prior to performing an encoding process, image drawing information of an image capable of using upon encoding and to convert the obtained image drawing information into a parameter for encoding, and an encoding processor configured to perform the encoding process by changing contents of the encoding process according to the parameter for encoding converted by the converter.

Abstract: A field effect transistor includes a substrate and a semiconductor layer provided on the substrate, wherein the semiconductor layer includes a lower barrier layer provided on the substrate, Ga-face grown, lattice relaxed, and having a composition In1-zAlzN (0?z?1), a channel layer having a composition of: AlxGa1-xN (0?x?1) or InyGa1-yN (0?y?1). Or GaN provided on and lattice-matched to the lower barrier layer, a source electrode and a drain electrode having ohmic contact to an upper part of the semiconductor layers, disposed spaced to each other, and a gate electrode arranged via a gate insulating film in a region lying between the source electrode and the drain electrode.

Abstract: The present invention provides a semiconductor device having such a structure formed by sequentially laminating a lower barrier layer composed of lattice-relaxed AlxGa1-xN (0?x?1), a channel layer composed of InyGa1-yN (0?y?1) with compressive strain and a contact layer composed of AlzGa1-zN (0?z?1), wherein a two-dimensional electron gas is produced in the vicinity of an interface of said InyGa1-yN channel layer with said AlzGa1-zN contact layer; a gate electrode is formed so as to be embedded in the recessed portion with intervention of an insulating film, which recessed portion is formed by removing a part of said AlzGa1-zN contact layer by etching it away until said InyGa1-yN channel layer is exposed; and, ohmic electrodes are formed on the AlzGa1-zN contact layer. Thus, the semiconductor device has superior uniformity and reproducibility of the threshold voltage while maintaining a low gate leakage current, and is also applicable to the enhancement mode type.

Abstract: A heterojunction filed effect transistor with a low access resistance, a low on resistance, and the like, a method for producing a heterojunction filed effect transistor and an electron device are provided.

Abstract: Provided is a semiconductor device capable of suppressing an occurrence of a punch-through phenomenon. A semiconductor device includes a substrate 1, a first n-type semiconductor layer 2, a p-type semiconductor layer 3, a second n-type semiconductor layer 4, a drain electrode 13, a source electrode 11, a gate electrode 12, and a gate insulation film 21, wherein the first n-type semiconductor layer 2, the p-type semiconductor layer 3, and the second n-type semiconductor layer 4 are laminated on the substrate 1 in this order. The drain electrode 13 is in ohmic-contact with the first n-type semiconductor layer 2. The source electrode 11 is in ohmic-contact with the second n-type semiconductor layer 4. An opening portion to be filled or a notched portion that extends from an upper surface of the second n-type semiconductor layer 4 to an upper part of the first n-type semiconductor layer 2 is formed at a part of the p-type semiconductor layer 3 and a part of the second n-type semiconductor layer 4.

Abstract: A semiconductor device including a field effect transistor having a buffer layer subjected to lattice relaxation, a channel layer, and an electron supply layer formed in this order with group-III nitride semiconductors respectively in a growth mode parallel with a [0001] or [000-1] crystallographic axis over a substrate and having a source electrode and a drain electrode, those being coupled electrically to the channel layer, and a gate electrode formed over the electron supply layer, in which, in the buffer layer and the electron supply layer, a layer existing on the group-III atomic plane side of the channel layer has an A-axis length larger than a layer existing on the group-V atomic plane side of the channel layer; and the electron supply layer has a bandgap larger than the channel layer.

Abstract: In a high electron mobility transistor, with a normally-off operation maintained, on-resistance can be sufficiently reduced, so that the performance of a semiconductor device including the high electron mobility transistor is improved. Between a channel layer and an electron supply layer, a spacer layer whose band gap is larger than the band gap of the electron supply layer is provided. Thereby, due to the fact that the band gap of the spacer layer is large, a high potential barrier (electron barrier) is formed in the vicinity of an interface between the channel and the electron supply layer.

Abstract: There is provided a semiconductor apparatus capable of achieving both a reverse blocking characteristic and a low on-resistance. The semiconductor apparatus includes a first semiconductor layer including a channel layer, a source electrode formed on the first semiconductor layer, a drain electrode formed at a distance from the source electrode on the first semiconductor layer, and a gate electrode formed between the source electrode and the drain electrode on the first semiconductor layer. The drain electrode includes a first drain region where reverse current between the first semiconductor layer and the first drain region is blocked, and a second drain region formed at a greater distance from the gate electrode than the first drain region, where a resistance between the first semiconductor layer and the second drain region is lower than a resistance between the first semiconductor layer and the first drain region.

Abstract: A semiconductor device includes a channel layer, an electron-supplying layer provided on the channel layer, a cap layer provided on the electron-supplying layer and creating lattice match with the channel layer, and ohmic electrodes provided on the cap layer. The cap layer has a composition of (InyAl1-y)zGa1-zN (0?y?1, 0?z?1). The z for such cap layer monotonically decreases as being farther away from the electron-supplying layer.

Abstract: Disclosed is an HJFET 110 which comprises: a channel layer 12 composed of InyGa1-yN (0?y?1); a carrier supply layer 13 composed of AlxGa1-xN (0?x?1), the carrier supply layer 13 being provided over the channel layer 12 and including at least one p-type layer; and a source electrode 15S, a drain electrode 15D and a gate electrode 17 which are disposed facing the channel layer 12 through the p-type layer, and provided over the carrier supply layer 13. The following relational expression is satisfied: 5.6×1011x<NA×?×t [cm?2]<5.6×1013x, where x denotes an Al compositional ratio of said carrier supply layer, t denotes a thickness of said p-type layer, NA denotes an impurity concentration, and ? denotes an activation ratio.

Abstract: The present technology is related to an image processing device and image processing method that enables the generating of 3D images that can be viewed safely and comfortably. The communication unit acquires encoded data of 3D images, and the 3D image bitstream that includes at least the disparity information representing the disparity of these 3D images. The CPU specifies the playback timing of the 3D images. Based on the disparity information, the CPU determines the re-encoding section, which is the section of a front stream and back stream where adjustment of the disparity is needed, so that the difference between the disparity of 3D images of which the timings of playback are consecutive is at or below a predetermined threshold. The editing unit adjusts the disparity of the image data in the re-encoding section. The present technology is applicable, for example, to an editing device that edits 3D images.

Abstract: A semiconductor device comprises a substrate 1, a first n-type semiconductor layer 21?, a second n-type semiconductor layer 23, a p-type semiconductor layer 24, and a third n-type semiconductor layer 25?, wherein the first n-type semiconductor layer 21?, the second n-type semiconductor layer 23, the p-type semiconductor layer 24, and the third n-type semiconductor layer 25? are laminated at the upper side of the substrate 1 in this order. The drain electrode 13 is in ohmic-contact with the first n-type semiconductor layer 21? and the source electrode 12 is in ohmic-contact with the third n-type semiconductor layer 25?.

Abstract: The present invention provides a field effect transistor which can achieve both of a high threshold voltage and a low on-state resistance, a method for producing the same, and an electronic device. In the field effect transistor, each of a buffer layer 112, a channel layer 113, a barrier layer 114, and a spacer layer 115 is formed of a group-III nitride semiconductor, and each of the upper surfaces thereof is a group-III atomic plane that is perpendicular to a (0001) crystal axis. The lattice-relaxed buffer layer 112, the channel layer 113 having a compressive strain, and the barrier layer 114 having a tensile strain, and the spacer layer 115 having a compressive strain are laminated on a substrate 100 in this order. The gate insulating film 14 is arranged on the spacer layer 115. The gate electrode 15 is arranged on the gate insulating film 14. The source electrode 161 and the drain electrode 162 are electrically connected to the channel layer 113 directly or via another component.

Abstract: The present invention provides a field effect transistor which can achieve both of a high threshold voltage and a low on-state resistance, a method for producing the same, and an electronic device. In the field effect transistor, each of a buffer layer 112, a channel layer 113, a barrier layer 114, and a spacer layer 115 is formed of a group-III nitride semiconductor, and each of the upper surfaces thereof is a group-III atomic plane that is perpendicular to a (0001) crystal axis. The lattice-relaxed buffer layer 112, the lattice-relaxed channel layer 113, and the barrier layer 114 having a tensile strain, and the spacer layer 115 are laminated on a substrate 100 in this order. The gate insulating film 14 is arranged on the spacer layer 115. The gate electrode 15 is arranged on the gate insulating film 14. The source electrode 161 and the drain electrode 162 are electrically connected to the channel layer 113 directly or via another component.

Abstract: A semiconductor device capable of suppressing the occurrence of a punch-through phenomenon is provided. A first n-type conductive layer (2?) is formed on a substrate (1?). A p-type conductive layer (3?) is formed thereon. A second n-type conductive layer (4?) is formed thereon. On the under surface of the substrate (1?), there is a drain electrode (13?) connected to the first n-type conductive layer (2?). On the upper surface of the substrate (1?), there is a source electrode (11?) in ohmic contact with the second n-type conductive layer (4?), and a gate electrode (12?) in contact with the first n-type conductive layer (2?), p-type conductive layer (3?), the second n-type conductive layer (4?) through an insulation film (21?). The gate electrode (12?) and the source electrode (11?) are alternately arranged. The p-type conductive layer (3?) includes In.

Abstract: A bipolar transistor includes: a substrate; a collector and a base layer with a p-conductive-type, an emitter layer with an n-conductive-type. The collector layer is formed above the substrate and includes a first nitride semiconductor. The base layer with the p-conductive-type is formed on the collector layer and includes a second nit ride semiconductor. The emitter layer with the n-conductive-type is formed on the base layer and includes a third nitride semiconductor. The collector layer, the base layer and the emitter layer are formed so that crystal growing directions with respect to a surface of the substrate are in parallel to a [0001] direction of the substrate. The first nitride semiconductor includes: InycAlxcGa1-xc-ycN (0?xc?1, 0?yc?1, 0<xc+yc?1). In the first nitride semiconductor, a length of an a-axis on a surface side is longer than a length of an a-axis on a substrate side.

Abstract: A semiconductor device includes a lower barrier layer 12 composed of a layer of AlxGa1-xN (0?x?1) in a state of strain relaxation, and a channel layer 13, which is composed of a layer of InyGa1-yN (0?y?1) disposed on the lower barrier layer 12, has band gap that is smaller than band gap of the lower barrier layer 12, and exhibits compressive strain. A gate electrode 1G is formed over the channel layer 13 via an insulating film 15 and a source electrode 1S and a drain electrode 1D serving as ohmic electrodes are formed over the channel layer 13. The insulating film 15 is constituted of polycrystalline or amorphous member.

Abstract: A silicone microemulsion composition obtained by microemulsifying a carboxy-modified organopolysiloxane, and having a lower surface tension than conventional microemulsions. The composition includes 100 parts by mass of a specific carboxy-modified organopolysiloxane (A), 25 to 75 parts by mass of a specific polyether-modified organopolysiloxane (B), 0.1 to 10 parts by mass of an anionic surfactant, and 20 to 6,000 parts by mass of water, wherein the average particle size of the emulsion particles is not more than 100 nm.

Abstract: A silicone microemulsion composition obtained by microemulsifying a carboxy-modified organopolysiloxane, and having a lower surface tension than conventional microemulsions. The composition includes 100 parts by mass of a specific carboxy-modified organopolysiloxane (A), 25 to 75 parts by mass of a specific polyether-modified organopolysiloxane (B), 0.1 to 10 parts by mass of an anionic surfactant, and 20 to 6,000 parts by mass of water, wherein the average particle size of the emulsion particles is not more than 100 nm.