A memory structure, device, and method of making the same, the memory structure including a surrounding gate thin film transistor (TFT) and a memory cell stacked on the GAA transistor. The GAA transistor includes: a channel comprising a semiconductor material; a source electrode electrically connected to a first end of the channel; a drain electrode electrically connected to an opposing second end of the channel; a high-k dielectric layer surrounding the channel; and a gate electrode surrounding the high-k dielectric layer. The memory cell includes a first electrode that is electrically connected to the drain electrode.

A pressure sensor element and a receiving circuit are formed on an IC chip. A transmitting circuit and a piezoelectric element of an actuator are respectively formed on a transmitting chip and a piezoelectric chip. The piezoelectric chip and the pressure sensor face each other separated by a distance in an airtight first space surrounded by a package main body and a base substrate. Dielectric breakdown voltage of signal transmission from the primary side to the secondary side is set by the distance. The first space is a pressure propagation region including an insulating medium capable of transmitting vibrations of the piezoelectric element as pressure. The signal transmission is performed with high insulation by the pressure generated in the pressure propagation region between components integrated in a single module by insulating the primary side and the secondary side from each other by the insulating medium of the pressure propagation region.

An active matrix substrate is provided with a plurality of oxide semiconductor TFTs including a plurality of first TFTs. An oxide semiconductor layer of each oxide semiconductor TFT includes a channel region, a source contact region, and a drain contact region. In a view from a normal direction of the substrate, the channel region is a region located between the source contact region and the drain contact region and overlapping a gate electrode, and the channel region includes a first end portion and a second end portion that oppose each other and extend in a first direction from the source contact region side toward the drain contact region side, a source side end portion that is located on the source contact region side of the first and second end portions and extends in a second direction that intersects the first direction, and a drain side end portion that is located on the drain contact region side of the first and second end portions and extends in the second direction. Each first TFT further includes a light blocking layer located between the oxide semiconductor layer and the substrate. In a view from the normal direction of the substrate, the light blocking layer includes an opening region that overlaps part of the channel region and a light blocking region that overlaps another part of the channel region. In a view from the normal direction of the substrate, the light blocking region includes a first light blocking portion that extends in the first direction over the first end portion of the channel region and a second light blocking portion that extends in the first direction over the second end portion of the channel region; each of the first light blocking portion and the second light blocking portion includes a first edge portion and a second edge portion that oppose each other and extend in the first direction; at least part of the first edge portion overlaps the channel region; and the second edge portion is located on an outer side of the channel region and does not overlap the channel region.

To provide a semiconductor device in which a large current can flow. To provide a semiconductor device which can be driven stably at a high driving voltage. The semiconductor device includes a semiconductor layer, a first electrode and a second electrode electrically connected to the semiconductor layer and apart from each other in a region overlapping with the semiconductor layer, a first gate electrode and a second gate electrode with the semiconductor layer therebetween, a first gate insulating layer between the semiconductor layer and the first gate electrode, and a second gate insulating layer between the semiconductor layer and the second gate electrode. The first gate electrode overlaps with part of the first electrode, the semiconductor layer, and part of the second electrode. The second gate electrode overlaps with the semiconductor layer and part of the first electrode, and does not overlap with the second electrode.

A display device includes pixels connected to scan lines and data lines intersecting the scan lines, wherein each of the pixels includes a light-emitting element, a driving transistor to control a driving current supplied to the light-emitting element according to a data voltage applied from the data lines, and a switching transistor to apply the data voltage of the data line to the driving transistor according to a scan signal applied from the scan lines. The driving transistor includes a first active layer having an oxide semiconductor and a first gate electrode below the first active layer. The switching transistor includes a second active layer having a same oxide semiconductor as the oxide semiconductor of the first active layer and a second gate electrode below the second active layer. At least one of the driving transistor and the switching transistor includes an oxide layer above each of the active layers.

To provide a semiconductor device with a novel structure. The semiconductor device includes an accelerator. The accelerator includes a first memory circuit, a second memory circuit, and an arithmetic circuit. The first memory circuit includes a first transistor. The second memory circuit includes a second transistor. Each of the first transistor and the second transistor includes a semiconductor layer including a metal oxide in a channel formation region. The arithmetic circuit includes a third transistor. The third transistor includes a semiconductor layer including silicon in a channel formation region. The first transistor and the second transistor are provided in different layers. The layer including the first transistor is provided over a layer including the third transistor. The layer including the second transistor is provided over the layer including the first transistor. The data retention characteristics of the first memory circuit are different from those of the second memory circuit.

A novel semiconductor device is provided. A memory string, which extends in the Z direction and includes a conductor and an oxide semiconductor, intersects with a plurality of wirings CG extending in the Y direction. The conductor is placed along a center axis of the memory string, and the oxide semiconductor is concentrically placed outside the conductor. The conductor is electrically connected to the oxide semiconductor. An intersection portion of the memory string and the wiring CG functions as a transistor. In addition, the intersection portion functions as a memory cell.

A semiconductor device that has low power consumption and is capable of performing a product-sum operation is provided. The semiconductor device includes first and second cells, a first circuit, and first to third wirings. Each of the first and second cells includes a capacitor, and a first terminal of each of the capacitors is electrically connected to the third wiring. Each of the first and second cells has a function of feeding a current based on a potential held at a second terminal of the capacitor, to a corresponding one of the first and second wirings. The first circuit is electrically connected to the first and second wirings and stores currents I1 and I2 flowing through the first and second wirings. When the potential of the third wiring changes and accordingly the amount of current of the first wiring changes from I1 to I3 and the amount of current of the second wiring changes from I2 to I4, the first circuit generates a current with an amount I1-I2-I3+I4. Note that the potential of the third wiring is changed by firstly inputting a reference potential to the third wiring and then inputting a potential based on internal data or a potential based on information obtained by a sensor.

A vertical-structure field-effect transistor comprises: a gate electrode, which is formed on a substrate and has a horizontal plane extending in the planar direction and a vertical plane extending in the height direction; a gate insulating layer for covering the gate electrode; a vertical channel which is formed on the gate insulating layer and has a channel formed in the height direction; a source electrode formed to make contact with one end of the vertical channel; and a drain electrode formed to make contact with the other end of the vertical channel and formed at a height level different from that of the source electrode, wherein channel on/off of the vertical channel is controlled by means of an electric field formed from the vertical plane of the gate electrode to the vertical channel, and the source electrode and/or the drain electrode can be non-overlapping on the gate electrode in the height direction of the gate electrode.

A semiconductor device with different configurations of gate structures and a method of fabricating the same are disclosed. The semiconductor device includes a first gate structure and a second gate structure. The first gate structure includes a first interfacial oxide (IO) layer, a first high-K (HK) dielectric layer disposed on the first interfacial oxide layer, and a first dipole layer disposed at an interface between the first IL layer and the first HK dielectric layer. The HK dielectric layer includes a rare-earth metal dopant or an alkali metal dopant. The second gate structure includes a second IL layer, a second HK dielectric layer disposed on the second IL layer, and a second dipole layer disposed at an interface between the second IL layer and the second HK dielectric layer. The second HK dielectric layer includes a transition metal dopant and the rare-earth metal dopant or the alkali metal dopant.