A tank circuit structure includes a first gate layer, a first substrate, a first shielding layer, a first inductor, a second inductor and a first inter metal dielectric (IMD) layer. The first substrate is over the first gate layer. The first shielding layer is over the first gate layer. The first inductor is over the first shielding layer. The second inductor is below the first substrate. The first IMD layer is between the first substrate and the first shielding layer.

A semiconductor device 100 has a power transistor N1 of vertical structure and a temperature detection element 10a configured to detect abnormal heat generation by the power transistor N1. The power transistor N1 includes a first electrode 208 formed on a first main surface side (front surface side) of a semiconductor substrate 200, a second electrode 209 formed on a second main surface side (rear surface side) of the semiconductor substrate 200, and pads 210a-210f positioned unevenly on the first electrode 208. The temperature detection element 10a is formed at a location of the highest heat generation by the power transistor N1, the location (near the pad 210b where it is easiest for current to be concentrated) being specified using the uneven positioning of the pads 210a-210f.

A semiconductor device 100 has a power transistor N1 of vertical structure and a temperature detection element 10a configured to detect abnormal heat generation by the power transistor N1. The power transistor N1 includes a first electrode 208 formed on a first main surface side (front surface side) of a semiconductor substrate 200, a second electrode 209 formed on a second main surface side (rear surface side) of the semiconductor substrate 200, and pads 210a-210f positioned unevenly on the first electrode 208. The temperature detection element 10a is formed at a location of the highest heat generation by the power transistor N1, the location (near the pad 210b where it is easiest for current to be concentrated) being specified using the uneven positioning of the pads 210a-210f.

A semiconductor integrated circuit device includes a core region and an IO region on a chip. In an IO cell row placed in the IO region, a first power supply line extending in the X direction in a low power supply voltage region has a portion protruding to the core region. A signal IO cell has a reinforcing line that connects a second power supply line extending in the X direction in the low power supply voltage region and a third power supply line extending in the X direction in a high power supply voltage region, the reinforcing line extending in the Y direction in a layer above the second and third power supply lines.

A method for forming an integrated circuit device is provided. The method includes forming a transistor over a frontside of a substrate; forming an interconnect structure over the transistor; depositing a first transition metal layer over the interconnect structure; performing a plasma treatment to turn the first transition metal layer into a first transition metal dichalcogenide layer; forming a dielectric layer over the first transition metal dichalcogenide layer; forming a first gate electrode over the dielectric layer and a first portion of the first transition metal dichalcogenide layer; and forming a first source contact and a first drain contact respectively connected with a second portion and a third portion of the first transition metal dichalcogenide layer, the first portion of the first transition metal dichalcogenide layer being between the second and third portions of the first transition metal dichalcogenide layers.

Semiconductor devices and corresponding methods of manufacture are disclosed. A method includes forming a stack of layers on a substrate. The stack includes a first sacrificial dielectric layer, a first metal layer, a second sacrificial dielectric layer, and a second metal layer vertically stacked on top of one another. The stack is etched to form a vertical opening. The opening is filled with a vertical structure. The vertical structure includes a first sacrificial semiconductor segment, a first semiconductor segment, a second sacrificial semiconductor segment, and a second semiconductor segment. The first and second sacrificial semiconductor segments are removed. Silicide layers are formed in the vertical structure to connect thereto.

A mount board has a plurality of terminals electrically connected to a plurality of pins of a semiconductor device, and a conductor pattern. An electrostatic withstand voltage test device includes a metal plate on which the mount board is installed, a power supply for applying a voltage to the metal plate, an insulator disposed between the metal plate and the mount board, a switch circuit connected between the terminals and ground wiring, and a controller for controlling the switch circuit. The switch circuit includes a plurality of first switches provided corresponding to the terminals and each connecting a corresponding terminal to the ground wiring. The controller turns on at least one first switch selected from the first switches when an electric charge stored in the conductor pattern is discharged to the ground wiring through the semiconductor device.

A method according to an embodiment is for forming a capacitor structure on a wafer. A first capacitor is formed on a first side of a wafer, and a second capacitor is formed on a second side of the wafer. The capacitor structure includes the first capacitor and the second capacitor. A trench capacitor is fabricated at both ends of an interposer, which can increase capacitance, and greatly improve the stability of the supplied power.

In a method of forming a semiconductor device, an epitaxial layer stack is formed over a substrate. The epitaxial layer stack includes intermediate layers, one or more first nano layers and one or more second nano layers positioned below the one or more first nano layers. Trenches are formed in the epitaxial layer stack to separate the epitaxial layer stack into sub-stacks, the one of more first nano layers into first nano-channels, and the one or more second nano layers into second nano-channels. The intermediate layers are recessed so that one or more first nano-channels of the first nano-channels and one or more second nano-channels of the second nano-channels in each of the sub-stacks protrude from sidewalls of the intermediate layers. Bottom source/drain (S/D) regions are formed in the trenches to connect the second nano-channels. Top S/D regions are formed in the trenches to connect the first nano-channels.

The present disclosure, in some embodiments, relates to a multi-dimensional integrated chip structure. The multi-dimensional integrated chip structure includes a first substrate having a first upper surface and a second upper surface above the first upper surface. A first outermost perimeter of the first upper surface is larger than a second outermost perimeter of the second upper surface. A second substrate is over the first substrate. The second substrate has a third upper surface above the second upper surface. A third outermost perimeter of the third upper surface is smaller than the second outermost perimeter of the second upper surface.