Describe is a resonator that uses ferroelectric (FE) material in a capacitive structure. The resonator includes a first plurality of metal lines extending in a first direction; an array of capacitors comprising ferroelectric material; a second plurality of metal lines extending in the first direction, wherein the array of capacitors is coupled between the first and second plurality of metal lines; and a circuitry to switch polarization of at least one capacitor of the array of capacitors. The switching of polarization regenerates acoustic waves. In some embodiments, the acoustic mode of the resonator is isolated using phononic gratings all around the resonator using metal lines above and adjacent to the FE based capacitors.

An integrated circuit (IC) structure includes a semiconductor substrate, a shallow trench isolation (STI) region, and a capacitor. The STI region is embedded in the semiconductor substrate. The capacitor includes first and second conductive stacks. The first conductive stack includes a first dummy gate strip disposed entirely within the STI region and a plurality of first metal dummy gate contacts landing on the first metal capacitor strip. The second conductive stack includes a second dummy gate strip disposed entirely within the STI region and extending in parallel with the first dummy gate strip, and a plurality of second dummy gate contacts landing on the second dummy gate strip, wherein the first conductive stack is electrically isolated from the second conductive stack.

An integrated circuit (IC) structure includes a semiconductor substrate, a shallow trench isolation (STI) region, and a capacitor. The STI region is embedded in the semiconductor substrate. The capacitor includes first and second conductive stacks. The first conductive stack includes a first dummy gate strip disposed entirely within the STI region and a plurality of first metal dummy gate contacts landing on the first metal capacitor strip. The second conductive stack includes a second dummy gate strip disposed entirely within the STI region and extending in parallel with the first dummy gate strip, and a plurality of second dummy gate contacts landing on the second dummy gate strip, wherein the first conductive stack is electrically isolated from the second conductive stack.

Semiconductor device structures with substrate biasing, methods of forming a semiconductor device structure with substrate biasing, and methods of operating a semiconductor device structure with substrate biasing. A substrate contact is coupled to a portion of a bulk semiconductor substrate in a device region. The substrate contact is configured to be biased with a negative bias voltage. A field-effect transistor includes a semiconductor body in the device region of the bulk semiconductor substrate. The semiconductor body is electrically isolated from the portion of the bulk semiconductor substrate.

A semiconductor metal-oxide-semiconductor field effect transistor (MOSFET) transistor with increased on-state current obtained through intrinsic bipolar junction transistor (BJT) of MOSFET has been described. Methods of operating the MOS transistor are provided.

Semiconductor device structures with substrate biasing, methods of forming a semiconductor device structure with substrate biasing, and methods of operating a semiconductor device structure with substrate biasing. A substrate contact is coupled to a portion of a bulk semiconductor substrate in a device region. The substrate contact is configured to be biased with a negative bias voltage. A field-effect transistor includes a semiconductor body in the device region of the bulk semiconductor substrate. The semiconductor body is electrically isolated from the portion of the bulk semiconductor substrate.

A semiconductor chip may have at least one p-channel field effect transistor (FET), at least one n-channel FET, a first and a second power supply terminal, wherein the at least one n-channel FET, if supplied with the upper supply potential at its gate, supplies the lower supply potential to the gate of the at least one p-channel FET and the at least one p-channel FET, if supplied with the lower supply potential at its gate, supplies the upper supply potential to the gate of the at least one n-channel FET, a precharge circuit to precharge the circuit to a first state, and a detection circuit configured to output an alarm signal if the circuit enters a second state.

An integrated circuit including a first cell and a second cell. The first cell includes a first plurality of active areas that extend in a first direction and a first plurality of gates that extend in a second direction that crosses the first direction, the first cell having first cell edges defined by breaks in the first plurality of gates. The second cell includes a second plurality of active areas that extend in the first direction and a second plurality of gates that extend in the second direction, the second cell having second cell edges defined by breaks in the second plurality of gates. Each of the second plurality of active areas is larger than each of the first plurality of active areas and the first cell is adjacent the second cell such that the first cell edges align with the second cell edges.

An integrated circuit (IC) structure includes a semiconductor substrate, a shallow trench isolation (STI) region, and a capacitor. The STI region is embedded in the semiconductor substrate. The capacitor includes first and second conductive stacks. The first conductive stack includes a first dummy gate strip disposed entirely within the STI region and a plurality of first metal dummy gate contacts landing on the first metal capacitor strip. The second conductive stack includes a second dummy gate strip disposed entirely within the STI region and extending in parallel with the first dummy gate strip, and a plurality of second dummy gate contacts landing on the second dummy gate strip, wherein the first conductive stack is electrically isolated from the second conductive stack.

A flexible electronic assembly includes an electronic component, a flexible substrate and a supporting layer. The flexible substrate includes a first surface coupled to the electronic component and a second surface opposite to the first surface. The supporting layer is coupled to the second surface, and the supporting layer includes a plurality of protrusions. In a plan view of the flexible electronic assembly, one of the plurality of protrusions includes at least a rounded corner.