A monolithic integration of enhancement mode (E-mode) and depletion mode (D-mode) field effect transistors (FETs) comprises a compound semiconductor substrate overlaid by an epitaxial structure overlaid by source and drain electrodes. The epitaxial structure includes from bottom to top sequentially a buffer layer, a channel layer, a Schottky barrier layer, a first etch stop layer, and a first cap layer. The respective first gate metal layers of the D-mode and E-mode FET are in contact with the first etch stop layer. The D-mode and E-mode gate-sinking regions are beneath the respective first gate metal layers of the D-mode and E-mode gate electrode at least within the first etch stop layer. The first gate metal layer material of the D-mode is the same as that of the E-mode, where the first gate metal layer thickness of the E-mode is greater than that of the D-mode.

Roughly described, a heterojunction field effect transistor device includes a first piezoelectric layer supporting a channel region, a second piezoelectric layer over the first, and a source and drain. A dielectric layer over the second piezoelectric layer electrically separates the source and drain, and has a plurality of segments, two of them separated by a first gap. A first gate has a first tine, the first tine within the first gap, the first gap having a length of less than about 200 nm. In the first piezoelectric layer immediately beneath the second piezoelectric layer, directly beneath the first gap, stress in the dielectric layer creates a piezoelectric charge of at least about 1×10.sup.11 per cm.sup.2 of electronic charge. The first gate controls a normally off segment of the channel region. A second gate, having a length of at least 500 nm, controls a normally on segment of the channel region.

A semiconductor apparatus with fake functionality includes a logic device and at least one fake device. The logic device is formed on a substrate and turned on by a bias voltage. The fake device is also formed on the substrate. The fake device cannot be turned on by the same bias voltage applied on the logic device.

A semiconductor structure and a method for forming a semiconductor structure are provided. The semiconductor structure includes a substrate, a gate electrode, a gate dielectric layer, first protection structures, a second protection structure and an insulating layer. The gate electrode is disposed within the substrate. The gate dielectric layer is disposed within the substrate and laterally surrounds the gate electrode. The first protection structures are disposed over the gate electrode. The second protection structure is disposed over the gate dielectric layer. The insulating layer is between the second protection structure and the gate dielectric layer.

An erasable programmable non-volatile memory includes a first transistor, a second transistor, an erase gate region and a metal layer. The first transistor includes a select gate, a first doped region and a second doped region. The select gate is connected with a word line. The first doped region is connected with a source line. The second transistor includes the second doped region, a third doped region and a floating gate. The third doped region is connected with a bit line. The erase gate region is connected with an erase line. The floating gate is extended over the erase gate region and located near the erase gate region. The metal layer is disposed over the floating gate and connected with the bit line.

A random number generator device has at least at least a memory unit, a voltage generator, and a control circuit. Each memory unit has two memory cells, one of the two memory cells is coupled to a bias line and a first bit line, and another of the two memory cells is coupled to the bias line and a second bit line. The voltage generator provides the two memory cells a bias voltage, a first bit line voltage and a second bit line voltage via the bias line, the first bit line and the second bit line respectively. The control circuit shorts the first bit line and the second bit line to program the two memory cells simultaneously during a programming period and generates a random number bit according the statuses of the two memory cells during a reading period.

An electronic device can include a low-side HEMT including a segmented gate electrode; and a high-side HEMT coupled to the low-side HEMT, wherein the low-side and high voltage HEMTs are integrated within a same semiconductor die. In another aspect, an electronic device can include a source electrode; a low-side HEMT; a high-side HEMT coupled to the low-side HEMT; and a resistive element. In an embodiment, the resistive element can be coupled to the source electrode and a gate electrode of the high voltage HEMT, and in another embodiment, the resistive element can be coupled to the source electrode and a drain of the low-side HEMT. A process of forming an electronic device can include forming a channel layer over a substrate; and forming a gate electrode over the channel layer. The gate electrode can be a segmented gate electrode of a HEMT.

A semiconductor device includes a semiconductor layer having a first doped region, a second doped region, and a third doped region. Each of the regions has the same dopant type. The first doped region extends further into a thickness of the semiconductor layer than the second or third doped regions, and the third doped region provides a conductive pathway between the first doped region and the second doped region. The semiconductor device also includes a first transistor and a second transistor. The first doped region is beneath the first transistor and the second doped region is beneath the second transistor. By using a commonly doped well region that includes each of the first, second, and third doped regions, at least the first and second transistors can be integrated closer together which lowers the overall device footprint. The transistors may be FETs, or other transistor technology.

The disclosure relates to a III-nitride power semiconductor based heterojunction device including a low voltage terminal, a high voltage terminal, a control terminal and an active heterojunction transistor formed on a substrate, and further including the following monolithically integrated components: voltage clamp circuit configured to limit a maximum potential that can be applied to the internal gate terminal, an on-state circuit configured to control the internal gate terminal of the active heterojunction transistor during an on-state operation, a turn-off circuit configured to control the internal gate terminal of the active heterojunction transistor during a turn-off operation and during an off-state.

A semiconductor structure includes a bulk semiconductor substrate, an electrically insulating layer over the substrate, an active layer of semiconductor material over the electrically insulating layer and a transistor. The transistor includes an active region, a gate electrode region and an isolation junction region. The active region is provided in the active layer of semiconductor material and includes a source region, a channel region and a drain region. The gate electrode region is provided in the bulk semiconductor substrate and has a first type of doping. The isolation junction region is formed in the bulk semiconductor substrate and has a second type of doping opposite the first type of doping. The isolation junction region separates the gate electrode region from a portion of the bulk semiconductor substrate other than the gate electrode region that has the first type of doping.