Abstract: An HFET includes a first and second semiconductor material. A first composite passivation layer includes a first insulation layer and a first passivation layer, and the first passivation layer is disposed between the first insulation layer and the second semiconductor material. The HFET includes a second passivation layer, where the first insulation layer is disposed between the first passivation layer and the second passivation layer. A gate dielectric is disposed between the second semiconductor material and the first passivation layer. A source electrode and a drain electrode are coupled to the second semiconductor material, and a gate electrode is disposed laterally between the source electrode and the drain electrode. A first gate field plate is disposed between the first passivation layer and the second passivation layer and electrically connected to the gate electrode, and a second gate field plate is disposed above first gate field plate.

Abstract: A high-voltage field effect transistor a heterojunction is disposed between the first and second semiconductor material. A first composite passivation layer includes a first insulation layer and a first passivation layer, and a second composite passivation layer includes a second insulation layer and a second passivation layer. The first insulation layer is disposed between the first passivation layer and the second passivation layer, and the second passivation layer is disposed between the first insulation layer and the second insulation layer. A gate dielectric disposed between the second semiconductor material and the first passivation layer. A gate electrode is disposed above the gate dielectric. A first gate field plate is disposed between the first passivation layer and the second passivation layer. A source electrode and a drain electrode are coupled to the second semiconductor material.

Abstract: A high-voltage field effect transistor a heterojunction is disposed between the first and second semiconductor material. A first composite passivation layer includes a first insulation layer and a first passivation layer, and a second composite passivation layer includes a second insulation layer and a second passivation layer. The first insulation layer is disposed between the first passivation layer and the second passivation layer, and the second passivation layer is disposed between the first insulation layer and the second insulation layer. A gate dielectric disposed between the second semiconductor material and the first passivation layer. A gate electrode is disposed above the gate dielectric. A first gate field plate is disposed between the first passivation layer and the second passivation layer. A source electrode and a drain electrode are coupled to the second semiconductor material.

Abstract: The present invention discloses a test structure and a method for judging the de-embedding accuracy of RF devices, which comprises testing the S parameters of a target device test structure, an introduced device test structure and an auxiliary test structure, respectively. Then calculating de-embedding S parameters of the target device test structure and the introduced device test structure according to the above-tested results, respectively. Finally, calculating performance parameters of the target device test structure according to the above-calculated de-embedding S parameters. So, the accuracy of the de-embedding method is determined by comparing the consistency of the performance parameters. The present invention can directly judge the de-embedding accuracy and the applicable frequency range of a given de-embedding method by analyzing the testing data. Further, the using of the parallel test structure and the cascade test structure together can increase the reliability of the judgment results.

Abstract: A high-voltage field effect transistor (HFET) includes a first semiconductor material, a second semiconductor material, and a heterojunction. The heterojunction is disposed between the first semiconductor material and the second semiconductor material. The HFET also includes a plurality of composite passivation layers, where a first composite passivation layer includes a first insulation layer and a first passivation layer, and a second composite passivation layer includes a second insulation layer and a second passivation layer. A gate dielectric is disposed between the first passivation layer and the second semiconductor material. A gate electrode is disposed between the gate dielectric and the first passivation layer. A first gate field plate is disposed between the first passivation layer and the second passivation layer. A source electrode and a drain electrode are coupled to the second semiconductor material, and a source field plate is coupled to the source electrode.

Abstract: High-electron-mobility transistors that include field plates are described. In a first implementation, a HEMT includes a first and a second semiconductor material disposed to form a heterojunction at which a two-dimensional electron gas arises and source, a drain, and gate electrodes. The gate electrode is disposed to regulate conduction in the heterojunction between the source electrode and the drain electrode. The gate has a drain-side edge. A gate-connected field plate is disposed above a drain-side edge of the gate electrode and extends laterally toward the drain. A second field plate is disposed above a drain-side edge of the gate-connected field plate and extends laterally toward the drain.

Abstract: A GaN HFET includes a silicon substrate with an Al2O3 layer above the silicon substrate. The Al2O3 layer has voids formed therein. A plurality of alternating GaN and AlN layers are above the Al2O3 layer. The GaN and AlN layers are under continuous compressive stress.

Abstract: High-electron-mobility transistors that include field plates are described. In a first implementation, a HEMT includes a first and a second semiconductor material disposed to form a heterojunction at which a two-dimensional electron gas arises and source, a drain, and gate electrodes. The gate electrode is disposed to regulate conduction in the heterojunction between the source electrode and the drain electrode. The gate has a drain-side edge. A gate-connected field plate is disposed above a drain-side edge of the gate electrode and extends laterally toward the drain. A second field plate is disposed above a drain-side edge of the gate-connected field plate and extends laterally toward the drain.

Abstract: A method of fabricating a multi-layer structure for a power transistor device includes performing, within a reaction chamber, a nitrogen plasma strike, resulting in the formation of a nitride layer directly on a nitride-based active semiconductor layer. A top surface of the nitride layer is then exposed to a second source. A subsequent nitrogen-oxygen plasma strike results in the formation of an oxy-nitride layer directly on the nitride layer. The nitride layer comprises a passivation layer and the oxy-nitride layer comprises a gate dielectric of the power transistor device.

Abstract: High-electron-mobility transistors that include field plates are described. In a first implementation, a HEMT includes a first and a second semiconductor material disposed to form a heterojunction at which a two-dimensional electron gas arises and source, a drain, and gate electrodes. The gate electrode is disposed to regulate conduction in the heterojunction between the source electrode and the drain electrode. The gate has a drain-side edge. A gate-connected field plate is disposed above a drain-side edge of the gate electrode and extends laterally toward the drain. A second field plate is disposed above a drain-side edge of the gate-connected field plate and extends laterally toward the drain.

Abstract: A GaN HFET includes a silicon substrate with an Al2O3 layer above the silicon substrate. The Al2O3 layer has voids formed therein. A plurality of alternating GaN and AlN layers are above the Al2O3 layer. The GaN and AlN layers are under continuous compressive stress.

Abstract: Generating a screenshot is disclosed, including: receiving a screenshot command from an application, wherein the screenshot command includes an application scenario parameter corresponding to the application; generating a screenshot object based at least in part on a screenshot class corresponding to the application scenario parameter; generating a screenshot from content displayed by the application using the screenshot object; and sending the screenshot to the application to be displayed.

Abstract: Substrates of GaN over silicon suitable for forming electronics devices such as heterostructure field effect transistors (HFETs), and methods of making the substrates, are disclosed. Voids in a crystalline Al2O3 film on a top surface of a silicon wafer are formed. The top surface of the silicon wafer is along the <111> silicon crystal orientation. A plurality of laminate layers is deposited over the voids and the Al2O3 film. Each laminate layer includes an AlN film and a GaN film. A transistor or other device may be formed in the top GaN film.

Abstract: Substrates of GaN over silicon suitable for forming electronics devices such as heterostructure field effect transistors (HFETs), and methods of making the substrates, are disclosed. Voids in a crystalline Al2O3 film on a top surface of a silicon wafer are formed. The top surface of the silicon wafer is along the <111> silicon crystal orientation. A plurality of laminate layers is deposited over the voids and the Al2O3 film. Each laminate layer includes an AlN film and a GaN film. A transistor or other device may be formed in the top GaN film.

Abstract: A FET includes a first and second set of finger arrays that each include a source, gate and drain. A first source pad is electrically coupled to source electrodes in the first set of finger arrays. A second source pad is electrically coupled to the source electrodes in the second set of finger arrays. A common drain pad is electrically coupled to drain electrodes in the first and second set of finger arrays. A first gate pad is electrically coupled to gate electrodes in the first set of finger arrays. A second gate pad is electrically coupled to gate electrodes in the second set of finger arrays. A substrate is also provided on which are disposed the first and second set of finger arrays, the first and second source pads, the common drain pad, and the first and second gate pads.

Abstract: A method of fabricating a multi-layer structure for a power transistor device includes performing, within a reaction chamber, a nitrogen plasma strike, resulting in the formation of a nitride layer directly on a nitride-based active semiconductor layer. A top surface of the nitride layer is then exposed to a second source. A subsequent nitrogen-oxygen plasma strike results in the formation of an oxy-nitride layer directly on the nitride layer. The nitride layer comprises a passivation layer and the oxy-nitride layer comprises a gate dielectric of the power transistor device.

Abstract: Substrates of GaN over silicon suitable for forming electronics devices such as heterostructure field effect transistors (HFETs), and methods of making the substrates, are disclosed. Voids in a crystalline Al2O3 film on a top surface of a silicon wafer are formed. The top surface of the silicon wafer is along the <111> silicon crystal orientation. A plurality of laminate layers is deposited over the voids and the Al2O3 film. Each laminate layer includes an AN film and a GaN film. A transistor or other device may be formed in the top GaN film.

Abstract: A heterostructure semiconductor device includes a first active layer and a second active layer disposed on the first active layer. A two-dimensional electron gas layer is formed between the first and second active layers. A first gate dielectric layer is disposed on the second active layer. A second gate dielectric layer is disposed on the first gate dielectric layer. A passivation layer is disposed over the second gate dielectric layer. A gate extends through the passivation layer to the second gate dielectric layer. First and second ohmic contacts electrically connect to the second active layer. The first and second ohmic contacts are laterally spaced-apart, with the gate being disposed between the first and second ohmic contacts.

Abstract: A method of fabricating a multi-layer structure for a power transistor device includes performing, within a reaction chamber, a nitrogen plasma strike, resulting in the formation of a nitride layer directly on a nitride-based active semiconductor layer. A top surface of the nitride layer is then exposed to a second source. A subsequent nitrogen-oxygen plasma strike results in the formation of an oxy-nitride layer directly on the nitride layer. The nitride layer comprises a passivation layer and the oxy-nitride layer comprises a gate dielectric of the power transistor device.

Abstract: Methods and apparatuses are disclosed for providing heterostructure field effect transistors (HFETs) with high-quality gate dielectric and field plate dielectric. The gate dielectric and field plate dielectric are in situ deposited on a semiconductor surface. The location of the gate electrode may be defined by etching a first pattern in the field plate dielectric and using the gate dielectric as an etch-stop. Alternatively, an additional etch-stop layer may be in situ deposited between the gate dielectric and the field plate dielectric. After etching the first pattern, a conductive material may be deposited and patterned to define the gate electrode. Source and drain electrodes that electrically contact the semiconductor surface are formed on opposite sides of the gate electrode.