A method includes: providing a bottom layer; depositing a first seed layer over the bottom layer, the first seed layer having at least one of a tetragonal crystal phase and an orthorhombic crystal phase; depositing a dielectric layer over the bottom layer adjacent to the first seed layer, the dielectric layer including an amorphous crystal phase; depositing an upper layer over the dielectric layer; performing a thermal operation on the dielectric layer; and cooling the dielectric layer, wherein after the cooling the dielectric layer becomes a ferroelectric layer.

A method for protecting a power switch during turn-on includes sensing that a change in current through the power switch is in regulation, measuring a time the change in current through the power switch is in regulation, and comparing the time the change in current through the power switch is in regulation to a reference time. An over current signal, which can be used to disable the power switch, is generated if the time the change in current through the power switch is in excess of the reference time.

Semiconductor structures and methods for forming those semiconductor structures are disclosed. For example, a semiconductor structure with a p-type superlattice region, an i-type superlattice region, and an n-type superlattice region is disclosed. The semiconductor structure can have a polar crystal structure with a growth axis that is substantially parallel to a spontaneous polarization axis of the polar crystal structure. In some cases, there are no abrupt changes in polarisation at interfaces between each region. At least one of the p-type superlattice region, the i-type superlattice region and the n-type superlattice region can comprise a plurality of unit cells exhibiting a monotonic change in composition from a wider band gap (WBG) material to a narrower band gap (NBG) material or from a NBG material to a WBG material along the growth axis to induce p-type or n-type conductivity.

Provided is a method for manufacturing a semiconductor device whose electric characteristics are prevented from being varied and whose reliability is improved. In the method, an insulating film is formed over an oxide semiconductor film, a buffer film is formed over the insulating film, oxygen is added to the buffer film and the insulating film, a conductive film is formed over the buffer film to which oxygen is added, and an impurity element is added to the oxide semiconductor film using the conductive film as a mask. An insulating film containing hydrogen and overlapping with the oxide semiconductor film may be formed after the impurity element is added to the oxide semiconductor film.

Favorable electrical characteristics are provided to a semiconductor device, or a semiconductor device with high reliability is provided. A semiconductor device including a bottom-gate transistor with a metal oxide in a semiconductor layer includes a source region, a drain region, a first region, a second region, and a third region. The first region, the second region, and the third region are each sandwiched between the source region and the drain region along the channel length direction. The second region is sandwiched between the first region and the third region along the channel width direction, the first region and the third region each include the end portion of the metal oxide, and the length of the second region along the channel length direction is shorter than the length of the first region or the length of the third region along the channel length direction.

A zinc magnesium oxide material includes at least two composite thin film layers. An atomic ratio of Zn element to Mg element in each of the at least two composite thin film layers is different from an atomic ratio of Zn element to Mg element in each of at least one remaining composite thin film layer of the at least two composite thin film layers.

A semiconductor device (100) includes a TFT (10) supported on a substrate (11), wherein the TFT (10) includes a gate electrode (12g), a gate insulating layer (14) that covers the gate electrode (12g), and an oxide semiconductor layer (16) that is formed on the gate insulating layer (14). The oxide semiconductor layer 16 has a layered structure including a first oxide semiconductor layer (16a) in contact with the gate insulating layer (14) and a second oxide semiconductor layer (16b) layered on the first oxide semiconductor layer (16a). The first oxide semiconductor layer (16a) and the second oxide semiconductor layer (16b) both include In, Ga and Zn; an In atomic ratio of the first oxide semiconductor layer (16a) is greater than a Zn atomic ratio thereof, and an In atomic ratio of the second oxide semiconductor layer (16b) is smaller than a Zn atomic ratio thereof; and the oxide semiconductor layer (16) has a side surface of a forward tapered shape.

Light emitting diode (LED) devices comprise: a patterned substrate comprising a substrate body, a plurality of integral features protruding from the substrate body, and a base surface defined by spaces between the plurality of integral features; a selective layer comprising a dielectric material located on the surfaces of the integral features, wherein there is an absence of the selective layer on the base surface; and a III-nitride layer comprising a III-nitride material on the selective layer and the base surface.

Superlattices and methods of making them are disclosed herein. The superlattices are prepared by irradiating a sample to prepare an alternating superlattice of layers of a first material and a second material, wherein the ratio of the first deposition rate to the second deposition rate is between 1.0:2.0 and 2.0:1.0. The superlattice comprises a multiplicity of alternating layers, wherein the multiplicity of layers of the first material have a thickness between 0.1 nm and 50.0 nm or the multiplicity of layers of the second material have a thickness between 0.1 nm and 50.0.

Systems and methods for forming semiconductor layers, including oxide-based layers, are disclosed in which a material deposition system has a rotation mechanism that rotates a substrate around a center axis of a substrate deposition plane of the substrate. A material source that supplies a material to the substrate has i) an exit aperture with an exit aperture plane and ii) a predetermined material ejection spatial distribution from the exit aperture plane. The exit aperture is positioned at an orthogonal distance, a lateral distance, and a tilt angle relative to the center axis of the substrate. The system can be configured for either i) minimum values for the orthogonal distance and the lateral distance to achieve a desired layer deposition uniformity using a set tilt angle, or ii) the tilt angle to achieve the desired layer deposition uniformity using a set orthogonal distance and a set lateral distance.