Electrolyte for a solid-state battery includes a body having grains of inorganic material sintered to one another, where the grains include lithium. The body is thin, has little porosity by volume, and has high ionic conductivity.

A bonded structure is disclosed. The bonded structure includes a first element and a second element that is bonded to the first element along a bonding interface. The bonding interface has an elongate conductive interface feature and a nonconductive interface feature. The bonded structure also includes an integrated device that is coupled to or formed with the first element or the second element. The elongate conductive interface feature has a recess through a portion of a thickness of the elongate conductive interface feature. A portion of the nonconductive interface feature is disposed in the recess.

A bonded structure is disclosed. The bonded structure includes a first element and a second element that is bonded to the first element along a bonding interface. The bonding interface has an elongate conductive interface feature and a nonconductive interface feature. The bonded structure also includes an integrated device that is coupled to or formed with the first element or the second element. The elongate conductive interface feature has a recess through a portion of a thickness of the elongate conductive interface feature. A portion of the nonconductive interface feature is disposed in the recess.

The semiconductor device includes a semiconductor element, a first lead, and a second lead. The semiconductor element has an element obverse surface and an element reverse surface spaced apart from each other in a thickness direction. The semiconductor element includes an electron transit layer disposed between the element obverse surface and the element reverse surface and formed of a nitride semiconductor, a first electrode disposed on the element obverse surface, and a second electrode disposed on the element reverse surface and electrically connected to the first electrode. The semiconductor element is mounted on the first lead, and the second electrode is joined to the first lead. The second lead is electrically connected to the first electrode. The semiconductor element is a transistor. The second lead is spaced apart from the first lead and is configured such that a main current to be subjected to switching flows therethrough.

Direct bonded stack structures for increased reliability and improved yields in microelectronics are provided. Structural features and stack configurations are provided for memory modules and 3DICs to reduce defects in vertically stacked dies. Example processes alleviate warpage stresses between a thicker top die and direct bonded dies beneath it, for example. An etched surface on the top die may relieve warpage stresses. An example stack may include a compliant layer between dies. Another stack configuration replaces the top die with a layer of molding material to circumvent warpage stresses. An array of cavities on a bonding surface can alleviate stress forces. One or more stress balancing layers may also be created on a side of the top die or between other dies to alleviate or counter warpage. Rounding of edges can prevent stresses and pressure forces from being destructively transmitted through die and substrate layers. These measures may be applied together or in combinations in a single package.

Implementations of a method of forming semiconductor packages may include: providing a wafer having a plurality of devices, etching one or more trenches on a first side of the wafer between each of the plurality of devices, applying a molding compound to the first side of the wafer to fill the one or more trenches; grinding a second side of the wafer to a desired thickness, and exposing the molding compound included in the one or more trenches. The method may include etching the second side of the wafer to expose a height of the molding compound forming one or more steps extending from the wafer, applying a back metallization to a second side of the wafer, and singulating the wafer at the one or more steps to form a plurality of semiconductor packages. The one or more steps may extend from a base of the back metallization.

A semiconductor device includes an N-type semiconductor substrate comprising silicon, an N-type low-concentration impurity layer that is in contact with the upper surface of the N-type semiconductor substrate, a metal layer that is in contact with the entire lower surface of the N-type semiconductor substrate and has a thickness of at least 20 m, and first and second vertical MOS transistors formed in the low-concentration impurity layer. The ratio of the thickness of the metal layer to the thickness of a semiconductor layer containing the N-type semiconductor substrate and the low-concentration impurity layer is greater than 0.27. The semiconductor device further includes a support comprising a ceramic material and bonded to the entire lower surface of the metal layer only via a bonding layer.

Provided is a light-emitting diode (LED) module, LED panel and LED screen. The LED module includes a composite layer, at least one LED chipset with an LED chip, at least one driver integrated circuit (IC); the composite layer includes a substrate arranged at the front side; the LED chip and the driver IC are installed at the front side of the composite layer, the cathode of the LED chip is connected to the driver IC by golden wire bonding; blind holes are arranged at the front side of the composite layer, the anode of the LED chip is connected to the positive electrode inside the composite layer through one of the blind holes; the wire coming from the VDD pin of the driver IC is connected to the positive electrode inside the composite layer through at least one of the blind holes; the wire coming from the GND pin of the driver IC is connected to the negative electrode inside the composite layer through one of the blind holes; the at least one driver IC is connected with each other through a signal line.

According to one aspect, there is proposed a method for assembling two integrated circuit wafers. The method includes removing by abrasion of a portion of an assembly face of a first wafer on a perimeter of the first wafer, and bonding the assembly face of the first wafer to an assembly face of a second integrated circuit wafer.

Embodiments disclosed herein include electronic packages. In an embodiment, an electronic package comprises a redistribution layer (RDL) having a conductive layer in a first dielectric layer, and a second dielectric layer over the conductive and first dielectric layers. The RDL comprises an extended portion having a first thickness that vertically extends from a bottom surface of the first dielectric layer to a topmost surface of the second dielectric layer. The electronic package comprises a die on the RDL, where the die has sidewall surfaces, a top surface, and a bottom surface that is opposite from the top surface, and an active region on the bottom surface of the die. The first thickness is greater than a second thickness of the RDL that vertically extends from the bottom surface of the first dielectric layer to the bottom surface of the die. The extended portion is over and around the sidewall surfaces.