The present disclosure provides a chip part. The chip part includes a substrate, a first external electrode, a second external electrode, a capacitor portion, a lower electrode, a capacitive film and an upper electrode. The first external electrode and the second external electrode are disposed on a first main surface of the substrate. The capacitor portion is disposed on the first main surface of the substrate. The lower electrode includes a first body portion and a first peripheral portion integrally drawn out around the capacitor portion from the first body portion. The capacitive film includes a second body portion disposed within the capacitor portion and a second peripheral portion integrally drawn out from the second body portion to the first peripheral portion. The upper electrode is disposed on the capacitive film.

The present disclosure provides a chip part. The chip part includes: a capacitor portion, including a plurality of wall portions separated from each other by a plurality of trenches formed on the first main surface and having a lengthwise direction; a substrate body, formed around the capacitor portion using a portion of the semiconductor substrate; a lower electrode, disposed using at least a portion of the semiconductor substrate including the wall portions; a capacitive film, disposed along top and side surfaces of the plurality of wall portions; and an upper electrode, disposed on the capacitive film.

Semiconductor dies including ultra-thin wafer backmetal systems, microelectronic devices containing such semiconductor dies, and associated fabrication methods are disclosed. In one embodiment, a method for processing a device wafer includes obtaining a device wafer having a wafer frontside and a wafer backside opposite the wafer frontside. A wafer-level gold-based ohmic bond layer, which has a first average grain size and which is predominately composed of gold, by weight, is sputter deposited onto the wafer backside. An electroplating process is utilized to deposit a wafer-level silicon ingress-resistant plated layer over the wafer-level Au-based ohmic bond layer, while imparting the plated layer with a second average grain size exceeding the first average grain size. The device wafer is singulated to separate the device wafer into a plurality of semiconductor die each having a die frontside, an Au-based ohmic bond layer, and a silicon ingress-resistant plated layer.

Semiconductor dies including ultra-thin wafer backmetal systems, microelectronic devices containing such semiconductor dies, and associated fabrication methods are disclosed. In one embodiment, a method for processing a device wafer includes obtaining a device wafer having a wafer frontside and a wafer backside opposite the wafer frontside. A wafer-level gold-based ohmic bond layer, which has a first average grain size and which is predominately composed of gold, by weight, is sputter deposited onto the wafer backside. An electroplating process is utilized to deposit a wafer-level silicon ingress-resistant plated layer over the wafer-level Au-based ohmic bond layer, while imparting the plated layer with a second average grain size exceeding the first average grain size. The device wafer is singulated to separate the device wafer into a plurality of semiconductor die each having a die frontside, an Au-based ohmic bond layer, and a silicon ingress-resistant plated layer.

A silver nano-twinned thin film structure and a method for forming the same are provided. A silver nano-twinned thin film structure, including: a substrate; an adhesive-lattice-buffer layer over the substrate; and a silver nano-twinned thin film over the adhesive-lattice-buffer layer, wherein the silver nano-twinned thin film comprises parallel-arranged twin boundaries, and a cross-section of the silver nano-twinned thin film reveals that 50% or more of all twin boundaries are parallel-arranged twin boundaries, wherein the parallel-arranged twin boundaries include Σ3 and Σ9 boundaries, wherein the Σ3 and Σ9 boundaries include 95% or more crystal orientation.

A silver nano-twinned thin film structure and a method for forming the same are provided. A silver nano-twinned thin film structure, including: a substrate; an adhesive-lattice-buffer layer over the substrate; and a silver nano-twinned thin film over the adhesive-lattice-buffer layer, wherein the silver nano-twinned thin film comprises parallel-arranged twin boundaries, and a cross-section of the silver nano-twinned thin film reveals that 50% or more of all twin boundaries are parallel-arranged twin boundaries, wherein the parallel-arranged twin boundaries include Σ3 and Σ9 boundaries, wherein the Σ3 and Σ9 boundaries include 95% or more crystal orientation.

A semiconductor die (“die”) employing repurposed seed layer for forming additional signal paths to a back end-of-line (BEOL) structure of the die, and related integrated circuit (IC) packages and fabrication methods. A seed layer is repurposed that was disposed adjacent the BEOL interconnect structure to couple an under bump metallization (UBM) interconnect without a coupled interconnect bump thus forming an unraised interconnect bump, to a UBM interconnect that has a raised interconnect bump. To couple the unraised interconnect bump to the raised interconnect bump, the seed layer is selectively removed during fabrication to leave a portion of the seed layer repurposed that couples the UBM interconnect that does not have an interconnect bump to the UBM interconnect that has a raised interconnect bump. Additional routing paths can be provided between raised interconnect bumps to the BEOL interconnect structure through coupling of UBM interconnects to an unraised interconnect bump.

A semiconductor device includes a silicon substrate, a first layer, a second layer, a barrier metal, and a gate pad. The first layer is formed of an oxide film provided on an upper surface of the silicon substrate. The second layer is a layer at least selectively having a projecting and recessed part on an upper surface of the first layer, the projecting and recessed part having a projection and recess deeper than a projection and recess occurring when the layer is formed in a planar shape. The barrier metal is formed on an upper surface of the second layer according to a shape of the projecting and recessed part. The gate pad is in close contact with the silicon substrate via the barrier metal.

A display device includes a base layer; a pixel circuit layer disposed on the base layer, the pixel circuit layer including a first transistor; and an insulating layer overlapping the first transistor; a first electrode disposed on the pixel circuit layer, the first electrode electrically connected to the first transistor via a contact hole of the insulating layer; a cover layer disposed on the first electrode, the cover layer overlapping at least a portion of the first electrode; a light emitting element including a first end and a second end electrically connected to the first electrode; a second electrode disposed on the light emitting element, the second electrode electrically connected to the second end of the light emitting element; and a third electrode disposed on the cover layer, the third electrode electrically contacting at least a portion of the first electrode.

Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a first die, having a first surface with first conductive contacts and an opposing second surface with second conductive contacts, in a first layer; a die attach film (DAF), at the first surface of the first die, including through-DAF vias (TDVs), wherein respective ones of the TDVs are electrically coupled to respective ones of the first conductive contacts; a conductive pillar in the first layer; and a second die, in a second layer on the first layer, wherein the second die is electrically coupled to the second conductive contacts on the second surface of the first die and electrically coupled to the conductive pillar.