Abstract: A semiconductor device includes a semiconductor layer that has a main surface, an electrode pad that is formed on the main surface, a rewiring that has a first wiring surface connected to the electrode pad and a second wiring surface positioned on a side opposite to the first wiring surface and being roughened, the rewiring being formed on the main surface such as to be drawn out to a region outside the electrode pad, and a resin that covers the second wiring surface on the main surface and that seals the rewiring.

Abstract: A chip structure is provided. The chip structure includes a substrate. The chip structure includes an interconnect layer over the substrate. The chip structure includes a conductive pad over the interconnect layer. The chip structure includes a conductive bump over the conductive pad. The conductive bump has a first portion, a second portion, and a neck portion between the first portion and the second portion. The first portion is between the neck portion and the conductive pad. The neck portion is narrower than the first portion and narrower than the second portion.

Abstract: The present invention provides a highly reliable solder joint, the solder joint including a solder joint layer having a melted solder material containing Sn as a main component and further containing Ag and/or Sb and/or Cu; and a joined body including a Ni—P—Cu plating layer on a surface in contact with the solder joint layer, wherein the Ni—P—Cu plating layer contains Ni as a main component and contains 0.5% by mass or greater and 8% by mass or less of Cu and 3% by mass or greater and 10% by mass or less of P, the Ni—P—Cu plating layer has a microcrystalline layer at an interface with the solder joint layer, and the microcrystalline layer includes a phase containing microcrystals of a NiCuP ternary alloy, a phase containing microcrystals of (Ni,Cu)3P, and a phase containing microcrystals of Ni3P.

Abstract: In a semiconductor device, a substrate has a main surface. A first semiconductor chip has a first front surface and a first back surface, and is mounted on the main surface via a plurality of bump electrodes. A first spacer has a second front surface and a second back surface that is mounted on the main surface. A height of the second front surface from the main surface is within a range between a highest height and a lowest height of the first back surface from the main surface. A second spacer has a third front surface and a third back surface that is mounted on the main surface. A height of the third front surface from the main surface is within the range between the highest height and the lowest height of the first back surface from the main surface.

Abstract: A die including a first contact with a first shape (e.g., ring-shaped) and a second contact with a second shape (e.g., cylindrical shaped) different from the first shape. The first contact has an opening that extends through a central region of a surface of the first contact. A first solder portion is coupled to the surface of the first contact and the first solder portion has the first shape. A second solder portion is coupled to a surface of the second contact and the second solder portion has the second shape. The first solder portion and the second solder portion both have respective points furthest away from a substrate of the die. These respective points of the first solder portion and the second solder portion are co-planar with each other such that a standoff height of the die remains consistent when coupled to a PCB or an electronic component.

Abstract: A semiconductor device and formation thereof. The semiconductor device includes a first semiconductor structure, a second semiconductor structure, and a plurality of pillars interconnecting the first semiconductor structure and the second semiconductor structure. The plurality of pillars include a first solder layer and a second solder layer, wherein the first solder layer has a higher melting point than the second solder layer.

Abstract: A solid-state imaging device to be provided includes a first semiconductor device including a semiconductor layer in which a photoelectric conversion unit that photoelectrically converts incident light and a penetrating via are provided, a first connecting portion and a second connecting portion on the surface side of the semiconductor layer on the side that receives the light, and a connecting wiring line that connects the first connecting portion, the second connecting portion, and the penetrating via. The solid-state imaging device further includes a second semiconductor device that is mounted on the first semiconductor device with the first connecting portion. The solid-state imaging device is connected to an external terminal by the second connecting portion.

Abstract: In a described example, an apparatus includes: a semiconductor die having bond pads on a device side surface, the semiconductor die having a ground plane spaced from the bond pads by a spacing distance. The bond pads have an upper surface for receiving a ball bond, and an outer boundary, the bond pads having vertical sides extending from the upper surface to a bottom surface, the bottom surface formed over the device side surface of the semiconductor die. A protective overcoat (PO) is formed overlying the ground plane and overlying the vertical sides of the bond pads, and overlying a portion of the upper surface of the bond pads, and having an opening exposing the remaining portion of the upper surface of the bond pads, the protective overcoat having a dielectric constant of less than 3.8.

Abstract: In a described example, an apparatus includes: a semiconductor die having a device side surface; bond pads on the semiconductor die on the device side surface; post connects having a proximate end on the bond pads and extending from the bond pads to a distal end, the diameter of the post connects at the proximate end being the same as the diameter of the post connects at the distal end; polyimide material covering sides of the post connects and covering at least a portion of the bond pads; and solder bumps on the distal end of the post connects.

Abstract: Provided here are: an electrically-conductive semiconductor substrate with which a semiconductor circuit is formed; an insulating film deposited on a major surface of the electrically-conductive semi-conductor substrate; and a bonding pad having fixing parts fixed onto the insulating film, side wall parts rising up from the fixing parts, and an electrode part connected to the side wall parts and disposed in parallel to the major surface; wherein the electrode part forms, together with the insulating film, a gap region therebetween, and portions of the electrode part where it is connected to the side wall parts are configured to have at least one of: a positional relationship in which they sandwich therebetween a central portion of the electrode part in its bonding region to be bonded to a bonding wire; and a positional relationship in which they surround the central portion.

Abstract: A printed wiring-board island relieves added complexity to a printed circuit board. The printed wiring-board island creates an island form factor in the printed circuit board. Coupling of a semiconductive device package to the printed wiring-board island includes a ball-grid array. The ball-grid array can at least partially penetrate the printed wiring-board island.

Abstract: A 3D memory device includes a memory stack including a memory block. The memory block includes a first memory array structure, a staircase structure, a second memory array structure in a first lateral direction, and a plurality of strings in a second lateral direction. The staircase structure includes a staircase zone and a bridge structure adjacent to the staircase zone. The 3D memory device also includes a SSG cut structure. The SSG cut structure includes a first portion between a first string and a second string and extends in the bridge structure in the first lateral direction. The staircase zone includes a first staircase conductively connected to first memory cells in the first string through the bridge structure and a second staircase conductively connected to second memory cells in the second string in the first memory array structure through the bridge structure.

Abstract: A display device having a function of sensing light is provided. A highly convenient display device is provided. The display device includes a first substrate, a second substrate, a light-receiving element, a transistor, and a light-emitting element in a display portion. The light-receiving element, the transistor, and the light-emitting element are each positioned between the first substrate and the second substrate. The light-receiving element is positioned closer to the first substrate than the transistor is. The light-emitting element is positioned closer to the second substrate than the transistor is. The light-receiving element includes a layer containing an organic compound. The transistor is electrically connected to the light-emitting element. The display device preferably further includes a lens and light transmitted through the lens preferably enters the light-receiving element.

Abstract: A microelectronic component comprises a substrate having at least one bond pad on a surface thereof and a metal pillar structure on the at least one bond pad, the metal pillar structure comprising a metal pillar on the at least one bond pad and a solder material having a portion within a reservoir within the metal pillar and another portion protruding from an end of the metal pillar opposite the at least one bond pad. Methods for forming the metal pillar structures, metal pillar structures, assemblies and systems incorporating the metal pillar structures are also disclosed.

Abstract: A cryogenic under bump metallization (UBM) stack includes an adhesion and barrier layer and a conductive pillar on the adhesion and barrier layer. The conductive pillar functions as a solder wetting layer of the UBM stack and has a thickness. An indium superconducting solder bump is on the conductive pillar. The thickness of the conductive pillar is sufficient to prevent intermetallic regions, which form in the conductive pillar at room temperature due to interdiffusion, from extending through the entire thickness of the conductive pillar to maintain the structural integrity of the UBM stack. The indium (In) solder bump may be formed through electroplating, with the conductive pillar being copper (Cu) and the adhesion and barrier layer being titanium tungsten (TiW) and a thin seed layer of copper (Cu), or a layer of titanium (Ti).

Abstract: Methods for forming under-bump metallurgy (UBM) structures having different surface profiles and semiconductor devices formed by the same are disclosed. In an embodiment, a semiconductor device includes a first redistribution line and a second redistribution line over a semiconductor substrate; a first passivation layer over the first redistribution line and the second redistribution line; a first under-bump metallurgy (UBM) structure over and electrically coupled to the first redistribution line, the first UBM structure extending through the first passivation layer, a top surface of the first UBM structure being concave; and a second UBM structure over and electrically coupled to the second redistribution line, the second UBM structure extending through the first passivation layer, a top surface of the second UBM structure being flat or convex.

Abstract: Semiconductor devices and methods of forming the same are provided. A semiconductor device according to the present disclosure includes a first semiconductor channel member and a second semiconductor channel member over the first semiconductor channel member and a porous dielectric feature that includes silicon and nitrogen. In the semiconductor device, the porous dielectric feature is sandwiched between the first and second semiconductor channel members and a density of the porous dielectric feature is smaller than a density of silicon nitride.

Abstract: The disclosed semiconductor structure includes a semiconductor substrate, a metal pad, a bump, a first solder layer, a barrier layer, and a second solder layer. The metal pad is disposed on the semiconductor substrate; the bump is arranged on the metal pad; the barrier layer is configured on the side of the bump away from the metal pad. The barrier layer includes a first surface and a second surface. The first solder layer is arranged between the bump and the first surface of the barrier layer. The second solder layer is configured on the second surface of the barrier layer. Since the first solder layer and the second solder layer are formed by reflowed and melt solder at a high temperature and can be stretched, the height of the second solder can be adjusted automatically, which reduces the non-wetting problem caused by the package substrate deformation after reflow.

Abstract: A first photoelectric conversion element according to an embodiment of the present disclosure incudes: a first electrode; a second electrode disposed to be opposed to the first electrode; and a photoelectric conversion layer provided between the first electrode and the second electrode and including a chromophore, fullerene or a fullerene derivative, and a hole-transporting material, in which the chromophore and the fullerene or the fullerene derivative are bonded to each other at least partially via a crosslinking group in the photoelectric conversion layer.

Abstract: A method for assembling components includes assembling a first component including solder bumps with a second component including connectors. The assembly of the components is preceded by pre-treating the first and second components wherein the solder bumps are contacted with a pre-treatment liquid configured to at least partially remove an oxide layer initially present on the solder. The pre-treatment liquid is an aqueous solution containing carboxylic acids or polycarboxylic acids. The assembly of the components is carried out after the pre-treatment in the absence of liquid or gas flux.