A method of fabricating a semiconductor device is provided. The method includes providing a die stacking unit that includes a plurality of dies stacked on each other, and a plurality of conductive joints connected between each two adjacent dies. The method includes providing a plurality of dummy micro bumps and dummy pads between the two adjacent dies and between the conductive joints. The dummy micro bumps and the dummy pads are connected to one of the two adjacent dies but not to the other, and the dummy micro bumps are formed on some of the dummy pads but not on all of the dummy pads. The method includes dispensing an underfill material into gaps between the plurality of dies, the conductive joints, the dummy micro bumps, and the dummy pads.

A curable resin or adhesive composition includes at least one monomer, a photoinitiator capable of initiating polymerization of the monomer when exposed to light, and at least one energy converting material, preferably a phosphor, capable of producing light when exposed to radiation (typically X-rays). The material is particularly suitable for bonding components at ambient temperature in situations where the bond joint is not accessible to an external light source. An associated method includes: placing a polymerizable adhesive composition, including a photoinitiator and energy converting material, such as a down-converting phosphor, in contact with at least two components to be bonded to form an assembly; and, irradiating the assembly with radiation at a first wavelength, capable of conversion (down-conversion by the phosphor) to a second wavelength capable of activating the photoinitiator, to prepare items such as inkjet cartridges, wafer-to-wafer assemblies, semiconductors, integrated circuits, and the like.

An electronic component includes: a plurality of first substrates that are connected in series along a coupling path; and a second substrate that is connected with one first substrate of the plurality of first substrates. The second substrate is in line with the one first substrate along a connection direction intersecting the coupling path, and the plurality of first substrates and the second substrate are configured to be foldable such that they are stacked.

A semiconductor structure includes a substrate including a conductive pillar protruded from the substrate; and a first chip disposed over the substrate and including a first via extended through the first chip, wherein the conductive pillar is extended from the substrate through the first chip and is partially disposed within the first via.

A semiconductor device has a first substrate including an element region, a peripheral region that surrounds the element region, a first insulator with a first recess portion in the peripheral region, a first metal layer in the element region, and a first conductor in the peripheral region to surround the element region. A second substrate has an element region, a peripheral region that surrounds the element region, a second insulator with a second recess portion that faces the first recess portion, a second metal layer in contact with the first metal layer, and a second conductor that surrounds the element region of the second substrate.

The present technology relates to a camera module and an electronic apparatus that can lower the risk of breakage. An imaging element has a light receiving surface to receive light, and is flip-chip mounted on a base. A joining material is joined to the optical back surface of the imaging element so that a space is formed between the joining material and a back-surface-side member provided on the side of the optical back surface on the opposite side of the imaging element from the light receiving surface. The present technology can be applied to camera modules and the like that capture images, for example.

A semiconductor device includes a silicon die having a metal material coating applied on one side, a lead frame having a mounting pad having an area smaller than an area of the silicon die, the silicon die being mounted on the lead frame via the mounting pad, and an etched area filled with a non-conductive mold compound on a side of the lead frame that comes into contact with an end of the silicon die along an edge of the silicon die. A volume of epoxy material is dispensed onto the lead frame along a length of the metal material coating to form a fillet weld on a side of the silicon die configured to adhere the silicon die to the lead frame and to prevent the metal material coating from coming into contact with the lead frame.

A semiconductor package includes: a first substrate including a first interconnection structure extending from a surface of the first substrate, the first interconnection structure including grains of a first size, a second substrate including: a second interconnection structure comprising grains of a second size, and a third interconnection structure disposed between the first interconnection structure and the second interconnection structure, the third interconnection structure including grains of a third size, a first sidewall inclined at a first angle to a reference plane and a second sidewall inclined at a second angle to the reference plane, wherein the first angle is different from the second angle, the first sidewall is disposed between the first substrate and the second sidewall, and the third size is smaller than both the first size and the second size.

A bonded assembly including: a first electronic component including a first substrate and a plurality of first electrodes disposed in a pressed area at a first height from a surface of the first substrate; a second electronic component including a second substrate and a plurality of second electrodes disposed at a second height from a surface of the second substrate, a second electrode overlapping with a corresponding first electrode to face the first electrode; a conductive bonding layer disposed between the first electrode and the second electrode overlapped with each other to bond the first electrode and the second electrode; and at least one spacer disposed between the first substrate and the second substrate to overlap the pressed area, the at least one spacer having a thickness that is greater than a value obtained by summing the first height and the second height.

An opto-electronic apparatus and a manufacturing method thereof are disclosed. The manufacturing method of the opto-electronic apparatus includes the following steps of: disposing a matrix circuit on a substrate, wherein the matrix circuit has a matrix circuit thickness between the highest point of the matrix circuit and the surface of the substrate; disposing a plurality of first protrusions above the substrate, wherein at least one of the first protrusions has a first protrusion thickness between the highest point of the first protrusion and the surface of the substrate, and the first protrusion thickness is greater than the matrix circuit thickness; and performing a transfer step for transferring a plurality of first opto-electronic units from a first carrier to the first protrusions and bonding the first protrusions to at least two of the first opto-electronic units with an adhesive material.