Die (110) are attached to an interposer (420), and the interposer/die assembly is placed into a lid cavity (510). The lid (210) is attached to the top of the assembly, possibly to the encapsulant (474) at the top. The lid's legs (520) surround the cavity and extend down below the top surface of the interposer's substrate (420S), possibly to the level of the bottom surface of the substrate or lower. The legs (520) may or may not be attached to the interposer/die assembly. In fabrication, the interposer wafer (420SW) has trenches (478) which receive the lid's legs during the lid placement. The interposer wafer is later thinned to remove the interposer wafer portion below the legs and to dice the interposer wafer. The thinning process also exposes, on the bottom, conductive vias (450) passing through the interposer substrate. Other features are also provided.

A method for fabricating an electronic device, and an electronic device in a stacked configuration, includes a rear face of an integrated-circuit chip that is fixed to a front face of a support wafer. A protective wafer is located facing and at a distance from the front face of the chip, and an infused adhesive is interposed between the chip and the protective wafer and located on a zone of the front face of the chip outside a central region of this front face. The infused adhesive includes a curable adhesive and solid spacer elements infused in the curable adhesive. An obstruction barrier is arranged between the chip and the protective wafer and is disposed outside the central region of the front face of the chip. An encapsulation ring surrounds the chip, the protective wafer and the obstruction barrier.

A method of assembling a semi-hermetic semiconductor package includes bonding a semiconductor die having bond pads to a top side of a base region of a package substrate having vertical side walls that are hollow which define an inner open volume (gap) having an adhesive or thermoplastic material therein. There are a plurality of metal terminals providing top terminal contacts on the top side of the base region and bottom terminal contacts on a bottom side or below the base region. The bond pads are coupled to the top terminal contacts. A lid is placed which provides a top for the semiconductor package, where the lid extends to vertically oriented end protrusions so that the protrusions are positioned within the adhesive or thermoplastic material to secure the protrusions within the adhesive or thermoplastic material to provide a seal for the semiconductor package.

A semiconductor device includes: a substrate; a semiconductor element disposed on the substrate; a plurality of electrodes disposed on the substrate separately from one another and arranged so as to surround the semiconductor element in a plan view; a lid that cover the semiconductor element, the lid including an inner portion and a periphery portion that is outer than the inner portion in a plan view, the lid including a plurality of first protruding members that is provided separately from one another, the first protruding members being disposed in the inner portion; and conductive members disposed between the plurality of electrodes and the plurality of protruding members disposed in positions opposed to the plurality of electrodes respectively, the conductive members being joined to the plurality of electrodes and the plurality of protruding members respectively.

Provided is an electronic device including a cover made of a material which is transparent to at least UV, and black printing which is impervious to UV and is applied on a peripheral edge portion of the cover. A cover-bonding portion has an overflow prevention recess into which a UV-curing adhesive applied between the cover-bonding portion and the cover flows. Emitted UV is reflected by a surface of the overflow prevention recess and caused to reach space which is located inward relative to the black printing and between a backside of the peripheral edge portion of the cover and the cover-bonding portion, thereby curing the UV-curing adhesive.

According to one embodiment of the present invention, the light emitting device includes an LED element, a side wall which surrounds the LED element, a phosphor layer which is fixed to the side wall with an adhesive layer therebetween, and is positioned above the LED element, and a metal pad as a heat dissipating member. The side wall includes an insulating base which surrounds the LED element and a metal layer which is formed on a side surface at the LED element side of the base, and is in contact with the metal pad and the adhesive layer. The adhesive layer includes a resin layer that includes a resin containing particles which have higher thermal conductivity than the resin or a layer that includes solder.

A new packaging method for a wide range of MEMS for application on both the wafer and device scale. Titanium is used as the packaging material and both silicon and titanium MEMS devices are integrated on to a titanium substrate. A Nd:YAG pulsed laser is used to micro-weld the titanium cap to the substrate. A three-dimensional time dependent model of heat flow during laser beam welding is presented. The heat transfer and parametric design capabilities of COMSOL were employed for this purpose. Model calculations are compared and calibrated with experimental results of pulsed laser welds. The functionality and hermiticity of the proposed packaging was evaluated by packaging a self actuated Veeco Instrument AFM cantilever tip. The experimental measurements show that the resonance frequency and quality factor of the device stay the same before and after packaging and the applied technique has no effect on the device.

A semiconductor structure includes a circuit substrate, a semiconductor die, and a cover. The semiconductor die is disposed on the circuit substrate. The cover is disposed over the semiconductor die and over the circuit substrate. The cover comprises a lid portion and a support portion. The structure includes a first adhesive bonding the support portion to the circuit substrate and a second adhesive bonding the support portion and the lid portion.

According to various aspects, there may be provided a stiffener assembly. The stiffener assembly may include a primary stiffener and an auxiliary stiffener. The primary stiffener may include a first engagement arrangement, and the auxiliary stiffener may include a second engagement arrangement. The first engagement arrangement of the primary stiffener and the second engagement arrangement of the auxiliary stiffener may be configured to form a detachable joint with each other, thereby enabling the auxiliary stiffener to be releasably connected to the primary stiffener for reinforcing the primary stiffener.

A method for fabricating an electronic device includes fixing a rear face of an integrated-circuit chip to a front face of a support wafer. An infused adhesive is applied in the form of drops or segments that are separated from each other. A protective wafer is applied to the infused adhesive, and the infused adhesive is cured. The infused adhesive includes a curable adhesive and solid spacer elements infused in the curable adhesive. A closed intermediate peripheral ring is deposited on the integrated-circuit chip outside the cured infused adhesive, and an encapsulation block is formed such that it surrounds the chip, the protective wafer and the closed intermediate peripheral ring.