A flexible board is disclosed. The flexible board comprises a flexible baseplate, a scattering structure that is arranged on at least one surface of the flexible baseplate, a buffer layer that is arranged at one side of the scattering structure far from the flexible baseplate, and an active layer that is arranged at one side of the buffer layer far from the flexible baseplate. The flexible board according to the present disclosure has an apparent advantage in protecting the active layer.

[PROBLEM] In accordance with one aspect of the present invention, to provide a tape and a sheet that make it possible to reduce cracking that would otherwise occur at the chip side face during dicing.

[SOLUTION MEANS] One aspect of the present invention relates to a sheet. The sheet comprises dicing film. The dicing film comprises a base layer and an adhesive layer disposed on the base layer. The sheet further comprises a semiconductor backside protective film disposed on the adhesive layer. Shear adhesive strength at 25° C. of the semiconductor backside protective film with respect to a silicon chip is not less than 1.7 kgf/mm.sup.2.

A stackable semiconductor package and manufacturing method thereof are provided. The stackable semiconductor package includes carrier, first RDL, encapsulation layer, vertical interposers, second RDL, and chip. The carrier has first surface in which the first RDL and the encapsulation layer are formed thereon. The first RDL includes first pads and second pads. The encapsulation layer covers the first RDL and has outer surface. The vertical interposers are disposed in the encapsulation layer to electrically connect with the first RDL. The second RDL is formed on the outer surface to electrically connect with the vertical interposers. The carrier includes terminal holes and chip-accommodating hole. The terminal holes correspondingly expose the second pads. The chip-accommodating hole exposes the first pads. The chip is mounted on the encapsulation layer through the chip-accommodating hole to electrically connect with the first pads.

An electronic device structure and a method for making an electronic device. As non-limiting examples, various aspects of this disclosure provide a method of manufacturing an electronic device that comprises the utilization of a carrier assisted substrate, and an electronic device manufactured thereby.

Some example forms relate to a stiffener tape for a wafer. The stiffener tape includes a mounting tape and a stiffener removably attached to the mounting tape. The stiffener tape further includes a die attach film attached to the stiffener. Other example forms relate to an electronic assembly that includes a wafer and a stiffener tape attached to the wafer. The stiffener tape includes a die attach film mounted to the wafer. A stiffener is attached to the die attach film and a mounting tape is removably attached to the stiffener. Still other example forms relate to a method that includes forming a stiffener tape which includes a mounting tape, a stiffener removably attached to the mounting tape and a die attach film attached to the stiffener.

The invention relates to a method for connecting a power semi-conductor chip having upper-sided potential surfaces to thick wires or strips, consisting of the following steps: Providing a metal molded body corresponding to the shape of the upper-sided potential surfaces, applying a connecting layer to the upper-sided potential surfaces or to the metal molded bodies, and applying the metal molded bodies and adding a material fit, electrically conductive compound to the potential surfaces prior to the joining of the thick wire bonds to the non-added upper side of the molded body.

A dicing sheet with a protective film forming layer has a substrate film, an adhesive layer, and a protective film forming layer, and at a minimum, the adhesive layer is formed in an area surrounding the protective film forming layer in a planar view, and the substrate film has the following characteristics (a)-(c): (a) the melting point either exceeds 130° C. or the film has no melting point; (b) the thermal contraction rate under conditions of heating at 130° C. for two hours is from −5 to +5%, and (c) the degree of elongation-to-break in the MD direction and the CD direction is at least 100%, and the stress at 25% is no more than 100 MPa.

An electronic device and a method of making an electronic device. As non-limiting examples, various aspects of this disclosure provide methods of making an electronic device, and electronic devices made thereby, that comprise forming first and second encapsulating materials, followed by further processing and the removal of the entire second encapsulating material.

Provided is a thermal type airflow volume meter improving measurement accuracy, a method for manufacturing the same, and an adhesive sheet for use therein, the adhesive sheet divided into at least two or more per adherend and having a thickness of approximately 0.1 mm or less is divided to correspond to a shape of the adherend and generates or increases adhesion or stickiness by external energy.

A method for manufacturing a semiconductor device includes: providing a carrier wafer and a silicon carbide wafer; bonding a first side of the silicon carbide wafer to the carrier wafer; splitting the silicon carbide wafer bonded to the carrier wafer into a silicon carbide layer thinner than the silicon carbide wafer and a residual silicon carbide wafer, the silicon carbide layer remaining bonded to the carrier wafer during the splitting; and forming a graphene material on the silicon carbide layer.