An epoxy resin composition for encapsulating a semiconductor device and a semiconductor device encapsulated by the epoxy resin composition, the composition including a base resin; a filler; a colorant; and a thermochromic pigment, wherein a color of the thermochromic pigment is irreversibly changed when a temperature thereof exceeds a predetermined temperature.

A wafer manufacturing method for manufacturing a wafer from an ingot includes forming a peeling layer within the ingot by positioning a condensing point at a depth corresponding to the thickness of the wafer to be produced, and irradiating the ingot with a first laser beam, forming a character, a number, or a mark representing information regarding resistivity in or on the ingot by positioning a condensing point in a region in which devices are not to be formed and irradiating the ingot with a second laser beam, and dividing the ingot with the peeling layer as a starting point.

Structures that include an identification marking and fabrication methods for such structures. A chip is formed within a usable area of a wafer, and a marking region is formed on the wafer. The marking region is comprised of a conductor used to form a last metal layer of an interconnect structure for the chip. The identification marking is formed in the conductor of the marking region. After the identification marking is formed, a dielectric layer is deposited on the marking region. The dielectric layer on the marking region is planarized.

The present disclosure provides improved approaches for marking and individual tracking of solar cells. These approaches can be used to identify key manufacturing process steps requiring optimization and/or significant factors extending solar cell lifetime. The approaches described herein for marking and individual tracking of solar cells avoid or greatly minimize any negative impact on solar cell performance while improving quality control of solar cells across multiple manufacturing steps and throughout the entire solar cell lifecycle. Embodiments described herein include a solar cell comprising a substrate having a front side and a back side. The substrate comprises at least one diffusion region of a first polarity. A first set of conductive conduits in the first set is electrically coupled to at least one active diffusion region of a first polarity. The solar cell further comprises a marking above an inactive region of the substrate. The marking can provide information about a particular cell which can be read or scanned during cell manufacturing and/or in the field during the operational life of the cell.

The present invention relates to a film for semiconductor device production, which includes: a separator; and a plurality of adhesive layer-attached dicing tapes each including a dicing tape and an adhesive layer laminated on the dicing tape, which are laminated on the separator at a predetermined interval in such a manner that the adhesive layer attaches to the separator, in which the separator has a cut formed along the outer periphery of the dicing tape, and the depth of the cut is at most ⅔ of the thickness of the separator.

A semiconductor device includes a semiconductor substrate, an effective region formed as a conductive section on the semiconductor substrate, an ineffective region formed as a non-conductive section on the semiconductor substrate, a wiring metal formed in the effective region, a metal section provided on an upper surface of the wiring metal and exposed to an outside, an identifying mark provided on the upper surface of the wiring metal and exposed to the outside, the identifying mark being spaced apart from the metal section, and an insulating body provided on the upper surface of the wiring metal and exposed to the outside, the insulating body being adjacent to the metal section and the identifying mark.

A method of manufacturing a semiconductor package includes the following steps. A backside redistribution structure is formed, wherein the backside redistribution structure comprises a first dielectric layer, and a redistribution metal layer over the first dielectric layer and comprising a dummy pattern. A semiconductor device is provided over the backside redistribution structure, wherein an active surface of the semiconductor device faces away from the backside redistribution structure, the semiconductor device is electrically insulated from the dummy pattern and overlapped with the dummy pattern from a top view of the semiconductor package. A front side redistribution structure is formed over the semiconductor device, wherein the front side redistribution structure is electrically connected to the semiconductor device. A patterning process is performed on the first dielectric layer to form a marking pattern opening exposing a part of the dummy pattern.

A semiconductor device according to the present embodiment includes a wiring substrate having a wiring layer. A first semiconductor chip is provided above the wiring substrate. A metallic wire connects the first semiconductor chip and the wiring substrate to each other. A silicon chip is provided above the first semiconductor chip and covers above the metallic wire. A resin layer seals the first semiconductor chip and the silicon chip, and the metallic wire. The silicon chip is insulated from the wiring substrate.

An electronic semiconductor component with a housing structure and a cavity introduced into the housing structure is specified. The cavity comprises a base surface. Furthermore, the electronic semiconductor component comprises an auxiliary layer arranged on the base surface of the cavity and a marking penetrating the auxiliary layer at least as far as the base surface of the cavity. The marking comprises an optical contrast that depends on both an optical property of the housing structure and an optical property of the auxiliary layer. Furthermore, a method for producing an electronic semiconductor component is given.

The present disclosure relates to a semiconductor chip scale package including a semiconductor die. The semiconductor die has a first major surface opposing a second major surface, a plurality of side walls extending between the first major surface and second major surface, a plurality of electrical contacts arranged on the second major surface of the semiconductor die, and an insulating material disposed on the plurality of side walls and on the first major surface. The insulating material includes a machine readable identifier by which a semiconductor chip scale packaging type is identifiable by an identification apparatus that reads the machine readable identifier, and the machine readable identifier includes a colour component.