An adhesive bonding method that includes bonding a handling wafer to a front side surface of a device wafer with an adhesive comprising N-substituted maleimide copolymers. The device wafer may then be thinned from the backside surface of the device wafer while the device wafer is adhesively engaged to the handling wafer. The adhesive can then be removed by laser debonding, wherein the device wafer is separated from the handling wafer.

A yield in a separation process is improved. A separation apparatus which enables easy separation in a large-area substrate is provided. The separation apparatus has a function of dividing a process member into a first member and a second member and includes a support body supply unit, a support body hold unit, a transfer mechanism, a direction changing mechanism, and a structure body. The structure body bonds a support body to a surface of the first member. When at least part of the process member is located between the direction changing mechanism and the structure body or the pressure applying mechanism, the shortest distance between the direction changing mechanism and a first plane including the surface of the first member is longer than the shortest distance between the first plane and the structure body or the pressure applying mechanism.

Among other things a method including releasing a discrete component from an interim handle and depositing a discrete component on a handle substrate, attaching the handle substrate to the discrete component, and removing the handle substrate from the discrete component.

A bonding method is disclosed. The bonding method can include providing a first element having a device portion and a first nonconductive bonding material disposed over the device portion of the first element. The bonding method can include providing a second element that includes a carrier. The second element having a substrate and a second nonconductive bonding material disposed over the substrate of the second element. The bonding method can include depositing a release layer between the device portion and the first nonconductive bonding material of the first element or between the substrate and the second nonconductive bonding material of the second element. The bonding method can include directly bonding the first nonconductive bonding material of the first element to the second nonconductive bonding material of the second element without an intervening adhesive. The bonding method can include removing the second element from the first element by transferring thermal energy to the release layer to thereby induce diffusion of gas including volatile species out of the release layer.

A method for fabricating a package structure is provided, including the steps of: disposing on a carrier a semiconductor chip having an active surface facing the carrier; forming a patterned resist layer on the carrier; forming on the carrier an encapsulant exposing an inactive surface of the semiconductor chip and a surface of the patterned resist layer; and removing the carrier to obtain a package structure. Thereafter, redistribution layers can be formed on the opposite sides of the package structure, and a plurality of through holes can be formed in the patterned resist layer by drilling, thus allowing a plurality of conductive through holes to be formed in the through holes for electrically connecting the redistribution layers on the opposite sides of the package structure. Therefore, the invention overcomes the conventional drawback of surface roughness of the through holes caused by direct drilling the encapsulant having filler particles.

A method for manufacturing a handling device includes depositing a single layer of an adhesive on a first surface of a first wafer; depositing an antiadhesive layer on a first surface of a second wafer different from the first wafer; bringing into contact the first wafer and the second wafer, the bringing into contact taking place at the level of the single adhesive layer of the first wafer and the antiadhesive layer of the second wafer; separating the first wafer and the second wafer; the first wafer including the single adhesive layer forming a handling device. The bringing into contact of the first wafer and the second wafer is carried out at a temperature T.sup.C such that T.sub.C>T.sub.g°100°C. where T.sub.g is the glass transition temperature of the material composing the single adhesive layer of the first wafer.

A semiconductor package includes semiconductor bridge, first and second multilayered structures, first encapsulant, and a pair of semiconductor dies. Semiconductor dies of the pair include semiconductor substrate and conductive pads disposed at front surface of semiconductor substrate. Semiconductor bridge electrically interconnects the pair of semiconductor dies. First multilayered structure is disposed on rear surface of one semiconductor die. Second multilayered structure is disposed on rear surface of the other semiconductor die. First encapsulant laterally wraps first multilayered structure, second multilayered structure and the pair of semiconductor dies. Each one of first multilayered structure and second multilayered structure includes a top metal layer, a bottom metal layer, and an intermetallic layer. Each one of first multilayered structure and second multilayered structure has surface coplanar with surface of first encapsulant. The top metal layers, the bottom metal layers, and the intermetallic layers are in contact with the first encapsulant.

A multilayer wiring board includes a main wiring board which mounts a semiconductor component on a surface of the main wiring board, and a wiring structure body which is mounted to the main wiring board and is formed to be electrically connected to the semiconductor component. The wiring structure body includes conductive pads formed on a first side of the wiring structure body, a heat radiation component formed on a second side of the wiring structure body on the opposite side with respect to the first side, an insulation layer positioned between the conductive pads and the heat radiation component, and via conductors formed in the insulation layer such that each of the via conductors has a diameter which increases from the first side toward the second side of the wiring structure body.

A laminate manufactured by forming a step difference in a substrate by grinding a periphery edge portion to have such a size that a surface on the inner side of the step difference can be housed in a cavity of a die, and then laminating the substrate, an adhesive layer, a release layer, and a support plate in this order such that the surface on the inner side of the step difference of the substrate faces the support plate.

According to one embodiment, in a semiconductor device, a first film is arranged on a side of a main surface of the substrate. A second film is arranged on an opposite side of the substrate with the first film interposed therebetween. A main surface of the second film is in contact with a main surface of the first film. A third film is arranged on an opposite side of the first film with the second film interposed therebetween. A main surface on a side of the substrate of the third film has two-dimensionally-distributed protrusions or recesses. A main surface on an opposite side of the substrate of the third film is flat. Absorptance of infrared light of the second film is higher than absorptance of the infrared light of the third film. Thermal expansion coefficient of the third film is different from thermal expansion coefficient of the second film.