According to a flexible light-emitting device production method of the present disclosure, after an intermediate region (30i) and flexible substrate regions (30d) of a plastic film (30) of a multilayer stack (100) are divided from one another, the interface between the flexible substrate regions (30d) and a glass base (10) is irradiated with lift-off light. The multilayer stack (100) is separated into a first portion (110) and a second portion (120) while the multilayer stack (100) is in contact with a stage (210). The first portion (110) includes a plurality of light-emitting devices (1000) which are in contact with the stage (210). The light-emitting devices (1000) include a plurality of functional layer regions (20) and the flexible substrate regions (30d). The second portion (120) includes the glass base (10) and the intermediate region (30i). The step of irradiating with the lift-off light includes making the irradiation intensity of lift-off light for at least part of the interface between the intermediate region (30i) and the glass base (10) lower than the irradiation intensity of lift-off light for the interface between the flexible substrate regions (30d) and the glass base (10).

A method of separating a support substrate and a wafer adhered to the support substrate includes inserting a trigger member into a space between the support substrate and the wafer. The space opens on a gap region of the support substrate. The gap region is within an outer periphery of a base member of the support substrate. The base member has an adhesive layer contacting the wafer. The adhesive layer does not extend to an edge of the base member facing the gap region at the space. The wafer and the base member are contacted by the trigger member which promotes separation of the wafer and the support substrate from each other.

A laminate processing method includes a water-soluble resin filling step of filling a water-soluble resin in a division groove formed in a dividing step, a modified layer removing step of positioning a cutting blade in the division groove formed in a back surface of a wafer to cut the division groove in a state in which the water-soluble resin is solidified or half-solidified, thereby removing a modified layer, and a water-soluble resin removing step of supplying cleaning water from the back surface of the wafer with a state in which an expandable tape is expanded being maintained, thereby removing the water-soluble resin being filled in a cut groove and the division groove.

A method for separating a window includes providing a display device including a display panel, a window disposed on the display panel and including a color layer. An adhesive layer is disposed between the display panel and the window. Heat is applied to the display device. The method includes inserting a disassembling stick between the display panel and the window to separate an edge of the display panel from the window. The method includes cooling the display device. The method includes separating the display panel and the window from each other.

A workpiece unit includes a wafer, a tape stuck to the wafer, and an annular frame to which an outer circumferential edge of the tape is stuck and which has an opening defined centrally therein. The wafer is disposed in the opening in the annular frame and supported on the annular frame by the tape. An irreversible ultraviolet radiation detecting seal that discolors when irradiated with an ultraviolet radiation as an external stimulus is stuck to the annular frame.

A composition exhibits excellent heat resistance and mounting reliability when bonding a semiconductor power element to a metal lead frame, which is also free of lead and thereby places little burden on the environment. An electrically conductive composition contains at least a sulfide compound represented by RSR (wherein R is an organic group containing at least carbon; R is an organic group that is the same as or different from R; and R and R may be bonded to each other to form a so-called cyclic sulfide) and metal particles containing at least Cu, Sn or Ni as its essential component. Further, a conductive paste and a conductive bonding film each are produced using the electrically conductive composition. A dicing die bonding film is obtained by bonding the conductive bonding film with an adhesive tape.

A laminate processing method includes a modified layer removing step of positioning a cutting blade to the region of the wafer corresponding to each of the division lines and cutting while supplying cutting water into which a water-soluble resin is mixed from the wafer side of the laminate, thereby removing the modified layer formed inside the wafer, a dividing step of, after the modified layer removing step is carried out, expanding the expandable tape, and dividing the laminate into individual image sensor chips, and a cleaning step of supplying cleaning water from the back surface of the wafer with a state in which the expandable tape is expanded being maintained, thereby cleaning the laminate.

A laminate processing method includes a water-soluble resin filling step of filling a water-soluble resin in a division groove formed in a dividing step, a modified layer removing step of positioning a cutting blade in the division groove formed in a back surface of a wafer to cut the division groove in a state in which the water-soluble resin is solidified or half-solidified, thereby removing a modified layer, and a water-soluble resin removing step of supplying cleaning water from the back surface of the wafer with a state in which an expandable tape is expanded being maintained, thereby removing the water-soluble resin being filled in a cut groove and the division groove.

A highly thermal conductive substrate formed by bonding a device layer formed on a silicon on insulator (SOI) wafer and a buried oxide film to an insulator substrate having a thermal conductivity of 40 W/m.Math.K or more via a low-stress adhesive, wherein a thickness of the buried oxide film is 50 to 500 nm and a thickness of the adhesive is 0.1 to 10 m.

A method of detecting adhesive residue on a wafer after peeling an adhesive film from the wafer by using a peeling tape is described. According to a first aspect, the method includes illuminating the peeling tape with first UV light after the peeling and acquiring a fluorescence image from the peeling tape. According to a second aspect, the method includes illuminating the wafer with second UV light after the peeling and acquiring a fluorescence image from the wafer.