A method is provided for localised deposition of a material over an element, including deposition of a portion of the material over a portion of a surface of a support; positioning of a portion of the element against the portion of the material; annealing of the material portion increasing, at the end of the treatment, the adhesion force of the material against the portion of the element, the materials of the portion of the element and of the portion of the surface of the support being selected such that the adhesion of the material against the portion of the element is, at the end of the annealing, higher than that of the material against the portion of the surface of the support; and separation of the element and the support at the interface between the material and the portion of the surface of the support, the material remaining secured to the portion of the element.

A method comprises: providing a layer of curable adhesive material (4) on a substrate (2); forming a pattern of microstructures (321) on the layer of curable adhesive material (4); curing a first region (42) of the layer of curable adhesive material (4) at a first level and a second region (44) of the layer of curable adhesive material (4) at a second level greater than the first level; providing a solid circuit die (6) to directly attach to a major surface of the first region (42) of the layer of curable adhesive material (4); and further curing the first region (42) of the layer of curable adhesive material (4) to anchor the solid circuit die (6) on the first region (42) by forming an adhesive bond therebetween. The pattern of microstructures (321) may include one or more microchannels (321), the method further comprising forming one or more electrically conductive traces in the microchannels (321), in particular, by flow of a conductive particle containing liquid (8) by a capillary force and, optionally, under pressure. The at least one microchannel (321) may extend from the second region (44) to the first region (42) and have a portion beneath the solid circuit die (6). The solid circuit die (6) may have at least one edge disposed within a periphery of the first region (42) with a gap therebetween. The solid circuit die (6) may have at least one contact pad (72) on a bottom surface thereof, wherein the at least one contact pad (72) may be in direct contact with at least one of the electrically conductive traces in the microchannels (321). Forming the pattern of microstructures (321) may comprise contacting a major surface of a stamp (3) to the layer of curable adhesive material (4), the major surface having a pattern of raised features (32) thereon. The curable adhesive material (4) may be cured by an actinic light source such as an ultraviolet (UV) light source (7, 7′), wherein a mask may be provided to at least partially block the first region (42) of the layer of curable adhesive material (4) from the cure. The stamp (3) may be positioned in contact with the curable adhesive material (4) to replicate the pattern of raised features (32) to form the microstructures (321) while the curable adhesive material (4) is selectively cured by the actinic light source such as the ultraviolet (UV) light source (7). The first region (42) of the layer of curab

A method comprises: providing a layer of curable adhesive material (4) on a substrate (2); forming a pattern of microstructures (321) on the layer of curable adhesive material (4); curing a first region (42) of the layer of curable adhesive material (4) at a first level and a second region (44) of the layer of curable adhesive material (4) at a second level greater than the first level; providing a solid circuit die (6) to directly attach to a major surface of the first region (42) of the layer of curable adhesive material (4); and further curing the first region (42) of the layer of curable adhesive material (4) to anchor the solid circuit die (6) on the first region (42) by forming an adhesive bond therebetween. The pattern of microstructures (321) may include one or more microchannels (321), the method further comprising forming one or more electrically conductive traces in the microchannels (321), in particular, by flow of a conductive particle containing liquid (8) by a capillary force and, optionally, under pressure. The at least one microchannel (321) may extend from the second region (44) to the first region (42) and have a portion beneath the solid circuit die (6). The solid circuit die (6) may have at least one edge disposed within a periphery of the first region (42) with a gap therebetween. The solid circuit die (6) may have at least one contact pad (72) on a bottom surface thereof, wherein the at least one contact pad (72) may be in direct contact with at least one of the electrically conductive traces in the microchannels (321). Forming the pattern of microstructures (321) may comprise contacting a major surface of a stamp (3) to the layer of curable adhesive material (4), the major surface having a pattern of raised features (32) thereon. The curable adhesive material (4) may be cured by an actinic light source such as an ultraviolet (UV) light source (7, 7′), wherein a mask may be provided to at least partially block the first region (42) of the layer of curable adhesive material (4) from the cure. The stamp (3) may be positioned in contact with the curable adhesive material (4) to replicate the pattern of raised features (32) to form the microstructures (321) while the curable adhesive material (4) is selectively cured by the actinic light source such as the ultraviolet (UV) light source (7). The first region (42) of the layer of curab

The present disclosure relates to an adhesive transfer film for bonding a semiconductor chip and a spacer to a substrate and a method for manufacturing a power module substrate by using same, the adhesive transfer film being obtained by manufacturing an Ag sintering paste in the form of a film. The present disclosure can reduce the process time by minimizing a sintering process, and can reduce equipment investment cost.

The present disclosure provides a method of transferring an electronic element using a stamping and magnetic field alignment technology and an electronic device including an electronic element transferred using the method. In the present disclosure, a polymer may be simultaneously coated on a plurality of electronic elements using the stamping process, and the polymer may be actively coated on the electronic elements without restrictions on process parameters such as size and spacing of the electronic elements. Moreover, the self-aligned ferromagnetic particles have an anisotropic current flow through which current flows only in the aligned direction. Therefore, the current may flow only vertically between the electronic element and the electrode, and there is no electrical short circuit between a peripheral LED element and the electrode.

A device (2) is formed on a main surface of a substrate (1). The main surface of the substrate (1) is bonded to the undersurface of the counter substrate (14) via the bonding member (11,12,13) in a hollow state. A circuit (17) and a bump structure (26) are formed on the top surface of the counter substrate (14). The bump structure (26) is positioned in a region corresponding to at least the bonding member (11,12,13), and has a higher height than that of the circuit (17).

The present disclosure provides a method of transferring an electronic element using a stamping and magnetic field alignment technology and an electronic device including an electronic element transferred using the method. In the present disclosure, a polymer may be simultaneously coated on a plurality of electronic elements using the stamping process, and the polymer may be actively coated on the electronic elements without restrictions on process parameters such as size and spacing of the electronic elements. Moreover, the self-aligned ferromagnetic particles have an anisotropic current flow through which current flows only in the aligned direction. Therefore, the current may flow only vertically between the electronic element and the electrode, and there is no electrical short circuit between a peripheral LED element and the electrode.

The present invention provides a method for producing a semiconductor device, including: a semiconductor chip-mounting step of subsequently pressing a plurality of semiconductor chips by a first pressing member to respectively bond the plurality of semiconductor chips to a plurality of mounting areas provided on a substrate, wherein the bonding is performed in a state where adhesive sheets are respectively interposed between the plurality of semiconductor chips and the plurality of mounting areas, each of the adhesive sheets includes sinterable metal particles that can be sintered by heating at a temperature of 400° C. or less, and the first pressing member is heated to a temperature, at which the sinterable metal particles can be sintered.

This member connection method includes a printing step. In the printing step, a coating film-formed region in which the coating film is formed, and a coating film non-formed region in which the coating film is not formed are formed in the print pattern, and the coating film-formed region is divided into a plurality of concentric regions and a plurality of radial regions by means of a plurality of line-shaped regions provided so as to connect various points, which are separated apart from one another in the marginal part of the connection region.

This member connection method includes a printing step. In the printing step, a coating film-formed region in which the coating film is formed, and a coating film non-formed region in which the coating film is not formed are formed in the print pattern, and the coating film-formed region is divided into a plurality of concentric regions and a plurality of radial regions by means of a plurality of line-shaped regions provided so as to connect various points, which are separated apart from one another in the marginal part of the connection region.