A semiconductor device may include a lower structure including a first substrate, a first pad on the first substrate, and a first insulating layer enclosing the first pad, and an upper structure including a second substrate, a second pad on the second substrate, and a second insulating layer enclosing the second pad. Each of the first and second pads may include a first portion and a second portion on the first portion. The second portion may include the same metallic material as the first portion. The second portion of the first pad may be in contact with the second portion of the second pad, and the first insulating layer may be in contact with the second insulating layer.

The present invention provides a photosensitive resin composition comprising: an alkali-soluble resin having a phenolic hydroxyl group as an end group (A); a radiation-polymerizable compound (B); and a photoinitiator (C), a film adhesive, an adhesive sheet, an adhesive pattern, a semiconductor wafer with an adhesive layer, and a semiconductor device using the photosensitive resin composition.

The present invention provides a photosensitive resin composition comprising: an alkali-soluble resin having a phenolic hydroxyl group as an end group (A); a radiation-polymerizable compound (B); and a photoinitiator (C), a film adhesive, an adhesive sheet, an adhesive pattern, a semiconductor wafer with an adhesive layer, and a semiconductor device using the photosensitive resin composition.

A method of forming an electronic device structure includes providing an electronic component having a first major surface, an opposing second major surface, a first edge surface, and an opposing second edge surface. A substrate having a substrate first major surface and an opposing substrate second major surface is provided. The second major surface of the first electronic component is placed proximate to the substrate first major surface and providing a conductive material adjacent the first edge surface of the first electronic component. The conductive material is exposed to an elevated temperature to reflow the conductive material to raise the first electronic component into an upright position such that the second edge surface is spaced further away from the substrate first major surface than the first edge surface. The method is suitable for providing electronic components, such as antenna, sensors, or optical devices in a vertical or on-edge.

A method of forming an electronic device structure includes providing an electronic component having a first major surface, an opposing second major surface, a first edge surface, and an opposing second edge surface. A substrate having a substrate first major surface and an opposing substrate second major surface is provided. The second major surface of the first electronic component is placed proximate to the substrate first major surface and providing a conductive material adjacent the first edge surface of the first electronic component. The conductive material is exposed to an elevated temperature to reflow the conductive material to raise the first electronic component into an upright position such that the second edge surface is spaced further away from the substrate first major surface than the first edge surface. The method is suitable for providing electronic components, such as antenna, sensors, or optical devices in a vertical or on-edge.

Representative implementations of devices and techniques provide interconnect structures and components for coupling various carriers, printed circuit board (PCB) components, integrated circuit (IC) dice, and the like, using tall and/or fine pitch physical connections. Multiple layers of conductive structures or materials are arranged to form the interconnect structures and components. Nonwettable barriers may be used with one or more of the layers to form a shape, including a pitch of one or more of the layers.

Representative implementations of devices and techniques provide interconnect structures and components for coupling various carriers, printed circuit board (PCB) components, integrated circuit (IC) dice, and the like, using tall and/or fine pitch physical connections. Multiple layers of conductive structures or materials are arranged to form the interconnect structures and components. Nonwettable barriers may be used with one or more of the layers to form a shape, including a pitch of one or more of the layers.

Representative implementations of devices and techniques provide interconnect structures and components for coupling various carriers, printed circuit board (PCB) components, integrated circuit (IC) dice, and the like, using tall and/or fine pitch physical connections. Multiple layers of conductive structures or materials are arranged to form the interconnect structures and components. Nonwettable barriers may be used with one or more of the layers to form a shape, including a pitch of one or more of the layers.

Representative implementations of devices and techniques provide interconnect structures and components for coupling various carriers, printed circuit board (PCB) components, integrated circuit (IC) dice, and the like, using tall and/or fine pitch physical connections. Multiple layers of conductive structures or materials are arranged to form the interconnect structures and components. Nonwettable barriers may be used with one or more of the layers to form a shape, including a pitch of one or more of the layers.

Representative implementations of devices and techniques provide interconnect structures and components for coupling various carriers, printed circuit board (PCB) components, integrated circuit (IC) dice, and the like, using tall and/or fine pitch physical connections. Multiple layers of conductive structures or materials are arranged to form the interconnect structures and components. Nonwettable barriers may be used with one or more of the layers to form a shape, including a pitch of one or more of the layers.