A method of selectively transferring micro devices from a donor substrate to contact pads on a receiver substrate. Micro devices being attached to a donor substrate with a donor force. The donor substrate and receiver substrate are aligned and brought together so that selected micro devices meet corresponding contact pads. A receiver force is generated to hold selected micro devices to the contact pads on the receiver substrate. The donor force is weakened and the substrates are moved apart leaving selected micro devices on the receiver substrate. Several methods of generating the receiver force are disclosed, including adhesive, mechanical and electrostatic techniques.

A method of selectively transferring micro devices from a donor substrate to contact pads on a receiver substrate. Micro devices being attached to a donor substrate with a donor force. The donor substrate and receiver substrate are aligned and brought together so that selected micro devices meet corresponding contact pads. A receiver force is generated to hold selected micro devices to the contact pads on the receiver substrate. The donor force is weakened and the substrates are moved apart leaving selected micro devices on the receiver substrate. Several methods of generating the receiver force are disclosed, including adhesive, mechanical and electrostatic techniques.

What is disclosed is a method of selectively transferring micro devices from a donor substrate to contact pads on a receiver substrate. Micro devices being attached to a donor substrate with a donor force. The donor substrate and receiver substrate are aligned and brought together so that selected micro devices meet corresponding contact pads. A receiver force is generated to hold selected micro devices to the contact pads on the receiver substrate. The donor force is weakened and the substrates are moved apart leaving selected micro devices on the receiver substrate. Several methods of generating the receiver force are disclosed, including adhesive, mechanical and electrostatic techniques.

An interposer board having heating function and an electronic device using the same are provided. The interposer board includes an insulating body, a plurality of top conductive contacts, a plurality of bottom conductive contacts, a plurality of conductive connection structures and a plurality of micro heaters. The top conductive contacts are disposed on the insulating body. The bottom conductive contacts are disposed on the insulating body. The conductive connection structures are disposed on the insulating body, and the conductive connection structures respectively electrically connected to the top conductive contacts and respectively electrically connected to the bottom conductive contacts. The micro heaters are disposed on or in the insulating body, and the micro heaters are respectively adjacent to the top conductive contacts and the bottom conductive contacts. Each of the top conductive contacts or each of the bottom conductive contacts can be heated by the corresponding micro heater.

A non-conductive film having heating function and an electronic device using the same are provided. The electronic device includes a circuit substrate, an interposer board disposed on the circuit substrate, at least one electronic chip carried by the interposer board, a first non-conductive film disposed between the interposer board and the circuit substrate, and a second non-conductive film disposed between the at least one electronic chip and the interposer board, the at least one electronic chip being electrically connected to the circuit substrate through the interposer board. One of the first non-conductive film and the second non-conductive film is a type of non-conductive film having heating function, and the non-conductive film with heating function includes a non-conductive body and a plurality of micro heaters. The shape of the non-conductive body is changeable by heating, and the micro heaters are disposed on or in the non-conductive body.

A method of selectively transferring micro devices from a donor substrate to contact pads on a receiver substrate. Micro devices being attached to a donor substrate with a donor force. The donor substrate and receiver substrate are aligned and brought together so that selected micro devices meet corresponding contact pads. A receiver force is generated to hold selected micro devices to the contact pads on the receiver substrate. The donor force is weakened and the substrates are moved apart leaving selected micro devices on the receiver substrate. Several methods of generating the receiver force are disclosed, including adhesive, mechanical and electrostatic techniques.

A stacked semiconductor device is provided, including a first semiconductor structure, a second semiconductor structure and a bonding structure disposed between the first and second semiconductor structures. The first semiconductor structure and the second semiconductor structure include first conductive pillars and second conductive pillars, respectively. The first semiconductor structure is stacked above the second semiconductor structure. The bonding structure contacts the first conductive pillars and the second conductive pillars, wherein the bonding structure comprises conductive paths for electrically connecting the first conductive pillars and the second conductive pillars.

A method of manufacturing a semiconductor device may include interposing a bonding material between an electrode of a semiconductor element and a conductor, the bonding material being a material that is to be melted by heat; melting the bonding material by applying a current to the semiconductor element to cause the semiconductor element to generate heat; and cooling and solidifying the bonding material that is melted by stopping the current.

A thermally-conductive and mechanically-robust bonding method for attaching a metal nanowire (MNW) array to an adjacent surface includes the steps of: removing a template membrane from the MNW; infiltrating the MNW with a bonding material; placing the bonding material on the adjacent surface; bringing an adjacent surface into contact with a top surface of the MNW while the bonding material is bondable; and allowing the bonding material to cool and form a solid bond between the MNW and the adjacent surface. A thermally-conductive and mechanically-robust bonding method for attaching a metal nanowire (MNW) array to an adjacent surface includes the steps of: choosing a bonding material based on a desired bonding process; and without removing the MNW from a template membrane that fills an interstitial volume of the MNW, depositing the bonding material onto a tip of the MNW.

What is disclosed is a method of selectively transferring micro devices from a donor substrate to contact pads on a receiver substrate. Micro devices being attached to a donor substrate with a donor force. The donor substrate and receiver substrate are aligned and brought together so that selected micro devices meet corresponding contact pads. A receiver force is generated to hold selected micro devices to the contact pads on the receiver substrate. The donor force is weakened and the substrates are moved apart leaving selected micro devices on the receiver substrate. Several methods of generating the receiver force are disclosed, including adhesive, mechanical and electrostatic techniques.