A method for trimming a micro electronic element includes: providing a substrate, wherein at least one micro electronic element is disposed on the substrate, heating an interface of the substrate and the micro electronic element by a first pulse laser beam to reduce a bonding force between the micro electronic element and the substrate, and irradiating a surface layer of the micro electronic element by a second pulse laser beam to generate a shock wave due to plasma on the surface layer of the micro electronic element. The shock wave removes the micro electronic element away from the substrate. An apparatus for trimming a micro electronic element is also provided.

Method and device for severing a microchip from a wafer and arranging the microchip on a substrate, wherein the microchip is contact-bonded to the free end of a tip during severing and accordingly adheres to the tip through adhesive force while the substrate is transported. A coordinate measuring machine can advantageously be used as device.

Techniques for high speed handling of ultra-small chips (e.g., micro-chips) by selective laser bonding and/or debonding are provided. In one aspect, a method includes: providing a first wafer including chips bonded to a surface thereof; contacting the first wafer with a second wafer, the second wafer including a substrate bonded to a surface thereof, wherein the contacting aligns individual chips with bonding sites on the substrate; and debonding the individual chips from the first wafer using a debonding laser having a small spot size of about 0.5 m to about 100 m, and ranges therebetween. A system is also provided that has digital cameras, a motorized XYZ-axis stage, and a computer control system configured to i) control a spot size of the at least one laser source and ii) adjust a positioning of the sample to align individual chips with a target area of the laser.

Techniques for high speed handling of ultra-small chips (e.g., micro-chips) by selective laser bonding and/or debonding are provided. In one aspect, a method includes: providing a first wafer including chips bonded to a surface thereof; contacting the first wafer with a second wafer, the second wafer including a substrate bonded to a surface thereof, wherein the contacting aligns individual chips with bonding sites on the substrate; and debonding the individual chips from the first wafer using a debonding laser having a small spot size of about 0.5 m to about 100 m, and ranges therebetween. A system is also provided that has digital cameras, a motorized XYZ-axis stage, and a computer control system configured to i) control a spot size of the at least one laser source and ii) adjust a positioning of the sample to align individual chips with a target area of the laser.

A repaired transfer printed system (e.g., micro-transfer printed system) includes a system substrate having two or more contact pads disposed on the system substrate. One or more transfer printed devices (e.g., micro-transfer printed devices) are disposed in contact with the system substrate, each device having two or more connection posts. Each connection post of a replacement device is in physical contact with a contact pad, the connection post forming a second imprint in the physically contacted contact pad. In certain embodiments, a first imprint is in at least one of the physically contacted contact pads and is between the replacement device and the system substrate.

An assembly is provided for mechanically severing ball grid array (BGA) attachment solder between an electronics chip and a printed circuit board. The assembly includes a bridge fixture, a tungsten wire and removable spacers. The bridge fixture extends over the chip. A pair of guide bars flanks the bridge fixture. each guide bar has a wire engagement surface. The tungsten wire is disposed across the chip between the pair of guide bars along their respective surfaces. The removable spacers are disposed between the corresponding guide bars and the printed circuit board for aligning the wire to engage the solder.

A solder removal apparatus is provided. The solder removal apparatus comprises a plurality of solder-interfacing protrusions extending from a body by a length. Each of the plurality of solder-interfacing protrusions is configured to remove a corresponding one of a plurality of solder features from a semiconductor device, where each of the plurality of solder features has a height and an amount of solder material.

A solder removal apparatus is provided. The solder removal apparatus comprises a plurality of solder-interfacing protrusions extending from a body by a length. Each of the plurality of solder-interfacing protrusions is configured to remove a corresponding one of a plurality of solder features from a semiconductor device, where each of the plurality of solder features has a height and an amount of solder material.

A method for debonding a bonded part includes attaching a handle to a third side of a first substrate of the bonded part with an adhesive layer. The bonded part has a plurality of inter-substrate bond structures that couple a first side of the first substrate to a second side of a second substrate. The third side of the first substrate is opposite the first side. The first substrate and the second substrate have different thicknesses. The method includes absorbing a solvent into the adhesive layer, swelling the adhesive layer in response to the absorbing of the solvent, bending the first substrate in response to the swelling, and breaking a plurality of thermocompression bonds between the plurality of inter-substrate bond structures and the second side of the second substrate in response to the bending to debond the first substrate.

Method and device for severing a microchip from a wafer and arranging the microchip on a substrate, wherein the microchip is contact-bonded to the free end of a tip during severing and accordingly adheres to the tip through adhesive force while the substrate is transported. A coordinate measuring machine can advantageously be used as device.