A bonding apparatus includes: an anisotropic conductive film (“ACF”) attachment unit which attaches a first ACF and a second ACF onto a display panel assembly; a compression unit which compresses a first chip-on-film (“COF”) on the first ACF and compresses a second COF on the second ACF; and a buffer unit which rotates the display panel assembly, on which the first ACF and the second COF are compressed, on a plane.

A microelectronic package of the present description may comprises a first microelectronic device having at least one row of connection structures electrically connected thereto and a second microelectronic device having at least one row of connection structures electrically connected thereto, wherein the connection structures within the at least one first microelectronic device row are aligned with corresponding connection structures within the at least one second microelectronic device row in an x-direction. An interconnect comprising an interconnect substrate having a plurality of electrically isolated conductive traces extending in the x-direction on a first surface of the interconnect substrate may be attached to the at least one first microelectronic device connection structure row and the at least one second microelectronic device connection structure row, such that at least one interconnect conductive trace forms a connection between a first microelectronic device connection structure and its corresponding second microelectronic device connection structure.

A semiconductor device includes a leadframe that includes contact pins and a semiconductor die that has protruding connection formations. A flexible support member is disposed between the leadframe and the semiconductor die and supports the semiconductor die. The flexible support member has electrically conductive lines that extend between the leadframe and the semiconductor die. The electrically conductive lines of the flexible support member are electrically coupled with the contact pins of the leadframe and with the connection formations of the semiconductor die.

A bonding and indexing method is provided, having a first index head to move a substrate in an indexing direction from a first position to a second position; a second index head to move the substrate in an indexing direction from the second position to a third position; and the first and/or second index head has a bonding element to effect a bonding process between the substrate and an element disposed against the substrate so that bonding and movement in the indexing direction is implemented simultaneously by the first index head and/or bonding and movement in the indexing direction is implemented simultaneously by the second index head.

A bonding and indexing apparatus has a first index head to move a substrate in an indexing direction from a first position to a second position and a second index head to move the substrate in an indexing direction from the second position to a third position. The first and/or second index head has a bonding element to effect a bonding process between the substrate and an element disposed against the substrate so that bonding and movement in the indexing direction is implemented simultaneously by the first index head and/or bonding and movement in the indexing direction is implemented simultaneously by the second index head.

A micro-LED module is disclosed. The micro-LED module includes: a micro-LED including a plurality of LED cells, each of which includes a first conductive semiconductor layer, an active layer, and a second conductive semiconductor layer; a submount substrate mounted with the micro-LED; a plurality of electrode pads formed on the micro-LED cells; a plurality of electrodes formed corresponding to the plurality of electrode pads on the submount substrate; a plurality of connection members through which the plurality of electrode pads are connected to the corresponding plurality of electrodes; and a gap fill layer formed in the gap between the micro-LED and the submount substrate and having a bonding strength to the micro-LED and the submount substrate.

This thermocompression bonding device is provided with a heating tool (1) and a backup member (3). The backup member (3) has: a support portion (3a) which faces the tip (1a) of the heating tool (1) while first and second members (111, 122) to be joined and a cushioning member (2) are located therebetween, and which supports the first and second members (111, 122) to be joined; and a body portion (3b) provided on the opposite side of the support portion (3a) from the first and second members (111, 122) to be joined. The support portion (3a) is formed so that the heat conductivity thereof is lower than that of the body portion (3b).

A micro-LED module is disclosed. The micro-LED module includes: a micro-LED including a plurality of LED cells, each of which includes a first conductive semiconductor layer, an active layer, and a second conductive semiconductor layer; a submount substrate mounted with the micro-LED; a plurality of electrode pads formed on the micro-LED cells; a plurality of electrodes formed corresponding to the plurality of electrode pads on the submount substrate; a plurality of connection members through which the plurality of electrode pads are connected to the corresponding plurality of electrodes; and a gap fill layer formed in the gap between the micro-LED and the submount substrate and having a bonding strength to the micro-LED and the submount substrate.

A method of attaching one or more active devices on one or more substrates to a metal carrier by hot stamping is disclosed. The method includes contacting the active device(s) on the substrate(s) with the metal carrier, and applying pressure to and heating the active device(s) on the substrate(s) and the metal carrier sufficiently to affix or attach the active device(s) on the substrate(s) to the metal carrier. The active device(s) may include an integrated circuit. The substrate(s) may include a metal substrate on the backside of the active device and a protective/carrier film on the frontside of the active device. The protective/carrier film may be or include an organic polymer. The metal carrier may be or include a metal foil. Various examples of the method further include thinning the metal substrate, dicing the active device(s) and a continuous substrate, and/or separating the active devices.

A bonding apparatus includes: an anisotropic conductive film (ACF) attachment unit which attaches a first ACF and a second ACF onto a display panel assembly; a compression unit which compresses a first chip-on-film (COF) on the first ACF and compresses a second COF on the second ACF;

and a buffer unit which rotates the display panel assembly, on which the first ACF and the second COF are compressed, on a plane.