A bonding tool for bonding a semiconductor element to a substrate on a bonding machine is provided. The bonding tool includes a body portion including a contact region for contacting the semiconductor element during a bonding process on the bonding machine. The body portion defines a non-contact region adjacent the contact region. The bonding tool also includes a heat resistant coating applied to the non-contact region.

An active substrate includes a plurality of active components distributed over a surface of a destination substrate, each active component including a component substrate different from the destination substrate, and each active component having a circuit and connection posts on a process side of the component substrate. The connection posts may have a height that is greater than a base width thereof, and may be in electrical contact with the circuit and destination substrate contacts. The connection posts may extend through the surface of the destination substrate contacts into the destination substrate connection pads to electrically connect the connection posts to the destination substrate contacts.

A jig for bonding a semiconductor chip may include a pressurizing portion and at least one opening. The pressuring portion may be configured to pressurize an upper surface of the semiconductor chip bonded to a package substrate via a bump and a flux using a laser. The opening may be surrounded by the pressurizing portion. The laser irradiated to the bump and the flux may be transmitted through the opening. A vapor generated from the flux by the laser may be discharged through the opening. Thus, the contamination of the jig caused by the vapor may be prevented so that a transmissivity of the laser through the jig may be maintained.

A bond tip for thermocompression bonding a bottom surface includes a die contact area and a low surface energy material covering at least a portion of the bottom surface. The low surface energy material may cover substantially all of the bottom surface, or only a peripheral portion surrounding the die contact area. The die contact area may be recessed with respect to the peripheral portion a depth at least as great as a thickness of a semiconductor die to be received in the recessed die contact area. A method of thermocompression bonding is also disclosed.

The present application provides methods, systems and devices for simultaneously bonding multiple semiconductor chips of different height profiles on a flexible substrate.

An array substrate includes a driver, a glass substrate having a driver mounting section where the driver is mounted, an anisotropic conductive material that is interposed between the driver and driver mounting section so as to electrically connect both and that at least includes a binder made of a thermosetting resin and conductive particles in the binder, and a heat supply part provided on at least the driver mounting section of the glass substrate for supplying heat to the anisotropic conductive material.

An active substrate includes a plurality of active components distributed over a surface of a destination substrate, each active component including a component substrate different from the destination substrate, and each active component having a circuit and connection posts on a process side of the component substrate. The connection posts may have a height that is greater than a base width thereof, and may be in electrical contact with the circuit and destination substrate contacts. The connection posts may extend through the surface of the destination substrate contacts into the destination substrate connection pads to electrically connect the connection posts to the destination substrate contacts,

An apparatus includes a circuit substrate including a circuit trace and a micro-sized semiconductor device die electrically connected to the circuit substrate. The micro-sized semiconductor device die has a height not greater than 400 microns and a width not greater than 800 microns. An anisotropic conductive adhesive (ACA) is disposed between the circuit substrate and the micro-sized semiconductor device die, thereby providing an electrical connection from the circuit substrate to the micro-sized semiconductor device die.

An electronic component includes a circuit substrate, a connecting electrode, a micro-element, and a solder. The connecting electrode is located on the circuit substrate. The connecting electrode has a first transparent conductive layer. A surface of the first transparent conductive layer is located opposite the circuit substrate, and has a plurality of micrometer or nanometer particles. The micro-element is electrically connected to the connecting electrode. The solder is located between the connecting electrode and the micro-element, and fixes the micro-element on the connecting electrode.

An electronic component includes a circuit substrate, a connecting electrode, a micro-element, and a solder. The connecting electrode is located on the circuit substrate. The connecting electrode has a first transparent conductive layer. A surface of the first transparent conductive layer is located opposite the circuit substrate, and has a plurality of micrometer or nanometer particles. The micro-element is electrically connected to the connecting electrode. The solder is located between the connecting electrode and the micro-element, and fixes the micro-element on the connecting electrode.