A carrier substrate includes a base layer, an antireflection layer, and an energy absorption layer, wherein the antireflection layer is formed on one surface of the base layer and allows an elastic wave generated by a first laser beam transmitted through an element adhesively bonded to the antireflection layer to be transmitted through the base layer without being reflected towards the element, the first laser beam being applied to the element through a source substrate of the element, and the energy absorption layer is formed between the base layer and the antireflection layer to be aligned with the element, and evaporates upon energy absorption.

A method of manufacturing a display apparatus includes: providing a substrate having a first surface and a second surface and arranging the substrate on a carrier such that the second surface of the substrate contacts the carrier; forming a display device on the first surface of the substrate; arranging a first protective film on the display device; cutting a substrate by irradiating a first short pulse laser beam onto the second surface of the substrate through the carrier; and cutting the first protective film by irradiating a laser beam of an infrared wavelength range onto an area of the first protective film that overlaps a cut area of the substrate.

A method of manufacturing a display apparatus includes: providing a substrate having a first surface and a second surface and arranging the substrate on a carrier such that the second surface of the substrate contacts the carrier; forming a display device on the first surface of the substrate; arranging a first protective film on the display device; cutting a substrate by irradiating a first short pulse laser beam onto the second surface of the substrate through the carrier; and cutting the first protective film by irradiating a laser beam of an infrared wavelength range onto an area of the first protective film that overlaps a cut area of the substrate.

Methods of laser processing a transparent material are disclosed. The method may include positioning the transparent material on a carrier and transmitting a laser beam through the transparent material, where the laser beam may be incident on a side of the transparent material opposite the carrier. The transparent material may be substantially transparent to the laser beam and the carrier may include a support base and a laser disruption element. The laser disruption element may disrupt the laser beam transmitted through the transparent material such that the laser beam may not have sufficient intensity below the laser disruption element to damage the support base.

Methods of laser processing a transparent material are disclosed. The method may include positioning the transparent material on a carrier and transmitting a laser beam through the transparent material, where the laser beam may be incident on a side of the transparent material opposite the carrier. The transparent material may be substantially transparent to the laser beam and the carrier may include a support base and a laser disruption element. The laser disruption element may disrupt the laser beam transmitted through the transparent material such that the laser beam may not have sufficient intensity below the laser disruption element to damage the support base.

A new ultrasonic aided laser joining method (UAL) for bonding dissimilar materials has been developed. The method is capable of eliminating the laser-induced bubbles at the bonding faces and to improve the joint strength over that of the conventional laser-assisted metal and plastic joining method (LAMP). Some experiments on joining titanium to polyethylene terephthalate have been conducted to show the superiority of UAL over LAMP. The results showed that the joint strength, measured in terms of failure load, was significantly increased when ultrasonic vibration was employed during laser joining. For the LAMP joined specimens, fracture normally occurred at the metal-plastic interface, whereas for the UAL joined specimens, fracture normally occurred in the parent plastic part. The improvement in joint strength is mainly due to the elimination of pores in the resolidified plastic. In addition, ultrasound vibration promotes chemical bonding between the plastic and metal parts, and this is supported by the XPS results.

The liquid-assisted micromachining methods include methods of processing a substrate made of a transparent dielectric material. A working surface of the substrate is placed in contact with a liquid-assist medium that comprises fluorine. A focused pulsed laser beam is directed through a first substrate surface and through the opposite working surface to form a focus spot in the liquid-assist medium. The focus spot is then moved over a motion path from its initial position in the liquid-assist medium through the substrate body in the general direction from the working surface to the first surface to create a modification of the transparent dielectric material that defines in the body a core portion. The core portion is removed to form the substrate feature, which can be a through or closed fiber hole that supports one or more optical fibers. Optical components formed using the processed substrate are also disclosed.

It comprises a first step of preparing an object; a second step of forming a modified region in a first member along a line by irradiating the first member with laser light while using a front face of the object as a laser light entrance surface; a third step of forming a processing scar in a bonding layer along the line by irradiating the bonding layer with laser light while using the front face as a laser light entrance surface; and a fourth step, after the first to third steps, of forming a modified region in a second member along the line by irradiating the second member with laser light while using a rear face of the object as a laser light entrance surface; the fourth step uses the processing scar as a reference for alignment of a laser light irradiation position with respect to the second member.

It comprises a first step of preparing an object; a second step of forming a modified region in a first member along a line by irradiating the first member with laser light while using a front face of the object as a laser light entrance surface; a third step of forming a processing scar in a bonding layer along the line by irradiating the bonding layer with laser light while using the front face as a laser light entrance surface; and a fourth step, after the first to third steps, of forming a modified region in a second member along the line by irradiating the second member with laser light while using a rear face of the object as a laser light entrance surface; the fourth step uses the processing scar as a reference for alignment of a laser light irradiation position with respect to the second member.

A resin pipe 30 and a resin member 31 are fixed to a setting portion 5 provided on the front side of a base 6, and a timing pulley 13 which is provided on the back side of the base 6 and to which a light emission unit 3 is attached is rotated. As a result, the light emission unit 3 applies laser light 20 to a junction 32 between the resin pipe 30 and the resin member 31 while revolving around the junction 32. This makes it easy to fuse and join the entire outer circumferential surface of the resin pipe 30 with the entire inner circumferential surface of the resin member 31, which are variously shaped and sized.