Patent application number | Description | Published |
20080290078 | LASER PROCESSING MACHINE - A laser processing machine having a laser beam irradiation unit is provided. The laser beam irradiation unit includes: a laser beam oscillation section; a beam splitter adapted to split the laser beam emitted from the laser beam oscillation section into a first laser beam and a second laser beam; a condenser lens adapted to condense the first and second laser beams; a prism adapted to lead the first and second laser beams split by the beam splitter to the condenser lens; a first angle-changing mirror disposed on a first optical path adapted to lead the first laser beam split by the beam splitter; a second angle-changing mirror disposed on a second optical path adapted to lead the second laser beam split by the beam splitter to the prism; and a half-wave plate disposed in the first or second optical path to allow one of respective directions of the first and second polarization planes to be aligned with the other. | 11-27-2008 |
20090311848 | OPTICAL DEVICE WAFER DIVIDING METHOD - An optical device wafer dividing method includes a rear surface grinding step for grinding a rear surface of the optical device wafer; a dicing tape sticking step for sticking the front surface of the optical device wafer bonded with the reinforcing substrate to the front surface of a dicing tape; a laser processing step for emitting a laser beam along the streets formed on the optical device wafer from the rear surface of the reinforcing substrate to perform laser processing on the reinforcing substrate along the streets to form fracture starting points; and a wafer dividing step for applying an external force along the fracture starting points of the reinforcing substrate to fracture the reinforcing substrate along the fracture starting points to fracture the optical device wafer along the streets. | 12-17-2009 |
20100035408 | METHOD OF PROCESSING OPTICAL DEVICE WAFER - A method of dividing an optical device wafer includes: a laser beam processing step of performing laser beam processing to provide an optical device wafer with breakage starting points along streets on the face side of the optical device wafer; a protective plate bonding step of bonding the face side of the optical device wafer to a surface of a highly rigid protective plate with a bonding agent permitting peeling; a back side grinding step of grinding the back side of the optical device wafer so as to form the optical device wafer to a finished thickness of the optical devices; a wafer supporting step of adhering the back-side surface of the optical device wafer to a surface of a dicing tape, and peeling the protective plate adhered to the face side of the optical device wafer; and a wafer dividing step of exerting an external force on the optical device wafer so as to break up the optical device wafer along the streets along which the breakage starting points have been formed, thereby dividing the optical device wafer into the individual optical devices. | 02-11-2010 |
20100041210 | METHOD OF PROCESSING OPTICAL DEVICE WAFER - A method of dividing an optical device wafer includes: a laser beam processing step of performing laser beam processing on the face side of an optical device wafer so as to form breakage starting points along streets; a protective plate bonding step of bonding the face side of the optical device wafer to a surface of a highly rigid protective plate with a bonding agent permitting peeling; a back side grinding step of grinding the back side of the optical device wafer so as to form the optical device wafer to a finished thickness of optical devices; a dicing tape adhering step of adhering the back-side surface of the optical device wafer to a dicing tape; a cut groove forming step of cutting the protective plate bonded to the optical device wafer along the streets so as to form cut grooves; and a wafer dividing step of exerting an external force on the optical device wafer through the protective plate, so as to break up the optical device wafer along the breakage starting points formed along the streets, thereby dividing the optical device wafer into the individual optical devices. | 02-18-2010 |
20100047999 | WORKING METHOD FOR AN OPTICAL DEVICE WAFER - A dividing method for an optical device wafer includes a protective plate adhering step of releasably adhering the surface of an optical device wafer to the surface of a protective plate, a reverse face grinding step of grinding the reverse face of the optical device wafer, a dicing tape sticking step of sticking the reverse face of the optical device wafer on the surface of a dicing tape, a protective plate grinding step of grinding the reverse face of the protective plate adhered to the optical device wafer stuck on the dicing tape so as to have a predetermined thickness, a laser working step of irradiating a laser beam upon the protective plate along the streets formed on the optical device wafer to carry out laser working, which forms break starting points along the streets, for the protective plate, and a wafer dividing step of applying external force to the protective plate to break the protective plate along the break starting points to break the optical device wafer along the streets thereby to divide the optical device wafer into the individual optical devices. | 02-25-2010 |
20110133235 | LIGHT EMITTING DEVICE AND MANUFACTURING METHOD THEREOF - A light emitting device including a sapphire layer and a light emitting layer formed on the sapphire layer. The sapphire layer has a polygonal sectional shape whose internal angle is an obtuse angle, such as a regular hexagonal shape. Light emitted from the light emitting layer is totally reflected on one side surface of the sapphire layer and next transmitted through another side surface of the sapphire layer. | 06-09-2011 |
20120083059 | SAPPHIRE WAFER DIVIDING METHOD - A sapphire wafer dividing method including a cut groove forming step of forming a plurality of cut grooves on the back side of a sapphire wafer along a plurality of crossing division lines formed on the front side where a light emitting layer is formed, a modified layer forming step of forming a plurality of modified layers inside the sapphire wafer along the division lines, and a dividing step of dividing the sapphire wafer into individual light emitting devices along the modified layers as a division start point, thereby chamfering the corners of the back side of each light emitting device owing to the formation of the cut grooves in the cut groove forming step. | 04-05-2012 |
20120156816 | SAPPHIRE WAFER DIVIDING METHOD - A sapphire wafer dividing method including a modified layer forming step of forming a plurality of modified layers inside a sapphire wafer along a plurality of crossing division lines formed on the front side where a light emitting layer is formed, and a chamfering and dividing step of forming a plurality of cut grooves on the back side of the sapphire wafer along the division lines, thereby dividing the sapphire wafer into individual light emitting devices along the modified layers as a division start point, wherein the corners of the back side of each light emitting device are chamfered by the formation of the cut grooves in the chamfering and dividing step. | 06-21-2012 |
20120289026 | SPLITTING METHOD FOR OPTICAL DEVICE WAFER - In a splitting method for an optical device wafer, the wafer having optical devices formed individually in regions partitioned by a plurality of crossing scheduled splitting lines provided on a front surface and having a reflective film formed on a reverse surface, a focal point of a laser beam is positioned to the inside of the optical device wafer and the laser beam is irradiated along the scheduled splitting lines from the reverse surface side of the wafer to form modification layers in the inside of the wafer. An external force is applied to the wafer to split the wafer along the scheduled splitting lines and form a plurality of optical device chips. The laser beam has a wavelength that produces transmittance through the reflective film equal to or higher than 80%. | 11-15-2012 |
20130189806 | PROCESSING METHOD FOR WAFER - A wafer has, on a front face thereof, a device region in which a device is formed in regions partitioned by a plurality of scheduled division lines. An outer peripheral region surrounds the device region. A reflecting film of a predetermined width is formed from the outermost periphery of the wafer on a rear face of the wafer corresponding to the outer peripheral region. The front face side of the wafer is held in a chuck table, and a focal point of a pulsed laser beam of a wavelength having permeability through the wafer is positioned in the inside of the wafer corresponding to the scheduled division lines. The pulsed laser beam is irradiated from the rear face side of the wafer to form modified layers individually serving as a start point of division along the scheduled division lines in the inside of the wafer. | 07-25-2013 |
20150076662 | COMPOSITE SUBSTRATE MANUFACTURING METHOD, SEMICONDUCTOR ELEMENT MANUFACTURING METHOD, COMPOSITE SUBSTRATE, AND SEMICONDUCTOR ELEMENT - Provided is a composite substrate manufacturing method, including at least: a first raw board deforming step of preparing a first substrate by deforming a first raw board having at least one surface as a minor surface into a state in which the minor surface warps outward; and a joining step of joining, after the first raw board deforming step, a protruding surface of the first substrate and one surface of a second substrate to each other, thereby manufacturing a composite substrate including the first substrate and the second substrate, in which the second substrate is any one substrate selected from a substrate having both surfaces as substantially flat surfaces and a substrate that warps so that a surface thereof to be joined to the first substrate warps outward. Also provided are a semiconductor element manufacturing method, a composite substrate and a semiconductor element manufactured. | 03-19-2015 |