Disclosed herein is a resin composition for fixing a plate-shaped workpiece. The resin composition includes a composition and a photopolymerization initiator added to the composition. This composition is composed of (meth)acrylate and a plasticizer or a reactive diluent. Preferably, the composition constituting the resin composition contains 30% to 45% by mass of (meth)acrylate having an urethane bond, 5% to 15% by mass of (meth)acrylate not having an urethane bond, and 40% to 65% by mass of plasticizer, which is an ester.

A hydrophobic film is provided. The hydrophobic film includes a flexible substrate; a hydrophobic layer located on the flexible substrate, a heating layer, a first electrode and a second electrode spaced apart from the first electrode. The hydrophobic layer comprises a base and a patterned bulge layer on a surface of the base away from the flexible substrate. The heating layer is on a surface of the flexible substrate away from the hydrophobic layer. The first electrode and the second electrode are electrically connected to and in direct contact with the heating layer.

An apparatus for separating a wafer from a carrier includes a platform having an upper surface, a tape feeding unit, a first robot arm, and a controller coupled to the platform. The controller is configured to mount a wafer frame, by using the tape feeding unit, on a wafer of a wafer assembly on the upper surface of the platform. The wafer assembly includes the wafer, a carrier, and a layer of wax between the wafer and the carrier. The controller is also configured to heat the upper surface of the platform to a predetermined temperature and separate, by the first robot arm, the wafer and the wafer frame mounted thereon from the carrier.

A protective sheet sticking apparatus includes a cutting unit that cuts a protective sheet stuck to a wafer along an outer circumference of the wafer while bringing a cutting part of a cutting blade into contact with the outer circumference of the wafer. The cutting unit has a cutting blade support part that supports the cutting blade rotatably in such a manner that the direction of a cutting edge of the cutting part is adjustable from the outside in the radial direction of the wafer to the inside. The cutting blade support part includes a first biasing spring that makes biasing to cause the cutting part to be oriented toward the inside and a second biasing spring that makes biasing to cause the cutting part to be oriented toward the outside in order to prevent the cutting part from being oriented toward the inside by a predetermined angle or larger.

A cover lid for use with a semiconductor package is disclosed. First, a polyamide mask is applied to one surface of the lid plate. Next, the exposed areas of the surface, as well as the sides of the lid plate, are metallized. The polyamide mask can then be removed. This reduces pullback and shrinkage of the metallized layer, while lowering the manufacturing cost and process times.

A delamination method for delaminating a laminated substrate which includes a first and a second substrates bonded to each other, includes: adjusting a position of the laminated substrate at a holding unit by a position adjusting unit and disposing the holding unit at a predetermined height position; disposing a sharp member of a delamination inducing unit at a predetermined height position; detecting a contact of the sharp member by bringing the sharp member into contact with a side surface of one end portion of the laminated substrate; inserting the sharp member into the side surface of the one end portion of the laminated substrate; and delaminating the second substrate from the first substrate by a plurality of suction movement units which sucks the second substrate of the laminated substrate to move the second substrate away from the first substrate.

A method for processing a semiconductor wafer where an opaque layer is located on a surface of a handling wafer is used so the surface of the handling wafer may be detected through optical sensors. The opaque layer may be modified, or oriented, to allow light to pass through unobstructed.

Laser lift off systems and methods may be used to provide monolithic laser lift off with minimal cracking by reducing the size of one or more beam spots in one or more dimensions to reduce plume pressure while maintaining sufficient energy to provide separation. By irradiating irradiation zones with various shapes and in various patterns, the laser lift off systems and methods use laser energy more efficiently, reduce cracking when separating layers, and improve productivity. Some laser lift off systems and methods described herein separate layers of material by irradiating non-contiguous irradiation zones with laser lift off zones (LOZs) that extend beyond the irradiation zones. Other laser lift off systems and methods described herein separate layers of material by shaping the irradiation zones and by controlling the overlap of the irradiation zones in a way that avoids uneven exposure of the workpiece. Consistent with at least one embodiment, a laser lift off system and method may be used to provide monolithic lift off of one or more epitaxial layers on a substrate of a semiconductor wafer.

The present invention provides a temporary-bonding adhesive having excellent heat resistance, whereby a semiconductor circuit formation substrate and a support substrate can be bonded by a single type of adhesive layer, the adhesive force thereof does not change over the course of steps for manufacturing a semiconductor device or the like, and the adhesive can subsequently be easily de-bonded at room temperature under mild conditions; and a method for manufacturing a semiconductor device using the temporary-bonding adhesive. The present invention includes a temporary-bonding adhesive wherein a polyimide copolymer having at least an acid dianhydride residue and a diamine residue, the diamine residue including both of (A1) a polysiloxane-based diamine residue represented by a general formula (1) in which n is a natural number from 1 to 15, and (B1) a polysiloxane-based diamine residue represented by a general formula (1) in which n is a natural number from 16 to 100, the polyimide copolymer containing 40-99.99 mol % of the (A1) residue and 0.01-60 mol % of the (B1) residue.

A method for assembling two substrates by molecular adhesion comprises: a first step (a) of putting first and second substrates in close contact in order to form an assembly having an assembly interface; a second step (b) of reinforcing the degree of adhesion of the assembly beyond a threshold adhesion value at which water is no longer able to diffuse along the assembly interface. The method also comprises a step (c) of anhydrous treatment of the first and second substrates in a treatment atmosphere having a dew point below −10° C., and control of the dew point of a working atmosphere to which the first and second substrates are exposed from the anhydrous treatment step (c) until the end of the second step (b) so as to limit or prevent the appearance of bonding defects at the assembly interface.