Abstract: In a manufacturing method of a semiconductor device having a multilevel interconnect layer including a low-k layer, a two-step cutting technique is used for dicing. After formation of a groove in a semiconductor wafer with a tapered blade, the groove is divided with a straight blade thinner than the groove width. The multilevel interconnect layer portion is cut while being covered with a tapered face and then the wafer is separated with a thin blade which is not brought into contact with the multilevel interconnect layer portion. The wafer can thus be diced without damaging a relatively fragile low-k layer.

Abstract: In a manufacturing method of a semiconductor device having a multilevel interconnect layer including a low-k layer, a two-step cutting technique is used for dicing. After formation of a groove in a semiconductor wafer with a tapered blade, the groove is divided with a straight blade thinner than the groove width. The multilevel interconnect layer portion is cut while being covered with a tapered face and then the wafer is separated with a thin blade which is not brought into contact with the multilevel interconnect layer portion. The wafer can thus be diced without damaging a relatively fragile low-k layer.

Abstract: With a recent shrinking semiconductor process, insulating layers formed between interconnect layers are becoming thin. To avoid parasitic capacitance between them, materials of a low dielectric constant have been used for an insulating layer in a multilevel interconnect. Low-k materials, however, have low strength compared with the conventional insulating layers. Porous low-k materials are structurally fragile. The invention therefore provides a manufacturing method of a semiconductor device having a multilevel interconnect layer including a low-k layer. According to the method, in a two-step cutting system dicing in which after formation of a groove in a semiconductor water with a tapered blade, the groove is divided with a straight blade thinner than the groove width, the multilevel interconnect layer portion is cut while being covered with a tapered face and then the wafer is separated with a thin blade which is not brought into contact with the multilevel interconnect layer portion.

Abstract: With a recent shrinking semiconductor process, insulating layers formed between interconnect layers are becoming thin. To avoid parasitic capacitance between them, materials of a low dielectric constant have been used for an insulating layer in a multilevel interconnect. Low-k materials, however, have low strength compared with the conventional insulating layers. Porous low-k materials are structurally fragile. The invention therefore provides a manufacturing method of a semiconductor device having a multilevel interconnect layer including a low-k layer. According to the method, in a two-step cutting system dicing in which after formation of a groove in a semiconductor water with a tapered blade, the groove is divided with a straight blade thinner than the groove width, the multilevel interconnect layer portion is cut while being covered with a tapered face and then the wafer is separated with a thin blade which is not brought into contact with the multilevel interconnect layer portion.

Abstract: A technique capable of stably releasing chips from a dicing tape, includes grinding a back surface of a semiconductor wafer, while adhering a pressure sensitive adhesive tape to a circuit forming surface of the semiconductor wafer formed with an integrated circuit, to achieve a predetermined thickness and forcibly oxidizing the back surface of the semiconductor wafer. Then, the pressure sensitive adhesive tape adhered to the circuit forming surface of the semiconductor wafer is released, and a dicing tape is adhered to the back surface of the semiconductor wafer. Further, the semiconductor wafer is divided by dicing it into individual chips, and then the back surface of the chip is pressed by way of the dicing tape, thereby releasing the chips from the dicing tape.

Abstract: A technique capable of stably releasing chips from a dicing tape, includes grinding a back surface of a semiconductor wafer, while adhering a pressure sensitive adhesive tape to a circuit forming surface of the semiconductor wafer formed with an integrated circuit, to achieve a predetermined thickness and forcibly oxidizing the back surface of the semiconductor wafer. Then, the pressure sensitive adhesive tape adhered to the circuit forming surface of the semiconductor wafer is released, and a dicing tape is adhered to the back surface of the semiconductor wafer. Further, the semiconductor wafer is divided by dicing it into individual chips, and then the back surface of the chip is pressed by way of the dicing tape, thereby releasing the chips from the dicing tape.

Abstract: A technique capable of stably releasing chips from a dicing tape, includes grinding a back surface of a semiconductor wafer, while adhering a pressure sensitive adhesive tape to a circuit forming surface of the semiconductor wafer formed with an integrated circuit, to achieve a predetermined thickness and forcibly oxidizing the back surface of the semiconductor wafer. Then, the pressure sensitive adhesive tape adhered to the circuit forming surface of the semiconductor wafer is released, and a dicing tape is adhered to the back surface of the semiconductor wafer. Further, the semiconductor wafer is divided by dicing it into individual chips, and then the back surface of the chip is pressed by way of the dicing tape, thereby releasing the chips from the dicing tape.

Abstract: A technique capable of stably releasing chips from a dicing tape, includes grinding a back surface of a semiconductor wafer, while adhering a pressure sensitive adhesive tape to a circuit forming surface of the semiconductor wafer formed with an integrated circuit, to achieve a predetermined thickness and forcibly oxidizing the back surface of the semiconductor wafer. Then, the pressure sensitive adhesive tape adhered to the circuit forming surface of the semiconductor wafer is released, and a dicing tape is adhered to the back surface of the semiconductor wafer. Further, the semiconductor wafer is divided by dicing it into individual chips, and then the back surface of the chip is pressed by way of the dicing tape, thereby releasing the chips from the dicing tape.