Abstract: An integrated circuit chip and test method thereof are provided. The integrated circuit chip of the disclosure includes a first chip circuit and a plurality of external pins. The first chip circuit includes a plurality of first internal pads, a plurality of second internal pads and a current mirror circuit. The current mirror circuit is coupled to one of the plurality of first internal pads and the plurality of second internal pads. The plurality of external pins are coupled to the plurality of first internal pads.

Abstract: An integrated circuit chip and test method thereof are provided. The integrated circuit chip of the disclosure includes a first chip circuit and a plurality of external pins. The first chip circuit includes a plurality of first internal pads, a plurality of second internal pads and a current mirror circuit. The current mirror circuit is coupled to one of the plurality of first internal pads and the plurality of second internal pads. The plurality of external pins are coupled to the plurality of first internal pads.

Abstract: A method for fabricating semiconductor devices with fine patterns includes the steps of providing a semiconductor substrate, forming a first photoresist layer on the semiconductor substrate, forming a second photoresist layer on the first photoresist layer, and performing an exposing process to change the state of at least one first portion of the first photoresist layer and the state of at least one second portion of the second photoresist layer. The conventional double patterning technique requires that the exposure processes be performed twice, which requires very precise alignment between the two exposure processes. In contrast, the embodiment of the present invention can perform the double patterning process with only one exposure process without requiring the precise alignment between the two exposure processes.

Abstract: Litho-litho-etch double patterning (LLE-DP) methods using silylation freeze technology are presented. The LLE-DP method using a silylation freeze reaction comprises providing a substrate with a first photoresist layer thereon. A first exposure process is performed defining a first latent image in a first photoresist. The first patterned structures on the substrate is developed and baked for photo-generated acid diffusion. The photo-generated acid is reacted with a silylation agent to freeze the first patterned structures. A second photoresist layer is formed overlying the substrate. A second lithography process is performed to create second patterned structures on the substrate. The first patterned structures and the second patterned structures are interlaced each other.

Abstract: An apparatus for homogenizing the developer concentration on the wafer and reducing the developer cost and the method thereof are provided in the present invention. The developer is provided on the wafer which then is spun to distribute the developer on the wafer. Next, the mechanical turbulence of the developer is produced on the wafer by the turbulence device or the mega-sonic vibrator. The apparatus is able to improve the uniformity of developer concentration, and the developer consumption is reduced.

Abstract: A gap-filling process is provided. A substrate having a dielectric layer thereon is provided. The dielectric layer has an opening therein. A gap-filling material layer is formed over the dielectric layer and inside the opening. A portion of the gap-filling material is removed from the gap-filling material layer to expose the dielectric layer. A gap-filling material treatment of the surface of the gap-filling material layer and the dielectric layer is carried out to planarize the gap-filling material layer so that a subsequently formed bottom anti-reflection coating or material layer over the gap-filling material layer can have a high degree of planarity.

Abstract: A gap-filling process is provided. A substrate having a dielectric layer thereon is provided. The dielectric layer has an opening therein. A gap-filling material layer is formed over the dielectric layer and inside the opening. A portion of the gap-filling material is removed from the gap-filling material layer to expose the dielectric layer. A gap-filling material treatment of the surface of the gap-filling material layer and the dielectric layer is carried out to planarize the gap-filling material layer so that a subsequently formed bottom anti-reflection coating or material layer over the gap-filling material layer can have a high degree of planarity.