摘要:
A semiconductor device 200 comprises a SiCN film 202 formed on a semiconductor substrate (not shown), a first SiOC film 204 formed thereon, a SiCN film 208 formed thereon, a second SiOC film 210 formed thereon, a SiO2 film 212 and a SiCN film 214 formed thereon. The first SiOC film 204 has a barrier metal layer 216 and via 218 formed therein, and the second SiOC film 210 has a barrier metal layer 220 and wiring metal layer 222 formed therein. Carbon content of the second SiOC film 210 is adjusted larger than that of the first SiOC film 204. This makes it possible to improve adhesiveness of the insulating interlayer with other insulating layers, while keeping a low dielectric constant of the insulating interlayer.
摘要:
A semiconductor device 200 comprises a SiCN film 202 formed on a semiconductor substrate (not shown), a first SiOC film 204 formed thereon, a SiCN film 208 formed thereon, a second SiOC film 210 formed thereon, a SiO2 film 212 and a SiCN film 214 formed thereon. The first SiOC film 204 has a barrier metal layer 216 and via 218 formed therein, and the second SiOC film 210 has a barrier metal layer 220 and wiring metal layer 222 formed therein. Carbon content of the second SiOC film 210 is adjusted larger than that of the first SiOC film 204. This makes it possible to improve adhesiveness of the insulating interlayer with other insulating layers, while keeping a low dielectric constant of the insulating interlayer.
摘要:
A semiconductor device 200 comprises a SiCN film 202 formed on a semiconductor substrate (not shown), a first SiOC film 204 formed thereon, a SiCN film 208 formed thereon, a second SiOC film 210 formed thereon, a SiO2 film 212 and a SiCN film 214 formed thereon. The first SiOC film 204 has a barrier metal layer 216 and via 218 formed therein, and the second SiOC film 210 has a barrier metal layer 220 and wiring metal layer 222 formed therein. Carbon content of the second SiOC film 210 is adjusted larger than that of the first SiOC film 204. This makes it possible to improve adhesiveness of the insulating interlayer with other insulating layers, while keeping a low dielectric constant of the insulating interlayer.
摘要:
A semiconductor device 200 comprises a SiCN film 202 formed on a semiconductor substrate (not shown), a first SiOC film 204 formed thereon, a SiCN film 208 formed thereon, a second SiOC film 210 formed thereon, a SiO2 film 212 and a SiCN film 214 formed thereon. The first SiOC film 204 has a barrier metal layer 216 and via 218 formed therein, and the second SiOC film 210 has a barrier metal layer 220 and wiring metal layer 222 formed therein. Carbon content of the second SiOC film 210 is adjusted larger than that of the first SiOC film 204. This makes it possible to improve adhesiveness of the insulating interlayer with other insulating layers, while keeping a low dielectric constant of the insulating interlayer.
摘要:
A semiconductor device has a semiconductor substrate, and a multi-layered wiring arrangement provided thereon. The multi-layered wring arrangement includes at least one insulating layer structure having a metal wiring pattern formed therein. The insulating layer structure includes a first SiOCH layer, a second SiOCH layer formed on the first SiOCH layer, and a silicon dioxide (SiO2) layer formed on the second SiOCH layer. The second SiOCH layer features a carbon (C) density lower than that of the first SiOCH layer, a hydrogen (H) density lower than that of the first SiOCH layer, and an oxygen (O) density higher than that of the first SiOCH layer.
摘要:
A manufacturing method of a semiconductor device including a step of forming a via hole in an insulation layer including an organic low dielectric film, such as MSQ, SiC, and SiCN, and then embedding a wiring material in the via hole through a barrier metal. According to this method, a plasma treatment is performed after the via hole is formed and before the barrier metal is deposited, using a He/H2 gas capable of replacing groups (methyl groups) made of organic constituents and covering the surface of the exposed organic low dielectric film (MSQ) with hydrogen, or a He gas capable decomposing the groups (methyl groups) without removing organic low dielectric molecules. As a result, the surface of the low dielectric film (MSQ) is reformed to be hydrophilic and adhesion to the barrier metal is hence improved, thereby making it possible to prevent the occurrence of separation of the barrier metal and scratches.
摘要翻译:一种半导体器件的制造方法,包括在包括诸如MSQ,SiC和SiCN的有机低电介质膜的绝缘层中形成通孔的步骤,然后通过阻挡金属将布线材料包埋在通孔中。 根据该方法,使用能够代替由有机成分构成的基团(甲基)并覆盖暴露的有机物的表面的He / H 2气体,在形成通孔并且在阻挡金属沉积之前进行等离子体处理 具有氢的低介电膜(MSQ)或能够分解基团(甲基)而不去除有机低介电分子的He气体。 结果,低电介质膜(MSQ)的表面被重新形成为亲水性,因此提高了与阻挡金属的粘合性,从而可以防止隔离金属的分离和划痕的发生。
摘要:
A method of fabricating a semiconductor device using a PECVD method is provided, which improves the adhesion strength of a deposited dielectric layer to an underlying layer and the reliability of the deposited dielectric layer. After placing a substrate in a chamber, a gas having a thermal conductivity of 0.1 W/mK or greater (e.g., H2 or He) is introduced into the chamber, thereby contacting the gas with the substrate for stabilization of a temperature of the substrate. A desired dielectric layer is deposited on or over the substrate in the chamber using a PECVD method after the step of introducing the gas. As the desired dielectric layer, a dielectric layer having a low dielectric constant, such as a SiCH, SiCHN, or SiOCH layer, is preferably used.
摘要翻译:提供了使用PECVD方法制造半导体器件的方法,其提高了沉积的介电层对下层的粘附强度和沉积的介电层的可靠性。 在将基板放置在室中之后,将导热率为0.1W / mK以上的气体(例如H 2 H 2或He)引入到室内,从而使气体与基板接触 稳定基板的温度。 在引入气体的步骤之后,使用PECVD方法将期望的电介质层沉积在室中的衬底上或衬底上。 作为所需的介电层,优选使用具有低介电常数的介电层,例如SiCH,SiCHN或SiOCH层。
摘要:
A manufacturing method of a semiconductor device including a step of forming a via hole in an insulation layer including an organic low dielectric film, such as MSQ, SiC, and SiCN, and then embedding a wiring material in the via hole through a barrier metal. According to this method, a plasma treatment is performed after the via hole is formed and before the barrier metal is deposited, using a He/H2 gas capable of replacing groups (methyl groups) made of organic constituents and covering the surface of the exposed organic low dielectric film (MSQ) with hydrogen, or a He gas capable decomposing the groups (methyl groups) without removing organic low dielectric molecules. As a result, the surface of the low dielectric film (MSQ) is reformed to be hydrophilic and adhesion to the barrier metal is hence improved, thereby making it possible to prevent the occurrence of separation of the barrier metal and scratches.
摘要翻译:一种半导体器件的制造方法,包括在包括诸如MSQ,SiC和SiCN的有机低电介质膜的绝缘层中形成通孔的步骤,然后通过阻挡金属将布线材料包埋在通孔中。 根据该方法,使用能够代替由有机成分构成的基团(甲基)的He / H 2气体,在形成通路孔之后和隔离金属沉积之前进行等离子体处理 并用氢气覆盖暴露的有机低介电膜(MSQ)的表面,或者能够分解基团(甲基)而不去除有机低介电分子的He气体。 结果,低电介质膜(MSQ)的表面被重新形成为亲水性,因此提高了与阻挡金属的粘附性,从而可以防止隔离金属的分离和划痕的发生。
摘要:
A semiconductor device has a semiconductor substrate, and a multi-layered wiring arrangement provided thereon. The multi-layered wring arrangement includes at least one insulating layer structure having a metal wiring pattern formed therein. The insulating layer structure includes a first SiOCH layer, a second SiOCH layer formed on the first SiOCH layer, and a silicon dioxide (SiO2) layer formed on the second SiOCH layer. The second SiOCH layer features a carbon (C) density lower than that of the first SiOCH layer, a hydrogen (H) density lower than that of the first SiOCH layer, and an oxygen (O) density higher than that of the first SiOCH layer.
摘要:
In a method of manufacturing a semiconductor device where at least one insulating layer structure having a metal wiring constitution is formed to thereby construct a multi-layered wiring arrangement, a first SiOCH layer is produced. Then, a surface section of the first SiOCH layer is treated to change the surface section of the first SiOCH layer to a second SiOCH layer which features a carbon (C) density lower than that of the first SiOCH layer, a hydrogen (H) density lower than that of the first SiOCH layer and an oxygen (O) density higher than that of the first SiOCH layer. Finally, a silicon dioxide (SiO2) layer is formed on the second SiOCH layer.