Pushing semiconductor manufacturing equipment capabilities to the physical limits is a must to follow Moore's Law in the mid-term future. That is why a novel paradigm of developing new semiconductor manufacturing equipment is needed. Already during the early stages of equipment development, it is inevitable to know as much as possible about the future equipment behavior. Equipment developers need to know about the influence of their development measures on the process and even on interdependencies with other processes to successfully design new leading edge equipment. Therefore, a continuous simulation chain is appropriate to get as much information as possible prior to manufacturing the first physical prototype. This paper presents the first-time demonstration of such a continuous simulation chain ranging from the CAD model of a semiconductor manufacturing equipment to the run time behavior of a transistor device fabricated with that equipment. Based on the concept of Virtual Equipment Engineering this approach allows to keep the simulation chain consistent through changes in the CAD model without manually updating the equipment simulation models. The development of an oxidation reactor is used as an example to demonstrate the principle possibility of such a simulation chain. Within this example the programs used are PTC Pro/ENGINEER, ESI CFD-ACE and Synopsys SProcess.
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机译:将半导体制造设备的能力推向物理限制是必须在中期未来遵循摩尔法的必要。这就是为什么需要开发新的半导体制造设备的新型范式。已经在设备开发的早期阶段,这是不可避免的,尽可能多地了解未来的设备行为。设备开发人员需要了解他们的发展措施对过程的影响,甚至在与其他流程中成功设计新的前沿设备的相互依赖性。因此,连续仿真链适合于在制造第一物理原型之前尽可能多地获取多重信息。本文介绍了从半导体制造设备的CAD模型的第一次演示,从半导体制造设备的CAD模型到与该设备制造的晶体管器件的运行时间行为。基于虚拟设备工程的概念,这种方法允许通过CAD模型的变化保持模拟链,而无需手动更新设备仿真模型。氧化反应器的发展用作示例以证明这种模拟链的原理可能性。在此示例中,使用的程序是PTC Pro / Engineer,ESI CFD-ACE和Synopsys Sprecess。
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