加拿大论文代写

多伦多大学代写:硅晶体生长与晶圆技术

多伦多大学代写:硅晶体生长与晶圆技术

这篇文章的目的是批判性地评论一篇文章。本文选择的这篇文章是Graham Fisher和Robert Standley(2012)所著的《硅晶体生长与晶圆技术》。本文讨论了半导体硅晶片技术的历史沿革,包括近年来晶片的晶片和成长性的发展。进一步的讨论集中于技术,以更好地了解CMOS的当前性能。

多伦多大学代写:硅晶体生长与晶圆技术

在这篇文章中,我们很好地认识到,硅基板是建立模型微电子(Buonassisi, 2016)的基础。虽然硅片技术最初的50年主要是由工业微电子驱动的,但光电技术的应用推动了矽晶圆技术的新进展。该研究通过回顾该技术的过去的发展和发展,进一步突出了在晶片技术和大量晶体生长方面的最新技术进步(Dahiya, 2016)。

多伦多大学代写:硅晶体生长与晶圆技术

The aim of this essay is to critically review an article. The article selected for this purpose is “Silicon Crystal Growth and Wafer Technologies” by Graham Fisher and Robert Standley (2012). This article discusses on the historical establishment of wafer technology with semiconductor silicon that include the recent advancements of wafering and growth in bulk crystals. Further discussion focuses on technologies for better understanding the current capabilities of CMOS.

多伦多大学代写:硅晶体生长与晶圆技术
It is well acknowledged in the article that silicon substrates are responsible for establishing the fundamental base of model microelectronics (Buonassisi, 2016). While the initial 50 years for technology of silicon wafer were driven primarily by the industry microelectronics, the application of photovoltaics has been driving the new advancements in technology of silicon wafer. The research reflects its effectiveness by reviewing the past development and evolution of this technology by further highlighting the latest technical advancements in wafering technologies and bulk crystal growth (Dahiya, 2016).