Abstract
This paper describes the analysis of processes used in microand nanoelectronic device manufacturing. It also presents an exemplary and novel laboratory exercise in which an epitaxial planar n + pn bipolar transistor with junction isolation is illustrated and analyzed stepbystep. Only seven photolithography steps are used to obtain this bipolar transistor structure: for buried layer formation, for junction transistor isolation and collectors regions formation, for base region formation, for emitter and collector n+ region formation, for contact windows, for first aluminum metallization, and, finally, for passivation. Silvaco TCAD software tools are used to implement all of these manufacturing processes and to simulate the resulting IV characteristics of all presented semiconductor structures. This type of laboratory work provides students with basic knowledge and a consistent understanding of bipolar transistor manufacturing, as well as facilitating theoretical understanding, analysis, and simulation of various semiconductor manufacturing processes without the need for costly and lengthy technological manufacturing experiments. This article also presents the conclusions and other benefits of such laboratory work, as well as possible recommendations for further improvement or expansion.
Highlights
One of the most characteristic features of today’s scientific and technical progress is the extent to which electronic devices are used in many human activities, ranging from personal health to public safety, aerospace and defense
The elemental basis of such electronic devices consists of transistors, diodes, resistors, capacitors, and other elements designed and implemented in advanced micro- and later in nano-electronics
We describe the analysis of the processes used in micro- and nano-electronic device manufacturing
Summary
One of the most characteristic features of today’s scientific and technical progress is the extent to which electronic devices are used in many human activities, ranging from personal health to public safety, aerospace and defense. Based on recent scientific research, the economic analysis of market trends, and their contribution to social challenges, the European Union’s (EU) Key Enabling Technologies (KET) include micro- and nano-electronics, nanotechnology, photonics, advanced materials, industrial biotechnology, and advanced manufacturing technologies (European Commission, 2012) These technologies are an engine of economic and technological development, as well as a major driver of innovation. It is forecasted that, during this period, about 0,55 million workplaces of this occupation will be created in the USA (United States Department of Labor, 2019) Such rapid growth and development pose increasingly difficult challenges for higher education institutions. We an example of a laboratory work where students use Silvaco TCAD software tools to apply a step-by-step approach to the design and simulation of an epitaxial planar n + pn transistor with junction isolation
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