Yet there is no fundamental obstacle to improved modeling and simulation nor to the eventual creation of computer-aided design (CAD) tools for designing plasma reactors.The key missing ingredients are the following: ., application-specific integrated circuits (ASICs), will gain an increasing fraction of the world market in microelectronic components.Tags: Art History Thesis PapersEssay Ambition EngineerEssay About The Book MonsterEssay On Why We Need RulesWriting The Discussion Section Of A Research Paper ApaSystem Development Life Cycle EssayMcat Essay Score RangeMost Common Mistakes In Student Essays
Because of the diversity of applications and the multidisciplinary nature of the science, scientific understanding lags technology. A summary of the many industrial applications of plasma-based systems for processing materials is included in Chapter 2.
Electronics and aerospace are the two major industries that are served by plasma processing technologies, although the automotive industry is likely to become a significant user of plasma-processed materials like those now in widespread use in the aerospace industry.
For example, graduate programs specifically focused on plasma processing are rare because of insufficient funding of university research programs in this field.
By contrast, both Japan and France have national initiatives that support education and research in plasma processing.
: In recent years, the number of applications requiring plasmas in the processing of materials has increased dramatically.
Plasma processing is now indispensable to the fabrication of electronic components and is widely used in the aerospace industry and other industries. economy and national defense, renewed support for low-energy plasma science is imperative.
Applications of plasma-based systems used to process materials are diverse because of the broad range of plasma conditions, geometries, and excitation methods that may be used.
The scientific underpinnings of plasma applications are multidisciplinary and include elements of electrodynamics, atomic science, surface science, computer science, and industrial process control.
Although an impressive arsenal of both experimental and numerical tools has been developed, significant gaps in understanding and lack of instrumentation limit progress.
The broad interdisciplinary nature of plasma processing is highlighted in the discussion of education issues outlined in Chapter 5, which addresses the challenges and opportunities associated with providing a science education in the area of plasma processing.