The Need for the ITRW

Riding the waves of wide bandgap semiconductor

Research and development activities in wide bandgap (WBG) devices have grown fast to the extent that good quality production devices are entering into the commercial market. The increasing interest and activities in the WBG devices arise from three facts.

  1. The limitation of traditional Si devices. The attempt to drive towards a viable 7-nm process, which is known to reach the physical limitation of ten Si atoms, have been delayed due to the complex procedures and requirement for expensive fabrication equipment. In addition, ever-increasing power density and heat dissipation requirements also pose significant obstacles to the commercialization of a 7-nm process. These are reasons why Intel, the leading giant in Si devices for high density processors publicly announced that they hold conservative opinions on the mass production of 7-nm Si devices in the future[1]. The WBG semiconductor is regarded as one of the major steps forward in the seemingly darkest age of Si devices since the establishment of Moore’s law. WBG materials have superior advantages for many applications, especially power electronics, including higher mobility, higher electron density, higher breakdown voltage and higher heat conductivity. Moreover, under the similar working principles, many of the standard Si-based processes can be adapted for wide band-gap, which will potentially reduce investment cost and shorten development cycles.
  2. The emergence of new devices and extended applications   With the aforementioned advantages, WBG devices are highly suitable to harsh working conditions such as high voltage, high temperature, high frequency, and high radiation exposure, which extend their application to extreme environments such as outer space to deep sea. For example, applications now using WBG devices include spacecraft, aircraft, high-speed trains, ocean oil drilling platform, EV/HEV and intelligent manufacturing. The working voltage in these applications can reach as high as 10 kV, and the heat flux can exceed 1*107 W/m2, which is far beyond the realm of Si devices. Furthermore, with the new concept of internet of things (IoT), many application areas are developing very quickly, including smart cities and big data, new sensors, MEMS, smart power system and 5G communication networks. Those application areas require new technologies such as power electronics, RF devices and solid state lighting. For those technologies, WBG devices are the key and are considered as the driving force for next-generation electronic industries.
  3. The ever-increasing need for low carbon emission and energy saving. Global economic growth results in increasing consumption of fossil fuels and excessive CO2 emission. According to the EIA report, only 50% of the generated energy will reach the end-load. Green energy, EV/HEV, high efficiency power module are three potentially dominant solutions for energy saving, and WBG devices will play an indispensable role in all of them. As we approach 2020, when the total CO2 should have decreased by 40%, wide band-gap devices will play an even more significant role in enhancing the the world economy and environment.

In a nutshell, wide bandgap devices have the potential to be the most important devices for the future of both microelectronics and power electronics, and have great potential to be one of the major engines of driving the world economy over the next several decades. Recognizing current trends and facts, there are clear requirements from industry, academia, education and public authorities to have a reliable and comprehensive view on the strategic research agenda and a technology roadmap for wide bandgap semiconductor devices. This is the primary motivation to establish the International Technology Roadmap for Wide Bandgap Power Semiconductors (ITRW). The ITRW working group will provide insightful strategic research and roadmap on biennial basis, and provide professional reference and guidelines to industry, academia, education and public authorities.

2016 has been identified as an optimal year for an ITRW for the following reasons.

  • Timing.After years of dedicated research and development, wide band-gap semiconductors are increasingly showing significant technology prospects and potential to return business value. 
  • Technology Maturity. The wafer manufacture and post process are becoming mature, therefore the costs can be confidently controlled within a marketable range. Recently, here has been a complementary expansion of bespoke circuit design companies, fabrication facilities, dedicated WBG modules and packaging technology, and system integration companies focussed on wide band-gap devices.
  • Notability. Compared to the Silicon age, the emergence of wide band-gap devices is a more global process. Participants from all over the world are at a similar status, preparing for the take-off of the wide band-gap industry. The ITRW can help provide guidance and a neutral forum to assist this global effort, which will benefit the world economy.

Working Groups

Technical analysis will be carried out by the ITRW working groups. The working groups will meet regularly and report back to the steering committee at the executive meetings held during the major conferences in the power electronics field. The initial subgroups in the technical committees have been identified as:

  1. Materials and Devices
  2. Packaging and Integration
  3. System Integration and Application:  SiC
  4. System Integration and Application:  GaN


The working group scope includes:

  • Acknowledging Moore’s law, ITRW will be an engine of the virtuous cycle, i.e. with power density scaling, improved performance, improving cost ratio, and finally the market and economy. The growth of the market will in turn benefit from new technology investment and development. Therefore, the ITRW will provide solid supporting evidence for the technical feasibility and the underpinning economic validity of this ecosystem.
  • The ITRW also has a strong prespective effect; it will provide research guidance, landscape analysis and applications forecasting for the actors in the semiconductor ecosystem. Therefore, it will significantly contribute to technology exploration and increase resource efficiency in the very fast technological development of the industry.

[1] Intel Abandoning Silicon With 7nm and Beyond – Silicon Alternatives Coming By 2020 (http://wccftech.com/intel-abandoning-silicon-7nm/)

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