Purpose
The Research Center for Semiconductor Materials and Advanced Optics (SMAO) is located at Chung Yuan Christian University. Our research center aims to promote the research on both fundamental science and industrial application for next-generation wide-bandgap compound semiconductor materials. We mainly adopt the advanced optical spectroscopy to study the properties of semiconductor materials and devices. The center is devoted to solving the core issues in industrial applications to enhance Taiwan’s research and development capabilities on semiconductor materials. Furthermore, the faculty and equipment in our center also support the teaching and research work related to talent cultivation in the semiconductor college in CYCU. The center aims to assist the Taiwanese semiconductor industry in cultivating high-level talents in semiconductor materials and optoelectronic detection to ensure that Taiwan maintains its leading position in the global semiconductor academic and industrial fields.
Background introduction
Taiwan has a huge advantage in the global semiconductor industry, ranking first in wafer manufacturing and chip packaging, and second in silicon wafer production capacity worldwide. To maintain Taiwan’s leading position in the global semiconductor industry, the Executive Yuan has announced a three-tiered strategy, with the national level focused on ensuring a steady supply of semiconductor talent that meets the quality and quantity demanded by the industry. The strategy also emphasizes strengthening semiconductor research in the areas of silicon-based semiconductors, compound semiconductors, and quantum technology.
According to the National Development Council’s “Three Key Talent Cultivation and Attraction Strategies,” Taiwan needs 136,000 STEM professionals annually, but the country’s universities and colleges can only produce around 97,000 relevant graduates each year. In addition, according to the human resources bank statistics, there is a shortage of 34,000 semiconductor professionals in Taiwan. Furthermore, emerging technologies such as electric vehicles, 5G, artificial intelligence, and high-speed computing all rely on next-generation semiconductor materials such as gallium nitride or silicon carbide power devices, which further increases the demand for semiconductor professionals. Therefore, the semiconductor talent pool and industry chain have become Taiwan’s most important assets for global competitiveness.
In recent years, due to increasing global chip demand, an aging population, and a shortage of STEM talent, Taiwan’s semiconductor human resources have been severely lacking. In response, the Legislative Yuan passed the “National Key Field Industry-Academia Cooperation and Talent Cultivation Innovation Act” last year, declaring semiconductors a national key development area. This has led to the establishment of four semiconductor colleges at National Taiwan University, National Chiao Tung University, National Tsing Hua University, and National Yang Ming Chiao Tung University. The Ministry of Science and Technology also launched research programs such as the “Next-generation Compound Semiconductor Forward-looking R&D Project,” “A-generation Forward-looking Semiconductor Project,” and “Advanced Crystal Project” to enhance Taiwan’s semiconductor research and development capabilities and ensure its future leadership in the industry.
Semiconductors are a multidisciplinary subject that covers areas such as physics, chemistry, chemical engineering, materials science, optoelectronics, electronics, electrical engineering, and mechanical engineering. National Chung Yuan University has a strong foundation in science and technology, with over 65 years of experience and well-established semiconductor and materials-related faculties, state-of-the-art research equipment, and outstanding research capabilities. Furthermore, the university’s research performance in the field of materials science is ranked sixth among all universities and colleges in Taiwan. Therefore, the university should play an important role in semiconductor material research and talent cultivation.
Our aim
In response to the demand for emerging technologies such as electric vehicles, 5G, Internet of Things (IoT), artificial intelligence (AI), and green energy equipment, high-power, high-frequency, and high-speed electronic components have become a major concern for advanced countries around the world. However, the operational voltage limitations of traditional silicon semiconductor devices cannot meet the requirements of these emerging technologies. The most critical semiconductor materials for next-generation electronic components are wide bandgap compound semiconductors, also known as third-generation semiconductors, which mainly include gallium nitride and silicon carbide. In addition, other emerging semiconductor materials such as 2D semiconductor materials are also key materials with great development potential in the future.
Our center focuses on the research and development of next-generation semiconductor crystal materials, including wide bandgap compound semiconductors, 2D semiconductors, organic semiconductors, perovskites, and quantum dots. We also develop advanced optoelectronic detection technology to facilitate basic scientific research on novel semiconductor materials, and are committed to researching key issues related to their applications in the optoelectronic device, green energy, and quantum technology industries.
The main objectives of our center are as follows:
1. Focus on the research and development of next-generation semiconductor materials for basic science and practical applications.
2. Develop non-destructive advanced optoelectronic technology for the detection of next-generation semiconductor materials.
3. Introduce industry resources and work together to solve key issues related to practical applications.
4. Secure research projects from industry, government, and academia to enhance the center’s research and development capabilities.
5. Support the teaching and talent cultivation work of the Semiconductor College of our university.
6. Promote semiconductor material science to high school students and cultivate high school seed teachers.
7. Provide semiconductor material testing and professional analysis services to maintain equipment operation and ensure the sustainable operation of the center.
