2017, Volume 19, Issue 3
Strategic Study of CAE >> 2017, Volume 19, Issue 3 doi: 10.15302/J-SSCAE-2017.03.018
The Development Status and Prospect of China’s Critical Basic Materials
General Research Institute for Nonferrous Metals, Beijing 100088, China
Next Previous
Abstract
Critical basic materials are a key factor in the development of the manufacturing industry. In addition, they play an important role in economic development and in the construction of the national defense industry. This paper describes the current status of critical basic materials in China and abroad, and presents related challenges that are confronting domestic enterprises. Finally, it puts forward suggestions for government policies that will promote the development of critical basic materials.
Keywords
critical basic materials ; development status ; policy suggestion
Figures
Fig. 1
Fig. 2
Fig. 3
Fig. 4
Fig. 5
Fig. 6
Fig. 7
References
[ 1 ] Ministry of Industry and Information Technology of the PRC. Guidelines for implementation of strong industrial engineering (2016–2020) [R]. Beijing: Ministry of Industry and Information Technology of the PRC, 2016. Chinese.
[ 2 ] Tu H L, Zhang S R, Li T F. Research on development strategies for China’s advanced materials industry [J]. Strategic Study of CAE, 2016, 18(4): 90–100. Chinese. link1
[ 3 ] Tu H L, Zhou J, Zhang G. The growth technology for 300 mm sin-gle crystal silicon [J]. Microelectronic Engineering, 2001, 56(1): 77–82. link1
[ 4 ] Wang J Y, Wu Y C. Progress of the research on photo electronic functional crystals [J]. Materials China, 2011, 29(10): 1–12. link1
[ 5 ] Zhang X M. Basic research on high performance aluminum alloy materials for aviation [J]. China Science and Technology Achieve-ments, 2016, 17(17): 18–19. Chinese.
[ 6 ] Chang H, Zhou L, Wang X D. Development and future of Chinese titanium industry and technology [J]. Journal of Aeronautical Ma-terials, 2014, 4(4): 38–43. Chinese. link1
[ 7 ] Zhou J. Some ideas on the combination of metamaterials and natural materials [J]. Advanced Materials Industry, 2014 (9): 5–8. Chinese. link1
[ 8 ] Pu J B, Wang L P, Xue Q J. Progress of tribology of graphene and graphene-based composite lubricating materials [J]. Tribology, 2014, 34(1): 93–112. Chinese. link1
[ 9 ] Shi C X. Reflections on the construction of China’s “new material industry system” [J]. Journal of Engineering Studies, 2013, 5(1): 5–11. Chinese. link1
[10] Xu K D, Ren Z M, Li C J. Progress in application of rare metals in super alloys [J]. Rare Metals, 2014, 33(2): 111–126. link1
[11] Xu N P. The development and prospect of the research on film field in China [R]. Tianjin: The 6th national symposium of film and film process, 2008. Chinese.
[12] National Energy Administration of the PRC. Photovoltaic power generation statistics for 2016 [EB/OL]. (2017-02-04) [2017-03-16]. http://www.nea.gov.cn/2017-02/04/c_136030860.htm. Chinese.
[13] China Soled State Lighting Alliance. The annual white paper on the development of semiconductor lighting industry in 2016 [R]. Beijing: China Soled State Lighting Alliance, 2016. Chinese.
[14] Ting F X. Current status and development trend of biomedical ma-terials in China [J]. China Medical Device Information, 2013 (8): 1–5. Chinese. link1
[15] Du X W, Yang B, Liu X L, et al. Decoupling analysis of China’s economic development, energy consumption and carbon dioxide emission [J]. China Population, Resources and Environment, 2015, 25(12): 1–7. Chinese.
[16] Gan Y, Li G Y, Ma M T, et al. Development of advanced compact steel process and deep working technology for high-strengthduc-tility auto-parts [J]. Steel Rolling, 2015, 32(4): 1–11. Chinese. link1
[17] Xie J X, Liu X F, Zhou C, et al. Intelligentization of materials pro-cessing technology [J]. Chinese Journal of Mechanical Engineer-ing, 2005, 41(11): 8–14. Chinese. link1
[18] Xing L Y, Bao J W, Li S M, et al. Development status and facing challenge of advanced polymer matrix composites [J]. Acta Mate-riae Compositae Sinica, 2016, 33(7): 1327–1338. Chinese. link1
[19] Yao Y, Wang X, Yan B L, et al. The research on heavy metal ionscuring and its influence on the cement hydration process [J]. Bulletin of the Chinese Ceramic Society, 2012, 31(5): 1138–1144. Chinese. link1
[20] Lu S G, Shi Q T, Tang H B. Mathematical analysis and numerical simulation for thermo-stress in a square lithium-ion battery [J]. Journal of Automotive Safety and Energy, 2014, 5(3): 298–303. Chinese.
[21] Yin R Y. Process engineering and manufacturing process [J]. Iron & Steel, 2014, 49(7): 15–22. Chinese. link1
[22] Chinese Academy of Engineering. Strategy research of special steel in advanced equipment manufacturing application advisory report [R]. Beijing: Chinese Academy of Engineering, 2012.
[23] Chinese Academy of Engineering. The present situation and de-velopment strategy of nonferrous rare metal materials in China (2010–2012) [R]. Beijing: Chinese Academy of Engineering, 2012. Chinese.
[24] Tu H L. Research report on the cultivation and the development of new materials industry [M]. Beijing: China Science Publishing & 138Development Status and Prospects of China’ Critical Basic MaterialsMedia Ltd (CSPM), 2014. Chinese.
[25] China Institute of Engineering Development Strategy. Develop-ment report of China’s strategic emerging industries (2014) [M]. Beijing: China Science Publishing & Media Ltd (CSPM), 2013. Chinese.
[26] Tu H L. 450 mm silicon wafers are imperative for Moore’s law but maybe postponed [J]. Engineering, 2015, 1(2): 162–163. link1
[27] Li L T. Research progress of functional ceramic materials [J]. Functional Materials Information, 2005, 2(1): 10–14. Chinese. link1
[28] The development course and future outlook of semiconductor lighting technology industry in China [J]. Electronics World, 2016 (6): 7. Chinese.
[29] Cui Y, Li Y, Luo K, et al. Research progress on biomedical Ni-Free Ti based shape memory alloys [J]. Rare Metal Materials and Engineering, 2010, 39(9): 1682–1686. Chinese. link1
[30] Li Z P. Major Advancement and development trends in study of hotwall microwave-transparency mechanisms and high-tempera-ture microwave-transparent materials [J]. Materials China, 2013, 32(4): 193–202. Chinese. link1
[31] Chen X B, Zhang B Y, Li B T. Low temperature cure high perfor-mance composites [J]. Journal of Materials Engineering, 2011 (1): 1–6. Chinese. link1
[32] Xu Q Y, Pan D, Yu J, et al. Application of numerical simula-tion technology in superalloy single crystal blade of aeroengine [J]. Aeronautical Manufacturing Technology, 2011 (4): 26–31. Chinese. link1
[33] Zhang X D, Wang B T. The rise of biological materials science and industry in China [J]. Advanced Materials industry, 2009 (10): 92–95. Chinese. link1
[34] Wang Y J, Du C, Zhao N R, et al. Biomimetic artificial bone re-pair materials: A review [J]. Journal of South China University of Technology (Natural Science Edition), 2012, 40(10): 51–58. link1
[35] Li G X. Coming challenge and opportunity to the nuclear fuel cy-cle industry of China [J]. Uranium Geology, 2008, 24(5): 257–267. Chinese. link1
[36] Tan T W. The development trend of green bio-manufacturing in-dustry [J]. Biotechnology & Business, 2015 (6):13–15. Chinese.
[37] Nie Z R, Gao F, Gong X Z, et al. Recent progress and application of materials life cycle assessment in China [J]. Progress in Natural Science: Materials International, 2011, 21(1): 1–11. link1
[38] Xu H B, Gong S K, Jiang C B, et al. Solid-state phase transfor-mations and their applications in special functional materials [J]. Materials China, 2011, 30(9): 1–13. Chinese. link1
[39] Chen L Q. The materials genome initiative and advanced materials [J]. Engineering, 2015, 1(2): 169. link1
[40] Gerbrand C, Kristin P. How supercomputers will yield a golden age of materials science [J]. Scientific American, 2013 (3): 36–40.
[41] Jain A ,Ong S P, Hautier G, et al. The materials project: A materi-als genome approach to accelerating materials innovation [J]. APL Materials, 2013, 1(1): 2166–2176.
京公网安备 11010502051620号
