Strategies of materials development and manufacturing and their effects for Chinese high-tech industries

被引：0

作者：

Jin Z. ^{[1
]}

Cai G. ^{[1
]}

Su L. ^{[1
]}

Fan X. ^{[1
]}

Zheng F. ^{[1
]}

机构：

[1] School of Materials Science and Engineering, Central South University, Changsha

来源：

Zhongguo Kexue Jishu Kexue/Scientia Sinica Technologica | 2016年 / 37卷 / 09期

关键词：

Industry chain; Knowledge base; Materials and their manufacturing and fabrication system; Materials designing; Microstructure evolution;

D O I：

10.1360/N092016-00031

中图分类号：

学科分类号：

摘要：

In order to catch up and compare with global competition in fields of industries, we state relevant arguments here as follows. 1) How could materials science meet the challenge of ever-increased development of advanced technologies? 2) The development of basic knowledge for microstructure evolution. 3) Newly-developed and developing industry chains are output of multidisciplinary integration occurred in advanced technologies. 4) What could we learn from global experience of novel materials and their manufacturing and fabrication? 5) Designing Chinese knowledge system of novel materials and their manufacturing and fabrication. 6) Where is our roadmap? What are tasks of emergency and measures of implementation for the 13th Five Year Plan? 7) Creating knowledge system of novel materials and their manufacturing and fabrication is one of the forward-looking strategies to build a strong state with advanced and powerful manufacturing and fabrication system. Implementing the so-called five development concepts of "innovation, harmony, green, open and sharing" is the key factor. © 2016, Science Press. All right reserved.

引用

页码：877 / 893

页数：16

共 34 条

[1] Cheng S.Z.D., Phase Transitions in Polymers-The Role of Metastable States, (2008)
[2] Zeng K., Tu K.N., Six cases of reliability study of Pb-free solder joints in electronic packaging technology, Mater Sci Eng R, 38, pp. 55-105, (2002)
[3] Lee B.J., Hwang N.M., Lee H.M., Prediction of interface reaction products between Cu and various solder alloys by thermodynamic calculation, Acta Mater, 45, pp. 1867-1874, (1997)
[4] Kuo K., Metallography of delta-ferrite. Part I: Eutectoid decomposition of delta-ferrite, J Iron Steel Inst, 176, (1955)
[5] Kuo K., Metallography of delta-ferrite. Part II Formation of delta-eutectoid in 18-4-1-type high-speed steels, J Iron Steel Inst, 181, (1955)
[6] Kuo K., Metallography of delta-ferrite. Part III: Isothermal transformation of delta-ferrite in a low-carbon 27-5-1.5 Cr-Ni-Mo corrosion-resistant steel, J Iron Steel Inst, 181, (1955)
[7] Kuo K., Metallography of delta-ferrite. Part IV: Decomposition of delta-ferrite between 650℃ and 1000℃ in a low-carbon 18-10-3 Cr-Ni-Mo corrosion-resisting steel, J Iron Steel Inst, 181, (1955)
[8] Kuo K., Metallography of delta-ferrite. Part V: δ-Eutectoid and the constitution diagram of the Fe-M-C system, J Iron Steel Inst, 181, (1955)
[9] Fridberg J., Hillert M., On the eutectoid transformation of δ-ferrite in Fe-Mo-C alloys, Acta Metall, 25, pp. 19-24, (1977)
[10] Oikawa K., Ohtani H., Ishida K., Et al., The control of the morphology of MnS inclusions in steel during solidification, ISIJ Int, 35, pp. 402-408, (1995)

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