2021年 第23卷 第4期
《中国工程科学》 >> 2021年 第23卷 第4期 doi: 10.15302/J-SSCAE-2021.04.017
超越巴斯德象限的基础研究动态演化模型及其实践内涵
1. 中国工程物理研究院研究生院,北京 100193;
2. 中国工程科技创新战略研究院,北京 100088
下一篇 上一篇
摘要
国家需求牵引的基础研究关系着我国源头创新能力和国际科技竞争力的提升,是颠覆性科技产生的重要驱动力,对我国创新型国家建设的重要性十分突出。为此,需要深入理解其内涵及基本发展规律,以更好引导基础研究的发展。本文回顾了布什科学研究线性模型的内涵、应用及其如何推广至巴斯德象限模型,在此基础上,考虑时间维度,引入基础度和应用度概念,提出由3个维度刻画的基础研究动态演化模型。为展示基础研究动态演化模型的适用性和优越性,以激光和强激光的发展为案例进行说明,阐述了国家需求牵引下基础研究、应用研究和技术开发之间的相互促进、螺旋上升的互动关系。基于本文模型描述的基础研究发展规律,针对需求牵引的基础研究,今后应更加强调学术诚信及可证伪性;要发挥基础研究对关键技术发展的方向性判定作用,并避免需求牵引引起的主观性诱导和误导。
关键词
基础研究 ; 需求牵引 ; 布什科学研究线性模型 ; 巴斯德象限模型 ; 基础研究动态演化模型 ; 可证伪性
图片
图 1
图 2
图 3
图 4
图 5
图 6
参考文献
[ 1 ] 范内瓦·布什, 拉什·霍尔特. 科学: 无尽的前沿 [M]. 崔传刚 译. 北京: 中信出版社, 2021:13–19. Vannevar B, Rush D H. Science: The endless frontier [M]. Translated by Cui C G. Beijing: China Citic Press, 2021.
[ 2 ] Stokes D E. Pasteur’s quadrant: Basic science and technological innovation [M]. Washington D.C.: Brookings Institution Press, 1997.
[ 3 ] President’s Council of Advisors on Science and Technology. Transformation and opportunity: The future of the U.S. research enterprise [R/OL]. Washington D.C.: President’s Council of Advisors on Science and Technology, 2012. (2012-11-30) [2021-04-12]. https://obamawhitehouse.archives.gov/sites/default/files/microsites/ostp/pcast_future_research_enterprise_20121130.pdf. 链接1
[ 4 ] 116th Congress. Endless frontier act [EB/OL]. (2020-05-21) [2021-04-12]. https://www.congress.gov/bill/116th-congress/senate-bill/3832. 链接1
[ 5 ] 116th Congress. Endless frontier act [EB/OL]. (2020-05-21) [2021-04-12]. https://www.congress.gov/bill/116th-congress/ house-bill/6978. 链接1
[ 6 ] National Academies of Sciences, Engineering, and Medicine. The endless frontier: The next 75 years in science [R]. Washington D.C.: The National Academies Press, 2020.
[ 7 ] 樊春良. 没有止境边疆的科学——《科学: 没有止境的边疆》 75年的历程和影响 [J]. 科技中国, 2020 (7): 56-64. Fan C L. Science of endless frontier: 75 years of history and influence of “Science: Endless frontier” [J]. China Scitechnology Think Thank, 2020 (7): 56-64. 链接1
[ 8 ] Brooks H. The evolution of U.S. science policy. in Bruce L. R. Smith and Claude E. Barfield, eds., Technology, R&D, and the economy [M]. Washington D.C.: Brookings Institution and American Enterprise Institute, 1995: 15-48.
[ 9 ] Organization for Economic Co-operation and Development. Frascati manual 2015: Guidelines for collecting and reporting data on research and experimental development, the measurement of scientific, technological and innovation activities [M]. Paris: Organization for Economic Co-operation and Development Publishing, 2015: 50–51.
[10] Townes C H. 1964 Nobel lecture: Production of coherent radiation by atoms and molecules [EB/OL]. (1964-11-11) [2021-04-12]. https://www.nobelprize.org/uploads/2018/06/townes-lecture.pdf. 链接1
[11] Maiman T. Stimulated optical radiation in Ruby [J]. Nature, 1960, 187: 493-494. 链接1
[12] Dicke R H. Object detection systems [P]. Patent U.S. 2, 624, 876, 1953.
[13] Darlington S. Pulse transmission [P]. Patent U.S. 2, 678, 997, 1954.
[14] Strickland D, Mourou G. Compression of amplified chirped optical pulses [J]. Optics Communications, 1985, 56(3): 219-221. 链接1
[15] Global Research Council. Statement of principles for the dynamic interplay between fundamental research and innovation [EB/OL]. (2017-10-30) [2021-04-30]. https://www.globalresearchcouncil. org/fileadmin//documents/GRC_Publications/Statement_of_ Principles_for_The_Dynamic_Interplay_Between_Fundamental_ Research_and_Innovation.pdf. 链接1
[16] 阎康年. 科学界的诚信——舍恩事件始末综述 [J]. 国外科技动 态, 2002 (11): 14-17. Yan K N. Integrity in the scientific community: A review of the Schoen case [J]. Scientific & Technological Trend Abroad, 2002 (11): 14-17. 链接1
[17] 尤吉尼 • 塞缪尔 • 瑞驰. 科学之妖 [M]. 北京: 科学出版社, 2010. Reich E S. Plastic fantastic: How the biggest fraud in physics shook the scientific world [M]. Beijing: Science Press, 2010.
[18] 张慧琴, 平婧, 孙昌璞. 分类支持基础研究 促进全链条颠覆性技 术创新 [J]. 中国工程科学, 2018, 20(6): 24-26. Zhang H Q, Ping J, Sun C P. Supporting basic research by classification to promote whole-chain disruptive technology innovation [J]. Strategic Study of CAE, 2018, 20(6): 24-26. 链接1
[19] The National Cyber Security Centre. Quantum security technologies [EB/OL]. (2020-03-24) [2021-04-12]. https://www.ncsc.gov. uk/whitepaper/quantum-security-technologies. 链接1
[20] The National Cyber Security Centre. Preparing for quantum-safe cryptography [EB/OL]. (2020-05-04) [2021-04-12]. https://www. ncsc.gov.uk/whitepaper/preparing-for-quantum-safe-cryptography. 链接1
[21] The French National Agency for the Security of Information Systems (ANSSI). Should quantum key distribution be used for secure communications? [EB/OL]. (2020-11-11) [2021-04-12]. https://www.ssi.gouv.fr/uploads/2020/05/anssi-technical_position_ papers-qkd.pdf. 链接1
[22] National Security Agency Central Security Service (NSA|CSS). NSA cybersecurity perspectives on quantum key distribution and quantum cryptography [EB/OL]. (2020-10-26) [2021-04-12]. https://www.nsa.gov/News-Features/Feature-Stories/Article-View/ Article/2394053/nsa-cybersecurity-perspectives-on-quantum-key-distribution-and-quantum-cryptogr/. 链接1
[23] Lieven L B. Teapot supremacy [EB/OL]. (2021-03-13) [2021-04- 12]. http://www.neverendingbooks.org/teapot-supremacy. 链接1
[24] Scott A. Doubts about teapot supremacy: My reply to Richard Borcherds [EB/OL]. (2021-03-13) [2021-04-30]. https://www. scottaaronson.com/blog/?p=5460. 链接1
[26] Global Research Council. Statement of principles for funding scientific breakthroughs [EB/OL]. (2015-05-28) [2021-04-30]. https://www.globalresearchcouncil.org/fileadmin//documents/ GRC_Publications/Statement_of_Principles_for_Funding_Scientific_Breakthrough.pdf. 链接1
京公网安备 11010502051620号
