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The Dynamics of Generic Technology Emergence Based on TERGMs: The Example of Supercapacitor Green Energy Storage Technology |
Tang Yujie1,Li Yang2 |
(1.College of Economics and Management, Zhengzhou University of Light Industry,Zhengzhou 450002,China;2.School of Management, Henan University of Technology, Zhengzhou 450002, China) |
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Abstract Since the technology emergence theory has gained much research attention, scholars have discussed the emergence of new technologies,technology breakthroughs and creative technologies.However, under the new wave of technological revolution and "anti-globalization," international industrial competition extends from frontier technology to generic technology.Because generic technology can be applied in many industries and restrict the development of industry technology,the emergence mechanism of the generic technology can provide a beneficial reference for China to break through the technology blockade and realize scientific and technological self-reliance.However, few studies have explored the emergence of generic technologies, failing to answer questions such as where they come from, why they arise, and what the emergence mechanism is.Reviewing the existing research on generic technology, this study confirms that the two research themes are "generic technology supply" and "generic technology identification." However, current studies have yet to answer the question of how generic technology emerges, which provides a research opportunity for this paper.#br#According to the technology emergence theory, technology emergence refers to the dynamic evolution process in which technology synergy, novelty, functionality, and other dynamic factors at the micro level can promote the continuous establishment and maintenance of long-term interactive relations among technologies in a highly creative technology network, and thus promote the gradual emergence of technologies at the macro level.Following this theory, this study adopts the TERGMs (time-series exponential stochastic model) method and constructs a dynamic model for the emergence of generic technologies to reveal the dynamic mechanism driven by the dynamic factors of technology synergy, novelty and functionality.#br#This paper takes the supercapacitor energy storage technology as an example because supercapacitor energy storage technology is a new green technology with an electric energy storage function.In the context of carbon peak and carbon neutrality, several generic technologies are likely to emerge in this domain.First,the study obtains the IPC code for identifying electrical energy storage according to the IPC green inventory provided by the World Intellectual Property Organization (WIPO).Then, this paper uses the De Winter Index of Innovation (DII) as the patent data source and finally gets 9 033 supercapacitor energy storage technology patents from 1985 to 2021.Using TERGMs, the study empirically tests the driving effects of synergism (indicators including k-star, k-triangle, and k-twopath), novelty (indicators including forward citation, backward citation, and science citation) and functionality (indicators including portfolio size and industry diversity) on the emergence of co-occurring technologies.#br#The results show that k-star and k-triangle significantly contribute to the emergence of generic technologies for technology synergy, while k-twopath is not significant.For technology novelty, forward citation significantly contributes to the emergence of generic technologies, while science citation has a significant negative effect, and backward citation does not have a significant effect.For technology functionality, industry diversity significantly contributes to the emergence of generic technologies, while portfolio size has no significant impact.#br#This paper has implications for companies and governments in understanding how generic technology emerges.(1)Compared with the backward reference, technologies with a more forward reference are more likely to become generic technologies because these technologies usually have strong technical influence.In addition, technologies with more scientific citations also have the potential to grow into generic technologies because they are closer to scientific discovery.Finally, the technologies with cross-industry application scenarios should also be paid attention to,as these technologies may become essential for the collaborative development of multi-industries.(2) Because of the "Matthew effect", the core technologies in the center of the technology network usually develop into generic technologies and become the potential objects of technology blockade.To avoid the generic technology being “blocked,” the government should make relevant policies and create a loose research and development environment, guide technology researchers to explore the new track of technology development, and vigorously develop alternative technologies by using particular science and technology projects.Universities and research institutes are encouraged to conduct primary research on various alternative technologies by giving full play to their advantages, such as a complete range of disciplines and a concentration of talents.#br#
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Received: 25 August 2022
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[1] KAPOOR R,KLUETER T.Progress and setbacks: the two faces of technology emergence[J].Research Policy,2020,49(1): 103874. [2] BURMAOGLU S,SARTENAER O,PORTER A.Conceptual definition of technology emergence:a long journey from philosophy of science to science policy[J].Technology in Society,2019,59: 101126. [3] ROTOLO D,HICKS D,MARTIN B R.What is an emerging technology[J].Research Policy,2015,44(10): 1827-1843. [4] LI M,WANG W,ZHOU K.Exploring the technology emergence related to artificial intelligence:a perspective of coupling analyses[J].Technological Forecasting and Social Change,2021,172: 121064. [5] WOOLLEY J.Technology emergence through entrepreneurship across multiple industries[J].Strategic Entrepreneurship Journal,2010,4(1): 1-21. [6] 陈傲,柳卸林,高广宇.突破性技术发明的涌现轨迹——以心脏起搏器行业为例[J].系统工程,2011,29(9): 1-8. [7] 毛荐其,刘娜.技术生态视野下的新技术涌现机理探析[J].管理世界,2011,27(12): 182-183. [8] 周军.创造性技术涌现中的政府模式选择[J].河南大学学报(社会科学版),2017,57(2): 8-14. [9] 郑月龙,刘思漫,白春光.考虑多主体参与的产业共性技术研发模式比较研究[J].中国管理科学,2021,29(8): 44-56. [10] 郑月龙,王琳.多企业共性技术合作研发行为的演化动态[J].系统工程,2018,36(2): 71-79. [11] 秦佳良,张玉臣,贺明华.技术—市场双重未知下企业共性技术设计:从试错学习到共同未知[J].中国科技论坛,2019,36(7): 128-137. [12] 郑月龙,秦国静.政府补贴对产业共性技术可持续研发行为的影响研究[J].研究与发展管理,2021,33(3): 121-145. [13] 樊霞,陈双丽.产学研合作更有利于产业共性技术研发创新吗——对USPTO中国专利数据的实证检验[J].科技进步与对策,2016,33(13): 59-65. [14] 郑彦宁,浦墨,刘志辉.基于产业创新链的产业共性技术识别基本理论探讨[J].情报理论与实践,2016,39(9): 53-58. [15] 陈伟,林超然,孔令凯.基于专利文献挖掘的关键共性技术识别研究[J].情报理论与实践,2020,43(2): 92-99. [16] 马永红,孔令凯,林超然.基于专利挖掘的关键共性技术识别研究[J].情报学报,2020,39(10): 1093-1103. [17] 郑赛硕,王学昭,陈小莉.共性技术识别方法构建与实证研究——以集成电路行业为例[J].图书情报工作,2021,65(15): 130-139. [18] HOLLAND J H.Emergence: from Chaos to order[M].Oxford:Oxford University Press,2000. [19] CORNING P A.The re-emergence of "emergence": a venerable concept in search of a theory[J].Complexity (New York,N.Y.),2002,7(6): 18-30. [20] GOLDSTEIN J.Emergence,creativity,and the logic of following and negating[J].The Innovation Journal: The Public Sector Innovation Journal,2005,10(3): 1-10. [21] 张琳,彭玉杰,杜会英.技术会聚:内涵、现状与测度——兼论与学科交叉的关系[J].图书情报工作,2021,65(1): 91-101. [22] 孙雯,刘人境.我国大科学工程协同创新参研人员的网络嵌入性前因机制研究[J].管理学报,2021,18(12): 1763-1771. [23] OPSAHL T,AGNEESSENS F,SKVORETZ J.Node centrality in weighted networks:generalizing degree and shortest paths[J].Social Networks,2010,32(3):245-251. [24] SANDN B A,AZAR C.Near-term technology policies for long-term climate targets—economy wide versus technology specific approaches[J].Energy Policy,2005,33(12): 1557-1576. [25] GHOSH A,RANGANATHAN R,ROSENKOPF L.The impact of context and model choice on the determinants of strategic alliance formation:evidence from a staged replication study[J].Strategic Management Journal,2016,37(11): 2204-2221. [26] KRIVITSKY P N,HANDCOCK M S.A separable model for dynamic networks[J].Journal of the Royal Statistical Society,Series B,Statistical Methodology,2014,76(1): 29-46. [27] YASUNAGA Y,WATANABE M,KORENAGA M.Application of technology roadmaps to governmental innovation policy for promoting technology convergence[J].Technological Forecasting and Social Change,2009,76(1): 61-79. [28] CURRAN C,BRRING S,LEKER J.Anticipating converging industries using publicly available data[J].Technological Forecasting and Social Change,2010,77(3): 385-395. [29] 陈亮,张志强,尚玮姣.技术融合研究进展分析[J].情报杂志,2013,32(10): 99-105. [30] KWON S,LIU X,PORTER A L,et al.Research addressing emerging technological ideas has greater scientific impact[J].Research Policy,2019,48(9): 103834. [31] 万小丽.专利质量指标中“被引次数”的深度剖析[J].情报科学,2014,32(1): 68-73. [32] 李睿,赵峰.届满专利与无效专利的施引特征对比及其情报学意义[J].情报学报,2016,35(6): 586-596. [33] 杨中楷,梁永霞,刘则渊.USPTO中我国专利引用状况的统计分析[J].图书情报工作,2009,53(2): 42-46. [34] CHRISTENSEN C M.The innovator's dilemma: when new technologies cause great firms to fail[M].Harvard:Harvard Business Review Press,2013. [35] HALL B H,JAFFE A,TRAJTENBERG M.Market value and patent citations[J].Rand Journal of Economics,2005,36(1): 16-38. [36] MEYER M.Does science push technology? patents citing scientific literature[J].Research Policy,2000,29(3): 409-434. [37] 陈凯,徐峰,程如烟.非专利引文分析研究进展[J].图书情报工作,2015,59(5): 137-144. [38] MEYER M.Patent citations in a novel field of technology——what can they tell about interactions between emerging communities of science and technology[J].Scientometrics,2000,48(2): 151-178. [39] 李睿,周维,王雪.引文生态视角下标准必要专利的引文特征研究[J].情报学报,2018,37(9): 882-889. [40] 王萍萍,王毅.知识单元特征对发明者知识组合行为的影响——知识网络的视角[J].经济管理,2018,40(5): 92-107. [41] PARCHOMOVSKY G,WAGNER R P.Patent portfolios[J].University of Pennsylvania Law Review,2005,154(1): 1-78. [42] 党兴华,张晨.基于Stergm的风险投资网络演化动力研究[J].科研管理,2022,43(5): 182-190. [43] LEIFELD P,CRANMER S J,DESMARAIS B A.Temporal exponential random graph models with btergm: estimation and bootstrap confidence intervals[J].Journal of Statistical Software,2018,83(6): 1-36. [44] CARNEGIE N B,KRIVITSKY P N,HUNTER D R,et al.An approximation method for improving dynamic network model fitting[J].Journal of Computational and Graphical Statistics,2015,24(2): 502-519.
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