Abstract
The relationship between industrial structure and carbon emissions has been widely identified as a critical research topic by international organizations and academics. Using bibliometrics analysis, this study aimed at dissecting the global characteristics and trends of research on industrial structure and carbon emissions. Based on the 806 documents from 2004 to 2019 in Web of Science, this work was implemented from four aspects, including basic characteristics analysis, country/territory and institution analysis, category and journal analysis, and reference and keyword analysis. The results of this study showed rapid growth trends of research on industrial structure and carbon emissions from 2015 to 2019. The collaborations among countries and institutions were extensive worldwide with China, the USA, and the UK as the main participants. Furthermore, the corresponding research topics, research priorities, and research paths were summarized according to the references co-citation analysis and keywords cluster analysis, which from the perspective of the correlation between different types of industry with carbon emissions. Finally, the timezone view of the top 100 keywords indicated that the emerging trends in the research on industrial structure and carbon emissions were regional analysis, industrialization, and environmental efficiency, and prediction of carbon emissions peak and the spatial distribution in different types of industries were the hotspots in recent years. The findings provide a better understanding of global characteristics and trends that have emerged in this field, which can also offer reference for future research.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Data availability
All data generated or analyzed during this study are included in this published article and its supplementary information files.
References
Ang B, Zhang F, Choi K (1998) Factorizing changes in energy and environmental indicators through decomposition. Energy 23:489–495
Chen C (2004) Searching for intellectual turning points: progressive knowledge domain visualization. Natl Acad Sci USA 2004(101):5303–5310
Chen C (2006) CiteSpace II: detecting and visualizing emerging trends and transient patterns in scientific literature. J Am Soc Inf Sci Technol 57:359–377
Chen C, Hu Z, Liu S, Tseng H (2012) Emerging trends in regenerative medicine: a scientometric analysis in CiteSpace. Expert Opin Biol Ther 12(5):593–608
Chen Y, Liu H, An J, Görsdorf U, Berger FH (2015) A field experiment on the small-scale variability of rainfall based on a network of micro rain radars and rain gauges. J Appl Meteorol Climatol 54:243–255
Chen H, Jiang W, Yang Y, Yang Y, Man X (2017) State of the art on food waste research: a bibliometrics study from 1997 to 2014. J Clean Prod 140:840–846
Chen X, Shuai C, Wu Y, Zhang Y (2020) Analysis on the carbon emission peaks of China’s industrial, building, transport, and agricultural sectors. Sci Total Environ 709:1–9
Cole MA, Elliott RJR, Wu S (2008) Industrial activity and the environment in China: an industry-level analysis. China Econ Rev 19:393–408
Diem A, Wolter SC (2012) The use of bibliometrics to measure research performance in education sciences. Res High Educ 54:86–114
Fisher-Vanden K, Jefferson GH, Jingkui M, Jianyi X (2006) Technology development and energy productivity in China. Energy Econ 28:690–705
Garfield E (2009) From the science of science to Scientometrics visualizing the history of science with HistCite software. J Informet 3:173–179
Henson SA, Beaulieu C, Ilyina T, John JG, Long M, Seferian R et al (2017) Rapid emergence of climate change in environmental drivers of marine ecosystems. Nat Commun 8:1–9
Hosseini MR, Martek I, Zavadskas EK, Aibinu AA, Arashpour M, Chileshe N (2018) Critical evaluation of off-site construction research: a scientometric analysis. Autom Constr 87:235–247
Huang L, Kelly S, Lv K, Giurco D (2019) A systematic review of empirical methods for modelling sectoral carbon emissions in China. J Clean Prod 215:1382–1401
Huang Y, Zhu H, Zhang Z (2020) The heterogeneous effect of driving factors on carbon emission intensity in the Chinese transport sector: evidence from dynamic panel quantile regression. Sci Total Environ 727:1–14
Jiang T, Huang S, Yang J (2019) Structural carbon emissions from industry and energy systems in China: an input-output analysis. J Clean Prod 240(118116):1–13
Kinnin J, Hanna TN, Jutras M, Hasan B, Bhatia R, Khosa F (2019) Top 100 cited articles on radiation exposure in medical imaging: a bibliometric analysis. Curr Probl Diagn Radiol 48:368–378
Kleinberg J (2003) Bursty and hierarchical structure in streams. Data Min Knowl Disc 7:373–397
Leontief W (1970) Environmental repercussions and the economic structure: an input-output approach. Rev Econ Stat 52(3):262–271
Li X, Ma E, Qu H (2017) Knowledge mapping of hospitality research − a visual analysis using CiteSpace. Int J Hosp Manag 60:77–93
Li W, Dong H, Yu H, Wang D, Yu H (2018a) Global characteristics and trends of research on ceramic membranes from 1998 to 2016: based on bibliometric analysis combined with information visualization analysis. Ceram Int 44:6926–6934
Li Y, Lu Y, Taylor JE, Han Y (2018b) Bibliographic and comparative analyses to explore emerging classic texts in megaproject management. Int J Proj Manag 36:342–361
Li B, Han S, Wang Y, Wang Y, Li J, Wang Y (2020) Feasibility assessment of the carbon emissions peak in China’s construction industry: factor decomposition and peak forecast. Sci Total Environ 706:1–13
Lin B, Wang M (2019) Dynamic analysis of carbon dioxide emissions in China’s petroleum refining and coking industry. Sci Total Environ 671:937–947
Liu Z, Yin Y, Liu W, Dunford M (2015) Visualizing the intellectual structure and evolution of innovation systems research: a bibliometric analysis. Scientometrics 103:135–158
Liu H, Fan J, Zhou K, Wang Q (2019) Exploring regional differences in the impact of high energy-intensive industries on CO2 emissions: evidence from a panel analysis in China. Environ Sci Pollut Res 26:26229–26241
Madani F, Weber C (2016) The evolution of patent mining: applying bibliometrics analysis and keyword network analysis. World Patent Inf 46:32–48
Ouyang W, Wang Y, Lin C, He M, Hao F, Liu H, Zhu W (2018) Heavy metal loss from agricultural watershed to aquatic system: a scientometrics review. Sci Total Environ 637-638:208–220
Özer B, Görgün E, İncecik S (2013) The scenario analysis on CO2 emission mitigation potential in the Turkish electricity sector: 2006–2030. Energy 49:395–403
Paul S, Bhattacharya RN (2004) CO2 emission from energy use in India: a decomposition analysis. Energy Policy 32:585–593
Qin Y, Zhang Q, Liu Y (2020) Analysis of knowledge bases and research focuses of cerebral ischemia-reperfusion from the perspective of mapping knowledge domain. Brain Res Bull 156:15–24
Ren S, Yin H, Chen X (2014) Using LMDI to analyze the decoupling of carbon dioxide emissions by China’s manufacturing industry. Environ Dev 9:61–75
Rousseeuw PJ (1987) Silhouettes: a graphical aid to the interpretation and validation of cluster analysis. J Comput Appl Math 20(C):53–65
Sue Wing I, Eckaus RS (2007) The implications of the historical decline in US energy intensity for long-run CO2 emission projections. Energy Policy 35:5267–5286
Tan Z, Li L, Wang J, Wang J (2011) Examining the driving forces for improving China’s CO2 emission intensity using the decomposing method. Appl Energy 88:4496–4504
Thomas Dietz EAR (1997) Effects of population and affluence on CO2 emissions. Source. Proc Natl Acad Sci U S A 94(1):175–179
Tian X, Chang M, Tanikawa H, Shi F, Imura H (2012) Regional disparity in carbon dioxide emissions. J Ind Ecol 16:612–622
Tian X, Chang M, Shi F, Tanikawa H (2014) How does industrial structure change impact carbon dioxide emissions? A comparative analysis focusing on nine provincial regions in China. Environ Sci Pol 37:243–254
Tian X, Bai F, Jia J, Liu Y, Shi F (2019) Realizing low-carbon development in a developing and industrializing region: impacts of industrial structure change on CO2 emissions in southwest China. J Environ Manag 233:728–738
Wang C, Chen J, Zou J (2005) Decomposition of energy-related CO2 emission in China: 1957–2000. Energy 30:73–83
Wang Q, Yang Z, Yang Y, Long C, Li H (2014) A bibliometric analysis of research on the risk of engineering nanomaterials during 1999-2012. Sci Total Environ 473-474:483–489
Wang C, Zhan J, Bai Y, Chu X, Zhang F (2019a) Measuring carbon emission performance of industrial sectors in the Beijing-Tianjin-Hebei region, China: a stochastic frontier approach. Sci Total Environ 685:786–794
Wang K, Wu M, Sun Y, Shi X, Sun A, Zhang P (2019b) Resource abundance, industrial structure, and regional carbon emissions efficiency in China. Res Policy 60:203–214
Wang S, Wang J, Li S, Fang C, Feng K (2019c) Socioeconomic driving forces and scenario simulation of CO2 emissions for a fast-developing region in China. J Clean Prod 216:217–229
Xie L, Xue Q, Yuan Z (2019) Composition and spatial difference of agro-industry carbon footprint in Hebei province, North China. Ecol Indic 97:141–149
Xu XY, Ang BW (2013) Index decomposition analysis applied to CO2 emission studies. Ecol Econ 93:313–329
Xu X, Zhao T, Liu N, Kang J (2014) Changes of energy-related GHG emissions in China: an empirical analysis from sectoral perspective. Appl Energy 132:298–307
Yang F, Qiu D (2019) Exploring coal spontaneous combustion by bibliometric analysis. Process Saf Environ Prot 132:1–10
Yu D, Xu Z, Wang W (2018) Bibliometric analysis of fuzzy theory research in China: a 30-year perspective. Knowl-Based Syst 141:188–199
Yuan Wang NL, Zuo J, Chen G, Du H (2016) Characteristics and trends of research on waste-to-energy incineration: a bibliometric analysis, 1999–2015. Renew Sust Energ Rev 2016(66):95–104
Zhang M, Mu H, Ning Y, Song Y (2009) Decomposition of energy-related CO2 emission over 1991–2006 in China. Ecol Econ 68:2122–2128
Zhang Y, Zhang J, Yang Z, Li S (2011) Regional differences in the factors that influence China’s energy-related carbon emissions, and potential mitigation strategies. Energy Policy 39:7712–7718
Zhang S, Li H, Zhang Q, Tian X, Shi F (2019) Uncovering the impacts of industrial transformation on low-carbon development in the Yangtze River Delta. Resour Conserv Recycl 150(104442):1–10
Zhao X (2017) A scientometric review of global BIM research: analysis and visualization. Autom Constr 80:37–47
Zhou X, Zhang J, Li J (2013) Industrial structural transformation and carbon dioxide emissions in China. Energy Policy 57:43–51
Acknowledgments
The reviewers and editors are appreciated for their comments and suggestions to improve the paper.
Funding
This work was financially supported by the Major Bidding Projects of National Social Science Foundation of China “Study on theConstruction Mechanism and path of Innovation ecosystem in Xiongan New area”(Grant no. 18ZD044).
Author information
Authors and Affiliations
Contributions
All authors contributed to the study conception and design. Methodology, resources, and writing original draft were performed by Liwen Sun and Linfei Wu. Software and writing review and editing were performed by Linfei Wu and Peixiao Qi. All authors read and approved the final manuscript.
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Additional information
Responsible Editor: Philippe Garrigues
Publisher’s note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
ESM 1
(DOCX 170 kb)
Rights and permissions
About this article
Cite this article
Sun, L., Wu, L. & Qi, P. Global characteristics and trends of research on industrial structure and carbon emissions: a bibliometric analysis. Environ Sci Pollut Res 27, 44892–44905 (2020). https://doi.org/10.1007/s11356-020-10915-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11356-020-10915-9