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2 - Emerging Bioeconomy Narratives

from Part I

Published online by Cambridge University Press:  26 October 2023

Piergiuseppe Morone ,
Dalia D'Amato ,
Nicolas Befort  and
Gülşah Yilan
Piergiuseppe Morone
Affiliation:
Unitelma Sapienza
Dalia D'Amato
Affiliation:
Finnish Environment Institute (Suomen Ympäristökeskus - SYKE)
Nicolas Befort
Affiliation:
NEOMA BS
Gülşah Yilan
Affiliation:
Unitelma Sapienza University of Rome
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Summary

The objective of this chapter is to offer a framework for understanding the debates around the bioeconomy. Indeed, a large body of literature has been developed in an attempt to identify the visions of the future and the narratives that aim to define the bioeconomy. This chapter offers a mapping of these visions and, based on three emblematic cases, shows how the three visions of the bioeconomy relate to economic realities.

Keywords

bioeconomy modelsbiotechnologyproduct development strategiesvisions of futurebusiness modelspublic policies
Type
Chapter
Information
The Circular Bioeconomy
Theories and Tools for Economists and Sustainability Scientists
 , pp. 15 - 30
Publisher: Cambridge University Press
Print publication year: 2023

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References

Aguilar, A., Magnien, E., & Thomas, D. (2013). Thirty years of European biotechnology programmes: From biomolecular engineering to the bioeconomy. New Biotechnology, 30(5), 410425.Google Scholar
Anastas, P. T., & Warner, J. C. (1998). Green chemistry. Frontiers, 640, 1998.Google Scholar
Andersson, T., Gleadle, P., Haslam, C., & Tsitsianis, N. (2010). Bio-pharma: A financialized business model. Critical Perspectives on Accounting, 21(7), 631641.Google Scholar
Arora, A. (2001). Markets for technology and their implications for corporate strategy. Industrial and Corporate Change, 10(2), 419451.Google Scholar
Audretsch, D. B. (2001). The role of small firms in U.S. biotechnology clusters. Small Business Economics, 17(1/2), 315.CrossRefGoogle Scholar
Audretsch, D. B., Lehmann, E. E., & Warning, S. (2005). University spillovers and new firm location. Research Policy, 34(7), 11131122.Google Scholar
Becker, J., Lange, A., Fabarius, J., & Wittmann, C. (2015). Top value platform chemicals: Biobased production of organic acids. Current Opinion in Biotechnology, 36, 168175.Google Scholar
Befort, N. (2020). Going beyond definitions to understand tensions within the bioeconomy: The contribution of sociotechnical regimes to contested fields. Technological Forecasting and Social Change, 153, 119923.Google Scholar
Belussi, F. (2016). The implementation of a new game strategy in biotech form. From start-up to acquisition: The case of Fidia Advanced Biopolymers (now Anika Therapeutics) of Abano Terme. In Belussi, F. & Orsi, L., eds., Innovation, alliances, and networks in high-tech environments., Routledge, pp. 337352.Google Scholar
Bozell, J. J., Moens, L., Elliott, D. C., … Jarnefeld, J. L. (2000). Production of levulinic acid and use as a platform chemical for derived products. Resources, Conservation and Recycling, 28(3–4), 227239.Google Scholar
Bozell, J. J., & Petersen, G. R. (2010). Technology development for the production of biobased products from biorefinery carbohydrates – The US Department of Energy’s “Top 10” revisited. Green Chemistry, 12(4), 539554.CrossRefGoogle Scholar
Bud, R. (1991). Biotechnology in the twentieth century. Social Studies of Science, 21(3), 415457.Google Scholar
Carothers, W. H. (1937). Linear Condensation Process. US2071250 A., Google Patents.Google Scholar
Carrez, D. (2016). European strategies and policies getting towards a bioeconomy. In Creating sustainable bioeconomies, Routledge, pp. 229243.Google Scholar
Cherubini, F., Jungmeier, G., Wellisch, M., … de Jong, E. (2009). Toward a common classification approach for biorefinery systems. Biofuels, Bioproducts and Biorefining, 3(5), 534546.Google Scholar
Coriat, B., & Orsi, F. (2002). Establishing a new intellectual property rights regime in the United States. Research Policy, 31(8–9), 14911507.Google Scholar
Datta, R. (1992, September 1). Process for the production of succinic acid by anaerobic fermentation, Google Patents.Google Scholar
de Jong, E., Higson, A., Walsh, P., & Wellisch, M. (2012). Product developments in the bio-based chemicals arena. Biofuels, Bioproducts and Biorefining, 6(6), 606624.CrossRefGoogle Scholar
Dubois, J.-L. (2011). Requirements for the development of a bioeconomy for chemicals. Current Opinion in Environmental Sustainability, 3(1–2), 1114.Google Scholar
Dunlop, A. P., & Wells, J. P. A. (1957, November 19). Process for producing levulinic acid, Google Patents.Google Scholar
European Commission. (2005). New perspectives on the knowledge‐based bio‐economy: Conference report, European Commission Brussels.Google Scholar
European Commission. (2012). Innovating for Sustainable Growth: A Bioeconomy for Europe (Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions No. SWD(2012) 11 final).Google Scholar
Festel, G., Detzel, C., & Maas, R. (2012). Industrial biotechnology – Markets and industry structure. Journal of Commercial Biotechnology, 18(1). doi:10.5912/jcb478Google Scholar
Fevolden, A., Coenen, L., Hansen, T., & Klitkou, A. (2017). The role of trials and demonstration projects in the development of a sustainable bioeconomy. Sustainability, 9(3), 419.CrossRefGoogle Scholar
Fitzpatrick, S. W. (1990). Manufacture of furfural and levulinic acid by acid degradation of lignocellulosic. World Patent, 8910362.Google Scholar
Friedman, D. C., & Ellington, A. D. (2015). Industrialization of biology. ACS Synthetic Biology, 4(10), 10531055.Google Scholar
Garnier, E., & Bliard, C. (2012). The emergence of doubly green chemistry, a narrative approach. European Review of Industrial Economics and Policy, (4).Google Scholar
Gruber, P. R., Hall, E. S., Kolstad, J. J., Iwen, M. L., Benson, R. D., & Borchardt, R. L. (1994, October 18). Continuous process for manufacture of lactide polymers with purification by distillation, Google Patents.Google Scholar
Hellsmark, H., Frishammar, J., Söderholm, P., & Ylinenpää, H. (2016). The role of pilot and demonstration plants in technology development and innovation policy. Research Policy, 45(9), 17431761.Google Scholar
Hopkins, M. M., Crane, P. A., Nightingale, P., & Baden-Fuller, C. (2013). Buying big into biotech: Scale, financing, and the industrial dynamics of UK biotech, 1980–2009. Industrial and Corporate Change, 22(4), 903952.Google Scholar
Kamm, B., Gruber, P. R., & Kamm, M. (2006). Biorefineries-industrial processes and products, Vol. 2, Wiley-VCH Weinheim.Google Scholar
Leonard, R. H. (1956). Levulinic acid as a basic chemical raw material. Industrial & Engineering Chemistry, 48(8), 13301341.Google Scholar
Levidow, L., Birch, K., & Papaioannou, T. (2012). EU agri-innovation policy: Two contending visions of the bio-economy. Critical Policy Studies, 6(1), 4065.Google Scholar
Lipinsky, E. S., Sinclair, R. G. (1986). Is lactic acid a commodity chemical? Chemical Engineering Progress, 82, 26–32.Google Scholar
McKelvey, M. (2007). Biotechnology industry. In Hanusch, H. & Pyka, A., eds., Elgar companion to neo-schumpeterian economics, Edward Elgar Publishing, pp. 607620.Google Scholar
Meyer, W. G. (1945, August 14). Manufacture of levulinic acid, Google Patents.Google Scholar
Mowery, D. C., & Sampat, B. N. (2004). The Bayh-Dole act of 1980 and university? Industry technology transfer: A model for other OECD governments? The Journal of Technology Transfer, 30(1–2), 115127.Google Scholar
Mustar, P., Wright, M., & Clarysse, B. (2008). University spin-off firms: Lessons from ten years of experience in Europe. Science and Public Policy, 35(2), 6780.Google Scholar
OECD. (2009). The bioeconomy to 2030: Designing a policy agenda, OECD, Paris.Google Scholar
OECD. (2017a). Biomass for a sustainable bioeconomy: Technology and governance.Google Scholar
OECD. (2017b). Towards Bio-Production of Materials: Replacing the oil barrel (No. DSTI/STP/BNCT(2016)17/FINAL).Google Scholar
Patrucco, P. P. (2014). The evolution of knowledge organization and the emergence of a platform for innovation in the car industry. Industry and Innovation, 21(3), 243266.Google Scholar
Robinson, J. B. (1982). Energy backcasting a proposed method of policy analysis. Energy Policy, 10(4), 337344.CrossRefGoogle Scholar
Ronzon, T., Piotrowski, S., M’Barek, R., & Carus, M. (2017). A systematic approach to understanding and quantifying the EU’s bioeconomy. Bio-Based and Applied Economics Journal, 6(1050-2018-3682), 117.Google Scholar
SCAR. (2015). Sustainable agriculture, forestry and fisheries in the bioeconomy – A challenge for Europe. 4th Foresight Exercise.Google Scholar
Schmidt, O., Padel, S., & Levidow, L. (2012). The bio-economy concept and knowledge base in a public goods and farmer perspective. Bio-Based and Applied Economics, 1(1), 4763.Google Scholar
Schneider, A. K. (1955, March 1). Polymers of high melting lactide, Google Patents.Google Scholar
SIRA. (2013). Bio-based and Renewable Industries for Development and Growth in Europe.Google Scholar
Staffas, L., Gustavsson, M., & McCormick, K. (2013). Strategies and policies for the bioeconomy and bio-based economy: An analysis of official national approaches. Sustainability, 5(6), 27512769.Google Scholar
Staley Manufacturing Company. (1943). Levulinic acid; a literature reference, compiled by Division of research development, A. E. Staley Manufacturing Co.Google Scholar
Veal, F. J., & Whalley, L. (1981). Renewable resources as chemical feedstocks. Conservation & Recycling, 4(1), 4757.Google Scholar
Vergragt, P. J., & Quist, J. (2011). Backcasting for sustainability: Introduction to the special issue. Technological Forecasting and Social Change, 78(5), 747755.CrossRefGoogle Scholar
Werpy, T. A., Frye, J. G., & Holladay, J. E. (2006). Succinic Acid-A Model Building Block for Chemical Production from Renewable Resources, United States: B Kamm, PR Gruber, and M Kamm; Wiley – VCH, Weinham, Germany. Retrieved from www.osti.gov/biblio/895169.Google Scholar
Werpy, T., & Petersen, G. (2004). Top value added chemicals from biomass: Volume I – Results of screening for potential candidates from sugars and synthesis gas, Golden, CO (United States).Google Scholar
Zeikus, J. G. (1980). Chemical and fuel production by anaerobic bacteria. Annual Review of Microbiology, 34(1), 423464.Google Scholar
Zeikus, J. G., Jain, M. K., & Elankovan, P. (1999). Biotechnology of succinic acid production and markets for derived industrial products. Applied Microbiology and Biotechnology, 51(5), 545552.Google Scholar

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