Introduction

In the last 50 years, the biosphere, upon which humanity depends, has been altered to an unparalleled degree[i]. The current fossil-based economy is putting at risk not only life on our planet, but also the world’s economy.

The coronavirus pandemic is yet another wake-up call to stop exceeding the planetary boundaries. After all, deforestation, biodiversity loss and landscape fragmentation have been identified as key processes enabling direct transmission of zoonotic infectious diseases[ii]. Likewise, a changing climate has profound implications for human health2.

The need to react to the unprecedented COVID-19 crisis is a unique opportunity to transition towards a sustainable wellbeing economy centered around people and nature[iii]. This requires transformative policies that trigger mission-oriented innovation, attract investments and rethink business models and markets. But above all we need to address the past failure of our economy to value nature, because our health and wellbeing fundamentally depends on it.

A circular bioeconomy[i] (see Figure 1) offers a conceptual framework for using renewable natural capital to holistically transform and manage our land, food, health and industrial systems with the goal of achieving sustainable wellbeing in harmony with nature.

Within the framework of the Sustainable Markets Initiative, under the leadership of His Royal Highness The Prince of Wales (https://www.sustainable-markets.org/), a 10-Point Action Plan to catalyse a circular bioeconomy of wellbeing is proposed below. The Prince of Wales reflected in a recent Science Editorial on the importance (link) of the circular bioeconomy. The Action Plan is guided by new scientific insights and breakthrough technologies from several disciplines and sectors. It is articulated around six transformative action points further discussed below and four enabling action points (Table 1), which mutually reinforce each other.

Figure 1 Flows in the circular bioeconomy of wellbeing. Source: European Forest Institute
The circular bioeconomy relies on healthy, biodiverse and resilient ecosystems and aims at providing sustainable wellbeing through the provision of ecosystem services and the sustainable management of biological resources (plants, animals, micro-organisms and derived biomass, including organic waste) and its cicular transformation in food, feed, energy and biomaterials within the ecological boundaries of the ecosystems that it relies on. The circular bioeconomy is powered by renewable energy and includes and interlinks holistically the following systems and sectors:
• land and marine ecosystems as well as green infrastructures and the services they provide in cities
• primary production sectors (agriculture, forestry, fisheries, aquaculture and aquaponics)
• economic and industrial sectors relying on biological resources and nature-based solutions (food, wood industry, bulk and speciality chemicals, construction, packaging, textiles, pharmaceuticals, bioenergy, and all sectors benefiting from biobased solutions or ecosystem services such us nature tourism or water supply).

1. Aim at sustainable wellbeing

The current fossil-based economy, addicted to “growth at all costs”, as measured by Gross Domestic Product (GDP) should be replaced by an economy aiming at sustainable wellbeing centered around people and our natural environment. This means replacing current economic indicators such as GDP, which focus only on market transactions, with new indicators of sustainable wellbeing including human health, which should include the broad range of non-market contributions from natural and social capital (e.g., Genuine Progress Indicator[i], or Sustainable Wellbeing Index3). The Sustainable Development Goals provide an internationally agreed framework to develop these new indicator approaches and integrate them in the national accounts accordingly. It is now technically possible to understand and measure the impact of developing a circular bioeconomy in terms of sustainable wellbeing while accounting for the tradeoffs and synergies between different SDGs3.

2. Invest in nature and biodiversity

Measures to protect and enhance biodiversity and our natural capital through two interdependent strategies are essential for sustainable wellbeing, human health and a resilient circular bioeconomy. The first strategy is based on massive research evidence showing how fostering more species-rich systems can support productive and resilient agriculture, forestry and aquaculture[ii], while avoiding the pitfalls of climate change, land degradation, resource depletion, pollution and insect decline.  The second strategy aims at protecting large, contiguous biodiverse systems across different ecoregions to prevent the deterioration of global ecosystem services, species extinction and the rapid erosion of biodiversity7. A global concerted action to maintain and restore highly biodiverse natural ecosystems over large land areas is required to save the diversity and abundance of life on Earth[iii]. Both types of measures require new business models and institutional instruments like payments for ecosystem services[iv] or common asset trusts aiming at the protection of biodiversity and the provision of ecosystem services.

3. Ensure an equitable distribution of prosperity

Biological resources like agriculture or forest resources, are usually owned and managed by many more people, communities and entities, when compared to fossil resources, such as gas and oil. This offers the circular bioeconomy the possibility to generate a more equitable distribution of income, jobs, infrastructure and prosperity across a wider geography4. To do that, circular bioeconomy value chains need to be co-created with the participation of local communities. This means that the role of local populations, including indigenous people where pertinent, should not be limited to supplying traditional knowledge or harvesting biological resources, but it should include their participation in strategic decision-making, governance and benefit sharing[v]. At the same time, the empowerment of women, including microfinance for women’s enterprises, should be explicitly addressed to guarantee inclusive governance, poverty alleviation and overall sustainable development.

4. Rethink holistically land, food and health systems

Food systems are responsible for 21-37% of global greenhouse gas emissions and a major driver of deforestation and land degradation[vi], yet there is still widespread food insecurity and malnutrition. Transforming the land sector (agriculture, forestry, wetlands, bioenergy) towards more sustainable practices could contribute an estimated 30% of the global mitigation needed in 2050 to deliver on the 1.5°C target [vii]. To achieve this, scaling up sustainable agriculture practices11 and climate smart forestry measures[viii] is needed to meet the demand for food while providing key regulating ecosystem services (e.g., link to climate cooling and water)[ix] and sustainable feedstocks for producing biobased products and bioenergy. A one-health2 approach is also necessary to address holistically human and animal health in connection to land use and climate change.

5. Transform industrial sectors

Globally, industry is responsible for over 30% of all greenhouse gas emissions, of which the majority arise from the production of bulk materials like cement, metals, chemicals and petrochemical products[x]. At the same time the current industrial system remains too ‘linear’ (for instance only 12% of the materials come from recycling globally), resource intense and based on non-renewable resources (non-metallic minerals such as sand or gravel account for about 50% of all resources that we extract globally)9. It is urgent to deploy scalable innovations and viable technologies to produce resource-efficient, circular and low carbon solutions based on both renewable energy and sustainability sourced bio-based materials. A good example is the first ever car made of nanocellulose, a biomaterial five times lighter and stronger than steel, produced in Japan in 2019. New biomaterials, including bioplastics, hold tremendous promise due to its lower carbon footprint and biodegradability compared to petrochemical products4. For instance, new wood-based textiles have a climate mitigation effect of 5 kg CO2 per kg of product used compared to polyester11. Finally, sustainable fuels processed from biowaste or even carbon emissions can be now used in aviation.

6. Reimagine cities through ecological lenses

UN projections foresee 2.3 billion new urban dwellers by 2050. Producing the volume of new housing required could claim up to 20% of the remaining carbon budget for 2020-2050 if mineral-based construction materials such as steel and cement are used[xi]. A shift to biomaterials (based on engineering wood or bamboo) could substantially reduce both the amount of materials used and the carbon footprint of our cities while creating durable carbon pools4,15. Using wood in construction has a climate mitigation effect of 2.4-2.9 Kg CO2 per Kg of product used when compared  to concrete11 while also storing 1 ton of CO2 in each m3 of products. Building with wood is also more resource efficient as it can reduce the total amount of materials used in construction by 50%15. Finally, the use of nature-based solutions such as urban forests, trees and vegetation has positive impacts on the health of urban populations while reducing the urban heat island effects[xii].

Realising the potential of the circular bioeconomy through the six transformative action points described above requires an enabling environment, as reflected in the four enabling action points below, which include mutually reinforcing policies and strategies, innovation, investments, and research and education in order to trigger the necessary transformative changes across sectors and systems. Table 1 summarizes the key recommendations under the four enabling action points in connection to the six transformative action points.

Table 1: Enabling action points for a circular bioeconomy of wellbeing

The Action Plan for a circular bioeconomy of wellbeing is a call for global, integrated and transformative action to put the world on a sustainable path. The path of a circular bioeconomy of wellbeing.

References:

  1. Steffen, W., Richardson, K., Rockström, J., Cornell, S. E., Fetzer, I., Bennett, E. M., Biggs, R., Carpenter, S. R., de Vries, W., de Wit, C. A., Folke, C., Gerten, D., Heinke, J., Mace, G. M., Persson, L. M., Ramanathan, V., Reyers, B., Sörlin, S. 2015. Planetary boundaries: Guiding human development on a changing planet. Science, 347(6223), 1259855.
  2. Kahn, L. 2017. Perspective: The one-health way. Nature 543, S47.
  3. Costanza, R., L. Daly, L. Fioramonti, E. Giovannini, I. Kubiszewski, L. F. Mortensen, K. Pickett, K. V. Ragnarsdóttir, R. de Vogli, and R. Wilkinson. 2016. Modelling and measuring sustainable wellbeing in connection with the UN Sustainable Development Goals. Ecological Economics. 130:350–355
  4. Hetemäki, L, Hanewinkel, M, Muys, B, Ollikainen, M, Palahí, M, Trasobares, T.  2017. Leading the way to a European circular bioeconomy strategy, From Science to Policy 5, European Forest Institute.
  5. Kubiszewski, I., R. Costanza, C. Franco, P. Lawn, J. Talberth, T. Jackson, and C. Aylmer. 2013. Beyond GDP: Measuring and Achieving Global Genuine Progress. Ecological Economics. 93:57-68.
  6. Tilman, D., Isbell, F., & Cowles, J. M. 2014. Biodiversity and ecosystem functioning. Annual review of ecology, evolution, and systematics, 45, 471-493.
  7. Dinerstein, Eric & Vynne, Carly & Sala, E. & Joshi, Anup & Fernando, Senura & Lovejoy, Thomas & Mayorga, Juan & Olson, David & Asner, G. & Baillie, J. & Burgess, Neil & Burkart, K. & Noss, Reed & Zhang, Y. & Baccini, A. & Birch, Tanya & Hahn, Nathan & Joppa, L. & Wikramanayake, Eric. 2019. A Global Deal For Nature: Guiding principles, milestones, and targets. Science Advances. 5. eaaw2869. 10.1126/sciadv.aaw2869.
  8. Farley, J. and R. Costanza. 2010. Payments for ecosystem services: from local to global. Ecological Economics. 69:2060-2068.
  9. IRP. 2019. Global Resources Outlook 2019: Natural Resources for the Future We Want. Oberle, B., Bringezu, S., Hatfield-Dodds, S., Hellweg, S., Schandl, H., Clement, J., and Cabernard, L., Che, N., Chen, D., Droz-Georget , H., Ekins, P., Fischer-Kowalski, M., Flörke, M., Frank, S., Froemelt , A., Geschke, A., Haupt , M., Havlik, P., Hüfner, R., Lenzen, M., Lieber, M., Liu, B., Lu, Y., Lutter, S., Mehr , J., Miatto, A., Newth, D., Oberschelp , C., Obersteiner, M., Pfister, S., Piccoli, E., Schaldach, R., Schüngel, J., Sonderegger, T., Sudheshwar, A., Tanikawa, H., van der Voet, E., Walker, C., West, J., Wang, Z., Zhu, B. A Report of the International Resource Panel. United Nations Environment Programme. Nairobi, Kenya.
  10. IPCC. 2019. Summary for Policymakers. In: Climate Change and Land: an IPCC special report on climate change, desertification, land degradation, sustainable land management, food security, and greenhouse gas fluxes in terrestrial ecosystems [P.R. Shukla, J. Skea, E. Calvo Buendia, V. Masson-Delmotte, H.- O. Pörtner, D. C. Roberts, P. Zhai, R. Slade, S. Connors, R. van Diemen, M. Ferrat, E. Haughey, S. Luz, S. Neogi, M. Pathak, J. Petzold, J. Portugal Pereira, P. Vyas, E. Huntley, K. Kissick, M. Belkacemi, J. Malley, (eds.)].
  11. Roe, S, Streck, C, Obersteiner, M, Frank, S, Griscom, B, Drouet, L, Fricko, O, Gusti, M, Harris, N, Hasegawa, T, Hausfather, Z, Havlík, P, House, J, Nabuurs, G-J, Popp, A, Sánchez, MJS, Sanderman, J, Smith, P, Stehfest, E, Lawrence, D. 2019.Contribution of the land sector to a 1.5 °C world. Nat. Clim. Chang. 9, 817–828. doi:10.1038/ s41558-019-0591-9.
  12. Verkerk, P.J, Costanza, R, Hetemäki, L, Kubiszewski, I, Leskinen, P, Nabuurs, G.J, Poto?nik, J, Palahí, M. 2020. Climate-Smart Forestry: the missing link. Forest Policy econ. 115
  13. Ellison D., Morris C.E., Locatelli B., Sheil D., Cohen J., Murdiyarso D., Gutierrez V., van Noordwijk M., Creed I.F., Pokorny J., Gaveau D., Spracklen D.V., Bargués Tobella A., Ilstedt U., Teuling A.J., Gebreyohannis Gebrehiwot S., Sands D.C., Muys B., Verbist B., Springgay E., Sugandi Y., Sullivan C.A. 2017. Trees, forests and water: Cool insights for a hot world. Global Environmental Change, 43, 51-61.
  14. Wesseling, J.H.. Lechtenböhmer, S., Åhman, M., Nilsson, L.J., Worrell, L., Coenen, L. 2017. The transition of energy intensive processing industries towards deep decarbonization: characteristics and implications for future research. Renew. Sustain. Energy Rev., 79, pp. 1303-1313
  15. Churkina, G., Organschi, A., Reyer, C.P.O. Andrew Ruff, A., Vinke, K., Liu, Z., Reck, B. K., Graedel, T. E., Schellnhuber, H. J. 2020. Buildings as a global carbon sink. Nat Sustain 3, 269–276. https://doi.org/10.1038/s41893-019-0462-4
  16. Willis, K. J. & Petrokofsky, G. 2017. he natural capital of city trees. Science 356, 374–376.
Avatar

Robert Costanza

Robert Costanza is Chair of Public Policy at the Crawford School of Public Policy, Australian National University. He has authored or coauthored over 350 scientific papers, and reports on his work have...

Avatar

Ida Kubiszewski

Dr. Ida Kubiszewski is an Associate Editor of Solutions. Dr. Ida Kubiszewski is an Associate Professor at Crawford School of Public Policy at The Australian National University. She is the author...

Avatar

Hunter Lovins

Hunter Lovins is president of Natural Capitalism Solutions, which helps companies, communities, and countries implement more sustainable business practices profitably. Over her 30 years as a sustainability...

Avatar

Enrico Giovannini

Enrico Giovannini has been the Italian Minister of Labor and Social Policies since April 2013. From August 2009 to April 2013 he was president of the Italian Statistical Institute. He was also president...

Avatar

Lorenzo Fioramonti

Lorenzo Fioramonti (@lofioramonti) is Full Professor of Political Economy at the University of Pretoria (South Africa), where he directs the Centre for the Study of Governance Innovation (

Avatar

Sandrine Dixson-Declѐve

Sandrine Dixson-Declѐve has 30+ years of European and international policy, business leadership and strategy experience with a particular focus on EU and international climate change, sustainable development,...

Avatar

Jacqueline McGlade

Jacqueline McGlade was executive director of the European Environment Agency from 2003 until 2013. Prior to this she held academic positions in Europe and North America, focusing her research on spatial...

Avatar

Kate Pickett

Kate Pickett is professor of epidemiology at the University of York and a cofounder and director of the Equality Trust. She is coauthor, with Richard Wilkinson, of the best-selling book "The Spirit Level,"...

Avatar

Richard Wilkinson

Richard Wilkinson has played a formative role in international research on the social determinants of health and on the societal effects of income inequality. He is professor emeritus of social epidemiology...

Avatar

Kristín Vala Ragnarsdóttir

Kristín Vala Ragnarsdóttir is Dean of the School of Engineering and Natural Sciences at the University of Iceland. She is currently working with the Idea Ministry in Iceland, a grassroots organization...

Leave a comment

Your email address will not be published. Required fields are marked *