Abstract
Purpose
Bananas are one of the highest selling fruits worldwide, and for several countries, bananas are an important export commodity. However, very little is known about banana’s contribution to global warming. The aims of this work were to study the greenhouse gas emissions of bananas from cradle to retail and cradle to grave and to assess the potential of reducing greenhouse gas (GHG) emissions along the value chain.
Methods
Carbon footprint methodology based on ISO-DIS 14067 was used to assess GHG emissions from 1 kg of bananas produced at two plantations in Costa Rica including transport by cargo ship to Norway. Several methodological issues are not clearly addressed in ISO 14067 or the LCA standards 14040 and ISO 14044 underpinning 14067. Examples are allocation, allocation in recycling, representativity and system borders. Methodological choices in this study have been made based on other standards, such as the GHG Protocol Products Standard.
Results and discussion
The results indicate that bananas had a carbon footprint (CF) on the same level as other tropical fruits and that the contribution from the primary production stage was low. However, the methodology used in this study and the other comparative studies was not necessarily identical; hence, no definitive conclusions can be drawn. Overseas transport and primary production were the main contributors to the total GHG emissions. Including the consumer stage resulted in a 34 % rise in CF, mainly due to high wastage. The main potential reductions of GHG emissions were identified at the primary production, within the overseas transport stage and at the consumer.
Conclusions
The carbon footprint of bananas from cradle to retail was 1.37 kg CO2 per kilogram banana. GHG emissions from transport and primary production could be significantly reduced, which could theoretically give a reduction of as much as 44 % of the total cradle-to-retail CF. The methodology was important for the end result. The choice of system boundaries gives very different results depending on which life cycle stages and which unit processes are included. Allocation issues were also important, both in recycling and in other processes such as transport and storage. The main uncertainties of the CF result are connected to N2O emissions from agriculture, methane emissions from landfills, use of secondary data and variability in the primary production data. Thus, there is a need for an internationally agreed calculation method for bananas and other food products if CFs are to be used for comparative purposes.
This is a preview of subscription content, access via your institution.
References
Adler PR, Del Grosso SJ, Parton WJ (2007) Life cycle assessment of net greenhouse-gas flux for bioenergy cropping systems. Ecol Appl 17:675–691
Berners-Lee M (2010) How bad are bananas? The carbon footprint of everything. Profile Books, London
Bessou C, Basset-Mens C, Tran T, Benoist A (2013) LCA applied to perennial cropping systems: a review focused on the farm stage. Int J Life Cycle Assess 18(2):340–361
BSI (2011) PAS 2050. Specification for the assessment of the life cycle greenhouse gas emissions of goods and services. British Standard Ltd., London
BSI (2012) PAS 2050-1:2012. Assessment of life cycle greenhouse gas emissions from horticultural products. http://shop.bsigroup.com/en/forms/PASs/PAS-2050-1/
Cellura M, Ardente F, Longo S (2012) From the LCA of food products to the environmental assessment of protected crops districts: a case-study in the south of Italy. J Environ Manage 93:194–208
Cerutti A, Bruun S, Beccaro GL, Bounous G (2011) A review of studies applying environmental impact assessment methods on fruit production systems. J Environ Manage 92:2277–2286
Davies J, Wallman M, Sund V, Emanuelsson A, Cederberg C, Sonesson U (2011) Emissions of greenhouse gases from production of horticultural products. Analysis of 17 products cultivated in Sweden. Report SR 828. SIK (Swedish Institute for Food and Biotechnology), June 2011
EIPRO (Environmental Impact of Products) (2006) Analysis of the life cycle environmental impacts related to the total final consumption of the EU 25. European Commission Technical Report EUR 22284
Evans E, Ballen F (2010) Banana market. Report FE901, University of Florida, IFAS Extension
FAOSTAT (2009) Food and Agriculture Organization of the United Nations. ftp://ftp.fao.org/docrep/fao/meeting/018/k6853e.pdf
FAOSTAT (2012) Food and Agriculture Organization of the United Nations. FAOSTAT database
Finkbeiner M (2009) Carbon footprinting—opportunities and threats. Int J Life Cycle Assess 14:91–94
Garnett T (2011) Where are the best opportunities for reducing greenhouse gas emissions in the food system (including the food chain)? Food Policy, Supplement 1:S23–S32
Graefe S, Dufor D, Giraldo A, Muños LA, Mora P, Solís H, Garcés H, Gonzales A (2011) Energy and carbon footprints of ethanol production using banana and cooking banana discard: a case study from Costa Rica. J Biomass Bioenerg 35:2640–2649
Hospido A, Milà i Canals L, McLaren S, Truninger M, Edwards-Jones G, Clift R (2009) The role of seasonality in lettuce consumption: a case study of environmental and social aspects. Int J Life Cycle Assess 14(5):381–391
IPCC (International Panel for Climate Change) (2006a) IPCC guidelines for national greenhouse gas inventories, chapter 11. N2O emissions from managed soils, and CO2 emissions from lime and urea application
IPCC (International Panel for Climate Change) (2006b) IPCC guidelines for national greenhouse gas inventories, chapter 3. LUCF sector good practice guidance
IPCC (International Panel for Climate Change) (2006c) IPCC guidelines for national greenhouse gas inventories, Chapter 5. Waste
International EPD System (2009) Product category rules for vegetables. http://www.environdec.com/en/Product-Category-Rules/Detail/?Pcr=8235
ISO (2012) ISO 14067: carbon footprint of products—requirements and guidelines for quantification and communication. ISO/DIS 14067 (E) official version, 18th January 2012, Document N 371. International Standards Organisation, Geneva (electronic source)
ISO (2006a) ISO 14040:2006. Environmental management—life cycle assessment—principles and framework. International Standards Organisation, Geneva (electronic resource)
ISO (2006b) ISO 14044:2006. Environmental management—life cycle assessment—requirements and guidelines. International Organization for Standards, Geneva (electronic resource)
Lescot T (2012) Carbon footprint analysis in banana production. Second Conference of the World Banana Forum, Guayaquil, Ecuador, 28–29 February 2012
Luske B (2010) Comprehensive carbon footprint assessment. Dole bananas. Soil and More International. http://www.dolecrs.com/performance/carbon-footprint-assessment
Lillywhite R, Chandler D, Grant W, Lewis K, Firth C, Schmutz U, Halpin D (2007) Environmental footprint and sustainability of horticulture (including potatoes)—a comparison with other agricultural sectors. http://randd.defra.gov.uk/
Machado SL, Carvalho MF, Gourc J-P, Vilar OM, do Nascimento JCF (2009) Methane generation in tropical landfills: simplified methods and field results J. Waste Manage 29:153–161
Milà i Canals L, Cowell SJ, Sim S, Basson L (2007) Comparing domestic versus imported apples: a focus on energy use. Environ Sci Pollut Res 14:338–344
Milà i Canals L, Muñoz I, Hospido A, Plassmann K, McLaren S (2008) Life cycle assessment (LCA) of domestic vs. imported vegetables. Case studies on broccoli, salad crops and green beans. CES working paper 01/08, Centre for Environmental Strategy, University of Surrey, Guildford (Surrey) GU2 7XH, UK
Ministerio de Ambiente y Energía (2007) Estrategia Nacional de Cambio Climático. Inventario e informe de gases con efecto invernadero (GEI). Programa piloto para empresas y organizaciones, version 2, 8 pp
Mordini M, Nemecek T, Gaillard G (2009) Carbon & water footprint of oranges and strawberries. A literature review. Agroscope Reckenholz-Tänikon Research Station ART. http://www.agroscope.admin.ch/data/publikationen/1296211551_Mordini_M_SAI_Fruit_Report_final.pdf
Muñoz I, Milà i Canals L, Clift R (2008) Consider a spherical man. J Ind Ecol 12(4):521–538
Robertson GP, Paul EA, Harwood RR (2000) Greenhouse gases in intensive agriculture: contributions of individual gases to the radiative forcing of the atmosphere. Science 289:1922–1925
Saunders C, Barber A, Taylor G (2006) Food miles—comparative energy/emissions performance of New Zealand’s agriculture industry. Research Project No. 285. http://www.lincoln.ac.nz/documents/2328_rr285_s13389.pdf
SCB (Statistiska Centralbyrån) (2010) Livsmedelsförsäljningstatistik 2010, HA 24 SM 1101. Statistics Sweden, food sales 2010. www.scb.se/Statistik/…/HA0103_2010A01_SMHA24SM1101_1.pdf
Sim S, Barry M, Clift R, Cowell SJ (2007) The relative importance of transport in determining an appropriate sustainability strategy for food sourcing. Int J Life Cycle Assess 12:422–431
Smedman A, Lindmark-Månsson H, Drewnowski A, Edman AKM (2010) Nutrient density of beverages in relation to climate impact. Food Nutr Res 54:art no. 517
Soh KG (1997) Fertilizer use by crops. IFA Agro-economics Meeting, Beijing, China. United Nations, 2005. The Millennium Development Goals Report 2005
Sonesson U, Jønsson H, Mattson B (2004) Post consumption sewage treatment in environmental systems analysis of foods. J Ind Ecol 8(3):51–64
Stoessel F, Juraske R, Pfister S, Hellweg S (2012) Life cycle inventory and carbon and water foodprint of fruits and vegetables: application to a Swiss retailer. Environ Sci Technol 46:3253–3262
Trenkel ME (2010) Slow- and controlled-release and stabilized fertilizers: an option for enhancing nutrient efficiency in agriculture, 2nd edn. IFA, Paris, France
USEPA (1998) Landfill air emissions estimation model (version 2.01). EPA-68-D1-0117, EPA 68-D3-0033, US Environmental Protection Agency
USEPA (2005) First-order kinetic gas generation model parameters for wet landfills. EPA-600/R-05/072, US Environmental Protection Agency
Vazquez-Rowe I, Villanueva-Roy P, Moreira T, Gumersindo F (2012) Environmental analysis of Ribeiro wine from a timeline perspective: harvest year matters when reporting environmental impacts. J Environ Manage 98:73–83
Wallén A, Brandt N, Wennersten R (2004) Does the Swedish consumer’s choice of food influence greenhouse gas emissions? Environ Sci Pol 7:525–535
Wicke B, Dornburg V, Junginger M, Faaij A (2008) Different palm oil production systems for energy purposes and their greenhouse gas implications. Biomass Bioenerg 32:1322–1337
Williams AG, Audsley E, Sandars DL (2006) Determining the environmental burdens and resource use in the production of agricultural and horticultural commodities. Main Report. Defra Research Project IS0205. Cranfield University and Defra, Bedford
Worobetz K (2000) Loss of biodiversity is a critical issue. Department of Biological Sciences. University of Alberta, 14 April 2000. http://members.tripod.com/foro_emaus/Growth.htm
World Banana Forum (2012) Working Group on Sustainable Production Systems and Environmental Impact. http://www.fao.org/economic/worldbananaforum/working-groups/wg01/en/
WRI (World Resources Institute) and WBSCD (World Business Council for Sustainable Development) (2011) Greenhouse gas protocol. Product life cycle accounting and reporting standard. http://www.ghgprotocol.org
WRAP (2008) The food we waste. Food waste report v 2. Project RBC405-0010
Xiloyannis C, Montanaro G, Dichio B (2011) Sustainable orchard management, fruit quality and carbon footprint. Acta Horticulturae, p 913
Yoshikawa N, Amano K, Shimada K (2008) Evaluation of environmental load on fruits and vegetables consumption and its reduction potential. Environ Syst Res 36:255–263
Acknowledgments
The authors would like to thank the Norwegian Research Council and the companies BAMA, Nortura, Tine, Norgesgruppen and Coop for financial support and supplying the necessary data for the assessments. We would also like to thank the Dole Food Company for kind cooperation and colleagues at SIK and Ostfold Research for their support.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible editor: Matthias Finkbeiner
Rights and permissions
About this article
Cite this article
Svanes, E., Aronsson, A.K.S. Carbon footprint of a Cavendish banana supply chain. Int J Life Cycle Assess 18, 1450–1464 (2013). https://doi.org/10.1007/s11367-013-0602-4
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11367-013-0602-4
Keywords
- Bananas
- Carbon footprint
- Fruit
- ISO 14067
- PCR