Energy Embedded in Food Loss Management and in the Production of Uneaten Food: Seeking a Sustainable Pathway

Recently, important efforts have been made to define food loss management strategies. Most strategies have mainly been focused on mass and energy recovery through mixed food loss in centralised recovery models. This work aims to highlight the need to address a decentralised food loss management, in order to manage the different fractions and on each of the different stages of the food supply chain. For this purpose, an energy flow analysis is made, through the calculation of the primary energy demand of four stages and 11 food categories of the Spanish food supply chain in 2015. The energy efficiency assessment is conducted under a resource use perspective, using the energy return on investment (EROI) ratio, and a circular economy perspective, developing an Energy return on investment – Circular economy index (EROIce), based on a food waste-to-energy-to-food approach. Results suggest that the embodied energy loss consist of 17% of the total primary energy demand, and related to the food categories, the vegetarian diet appears to be the most efficient, followed by the pescetarian diet. Comparing food energy loss values with the estimated energy provided for one consumer, it is highlighted the fact that the food energy loss generated by two to three persons amounts to one person's total daily intake. Moreover, cereals is the category responsible for the highest percentage on the total food energy loss (44%); following by meat, fish and seafood and vegetables. When the results of food energy loss and embodied energy loss are related, it is observed that categories such as meat and fish and seafood have a very high primary energy demand to produce less food, besides that the parts of the food supply chain with more energy recovery potential are the beginning and the end. Finally, the EROIce analysis shows that in the categories of meat, fish and seafood and cereals, anaerobic digestion and composting is the best option for energy recovery. From the results, it is discussed the possibility to developed local digesters at the beginning and end of the food supply chain, as well as to developed double digesters installations for hydrogen recovery from cereals loss, and methane recovery from mixed food loss.

[1]  G. Finnveden,et al.  Environmental Assessment of Possible Future Waste Management Scenarios , 2017 .

[2]  Hanne Østergård,et al.  Energy Analysis of the Danish Food Production System: Food-EROI and Fossil Fuel Dependency , 2013 .

[3]  Joan Martinez-Alier,et al.  The EROI of agriculture and its use by the Via Campesina , 2011 .

[4]  ThE CirCUlAr,et al.  EU Action Plan for the Circular Economy , 2016 .

[5]  Ian Vázquez-Rowe,et al.  Assessing Energy and Environmental Efficiency of the Spanish Agri-Food System Using the LCA/DEA Methodology , 2018, Energies.

[6]  Carles M. Gasol,et al.  Life Cycle Assessment of apple and peach production, distribution and consumption in Mediterranean fruit sector , 2017 .

[7]  Abel O. Olorunnisola,et al.  Biogas as an alternative energy source and a waste management strategy in Northern Ethiopia , 2016 .

[8]  J. Amate,et al.  ‘Sustainable de-growth’ in agriculture and food: an agro-ecological perspective on Spain’s agri-food system (year 2000) , 2013 .

[9]  M. G. Molina,et al.  La gran transformación del sector agroalimentario español. Un análisis desde la perspectiva energética (1960-2010) , 2014 .

[10]  M Margallo,et al.  Life cycle assessment modelling of waste-to-energy incineration in Spain and Portugal , 2014, Waste management & research : the journal of the International Solid Wastes and Public Cleansing Association, ISWA.

[11]  M. Kummu,et al.  Lost food, wasted resources: global food supply chain losses and their impacts on freshwater, cropland, and fertiliser use. , 2012, The Science of the total environment.

[12]  Janusz Skorek,et al.  Energy and economic optimization of the repowering of coal-fired municipal district heating source by a gas turbine , 2017 .

[13]  Sora Yi,et al.  Evaluation of environmental impacts of food waste management by material flow analysis (MFA) and life cycle assessment (LCA) , 2016 .

[14]  Michael E. Webber,et al.  Wasted Food, Wasted Energy: The Embedded Energy in Food Waste in the United States , 2010, Environmental science & technology.

[15]  R. Rafieenia,et al.  Effect of Aeration Applied During Different Phases of Anaerobic Digestion , 2018 .

[16]  A. Carlsson-kanyama,et al.  Food and life cycle energy inputs: consequences of diet and ways to increase efficiency , 2003 .

[17]  Serenella Sala,et al.  Quantifying household waste of fresh fruit and vegetables in the EU. , 2018, Waste management.

[18]  Rajesh K. Sani,et al.  Thermophilic anaerobic digestion: enhanced and sustainable methane production from co-digestion of food and lignocellulosic wastes. , 2018 .

[19]  Serena Righi,et al.  Life Cycle Assessment of management systems for sewage sludge and food waste: centralized and decentralized approaches , 2013 .

[20]  Almudena Hospido,et al.  Carbon footprint along the Ecuadorian banana supply chain: methodological improvements and calculation tool. , 2016 .

[21]  Simone Manfredi,et al.  Prioritizing and optimizing sustainable measures for food waste prevention and management , 2018, Waste management.

[22]  Sonja Brodt,et al.  Energy Intensity of Agriculture and Food Systems , 2011 .

[23]  M Walker,et al.  Assessment of micro-scale anaerobic digestion for management of urban organic waste: A case study in London, UK. , 2017, Waste management.

[24]  D. Reinhart,et al.  Food waste and the food-energy-water nexus: A review of food waste management alternatives. , 2018, Waste management.

[25]  B. Popkin Reducing meat consumption has multiple benefits for the world's health. , 2009, Archives of internal medicine.

[26]  Serenella Sala,et al.  Food waste accounting along global and European food supply chains: State of the art and outlook , 2018, Waste management.

[27]  Olaf Thieme,et al.  Global Initiative on Food Loss and Waste reduction , 2013 .

[28]  Sven Lundie,et al.  LIFE CYCLE ASSESSMENT OF FOOD WASTE MANAGEMENT OPTIONS , 2005 .

[29]  M. Clarke,et al.  The implementation of decentralised biogas plants in Assam, NE India: The impact and effectiveness of the National Biogas and Manure Management Programme , 2014 .

[30]  C. N. Hewitt,et al.  The relative greenhouse gas impacts of realistic dietary choices , 2012 .

[31]  Per-Anders Hansson,et al.  Carbon footprint of food waste management options in the waste hierarchy – a Swedish case study , 2015 .

[32]  Simone Manfredi,et al.  Towards more sustainable management of European food waste: Methodological approach and numerical application , 2016, Waste management & research : the journal of the International Solid Wastes and Public Cleansing Association, ISWA.

[33]  Ulf Sonesson,et al.  The methodology of the FAO study: Global Food Losses and Food Waste - extent, causes and prevention”- FAO, 2011 , 2013 .

[34]  Pere Fullana,et al.  On the estimation of potential food waste reduction to support sustainable production and consumption policies , 2018, Food Policy.

[35]  N. G. Wright,et al.  The food waste hierarchy as a framework for the management of food surplus and food waste , 2014 .

[36]  J la Cour Jansen,et al.  Review of comparative LCAs of food waste management systems--current status and potential improvements. , 2012, Waste management.

[37]  David Maia,et al.  Construction of Biodigesters to Optimize the Production of Biogas from Anaerobic Co-Digestion of Food Waste and Sewage , 2018 .

[38]  Fabio De Menna,et al.  The Hidden Burden of Food Waste: The Double Energy Waste in Italy , 2016 .

[39]  Teiji Takahashi Food Insecurity in the World , 2004 .

[40]  U. Sonesson,et al.  Global food losses and food waste: extent, causes and prevention , 2011 .