Food system

Source: Wikipedia, the free encyclopedia.

The term food system describes the interconnected systems and processes that influence nutrition, food, health, community development, and agriculture. A food system includes all processes and infrastructure involved in feeding a population: growing, harvesting, processing, packaging, transporting, marketing, consumption, distribution, and disposal of food and food-related items. It also includes the inputs needed and outputs generated at each of these steps. Food systems fall within agri-food systems, which encompass the entire range of actors and their interlinked value-adding activities in the primary production of food and non-food agricultural products, as well as in food storage, aggregation, post-harvest handling, transportation, processing, distribution, marketing, disposal, and consumption.[1] A food system operates within and is influenced by social, political, economic, technological and environmental contexts. It also requires human resources that provide labor, research and education. Food systems are either conventional or alternative according to their model of food lifespan from origin to plate.[2][3][4] Food systems are dependent on a multitude of ecosystem services. For example, natural pest regulations, microorganisms providing nitrogen-fixation, and pollinators.[5]

According to the IPCC, the global food system, including all of the various industries involved in sustainable and conventional food systems, provide employment for 1 billion people.[6] This global food system is facing a number of challenges created by impeding global food security issues created by climate change and non-climate change stresses on the system.[6] About 34% of total greenhouse gas emissions are attributable to the global food system.[7][8][6] In 2020 an EU evidence review found that food system gas emissions are on course to increase by 30–40% by 2050 due to population growth and dietary change.[9] It is crucial to build the resilience of agrifood systems so that they have the capacity over time, in the face of any disruption, to sustainably ensure availability of and access to sufficient, safe and nutritious food for all, and sustain the livelihoods of agrifood systems' actors.[1]

Transitioning to sustainable food systems is critical for addressing global challenges such as climate change, hunger, biodiversity loss, and deforestation. Addressing issues at each stage in the system, can have system-wide effects for 30-40 percent of food produced is lost from post-harvest up to retail and the consumer.[10] Reducing food waste then reduces the environmental impacts of agriculture, such as land use impacts, and reducing food prices or preventing shortages. International policy has increasingly approached policy from a food systems perspective: Sustainable Development Goal 2: Zero Hunger and Sustainable Development Goal 12: "responsible consumption and production" focus on sustainable food systems and Sustainable and in September 2021 the United Nations hosted the first Food Systems Summit.[11]

Conventional food systems

Conventional food systems operate on economies of scale. These food systems are geared towards a production model that requires maximizing efficiency in order to lower consumer costs and increase overall production, and they utilize economic models such as vertical integration, economic specialization, and global trade. The growing soil quality degradation, climate change, and growing world population put pressure on agricultural land, leading to innovations to increase agricultural productivity on the limited available land and urban space. Though conventional farming practices have increased crop yield through the use of climate-smart agriculture (CSA), smallholder farming systems and limited knowledge of CSA remain constraints for enjoying economies of scale and sustainable crop production and food security.[12]

The term "conventional" when describing food systems is largely due to comparisons made to it by proponents of other food systems, collectively known as alternative food systems.

History of conventional food systems

The development of food systems can be traced back to the origins of in-situ agriculture and the production of food surpluses. These surpluses enabled the development of settled areas and contributed to the development of ancient civilizations, particularly those in the Fertile Crescent.[13] The system of trade associated with the exchange of foodstuffs also emerged in East Asia, North America, South America, and Subsaharan Africa with common commodities of exchange such as salt, spices, fish, grains, etc.[14] Through events in world history such as the conquests of Alexander the Great, the Crusades, the expansion of Islam, the journeys of Marco Polo, and the exploration and colonization of the Americas by Europeans led to the introduction and redistribution of new foods to the world at large, and food systems began to intermingle on a global scale. After World War II, the advent of industrialized agriculture and more robust global trade mechanisms have evolved into the models of food production, presentation, delivery, and disposal that characterize conventional food systems today.[15]

Impacts of conventional food systems

The development of conventional food systems is directly responsible for decreased food prices and increased food variety. Agronomic efficiency is driven by the necessity to constantly lower production expenses, and those savings can then be passed on to the consumer. Also, the advent of industrial agriculture and the infrastructure built around conventional food systems has enabled the world population to expand beyond the "Malthusian catastrophe" limitations. According to the IPCC, food supply per capita has increased by more than 30% since 1961.[6]

However, conventional food systems are largely based on the availability of inexpensive fossil fuels, which is necessary for mechanized agriculture, the manufacture or collection of chemical fertilizers, the processing of food products, and the packaging of the foods.[16] The increase in the availability of food since 1961 has primarily been driven by an 800% increase in the use of nitrogen fertilizers (which are fossil fuel dependent) and high water usage (an increase of over 100% since 1961).[6]

The impacts of these intense resource processes are many a varied: food processing began when the number of consumers started proliferating. The demand for cheap and efficient calories climbed, resulting in nutrition decline;[16] and industrialized agriculture, due to its reliance on economies of scale to reduce production costs, often leads to the compromising of local, regional, or even global ecosystems through fertilizer runoff, nonpoint source pollution,[17] and greenhouse gas emission.

The need to reduce production costs in an increasingly global market can cause the production of foods to be moved to areas where economic costs (labor, taxes, etc.) are lower or environmental regulations are laxer, which are usually further from consumer markets. For example, the majority of salmon sold in the United States is raised off the coast of Chile, due in large part to less stringent Chilean standards regarding fish feed and regardless of the fact that salmon are not indigenous in Chilean coastal waters.[18] The globalization of food production can result in the loss of traditional food systems in less developed countries, and have negative impacts on the population health, ecosystems, and cultures in those countries.[19] As a result of these forces, 2018 estimates suggest that 821 million people are currently undernourished, and 2 billion adults are overweight and obese.[6]

The issue of having minimal access to food, or access to primarily unhealthy food, is often described in terms of food security. The 1996 World Food Summit defined food security as a state in which "all people, at all times, have physical and economic access to sufficient, safe and nutritious food to meet their dietary needs and food preferences for an active and healthy life. "[20] Many groups argue that food security is largely determined by a given person's socioeconomic status, race, ethnicity, or other socially defined categories, making food access a social justice issue. This has given rise to numerous social movements whose goal is to increase access to healthy and culturally appropriate foods, among a wide variety of groups. These movements are often described as belonging to a more significant food justice movement.

Scientists estimated the extensive pesticide pollution risks worldwide with a new environmental model and found that a third of global agricultural land is at high risk for such pollution, of which a third are high-biodiversity regions.[21][22]

Hidden impacts

Recent studies aimed at measuring and valuing the hidden costs of agrifood systems have used True Cost Accounting (TCA), an accounting approach that measures and values the hidden impacts of economic activities on the environment, society and health. These impacts are regarded as hidden because they are not reflected in the market prices of products and services, i.e. not included in the operational profit and loss accounts.[23]

Quantified hidden costs of agrifood systems by cost category (left) and subcategory (right), 2020

The scope of these studies differs depending on the research question being addressed, the geographical coverage and the hidden impacts to be included in the analysis. There are many hidden impacts and some are difficult to measure or quantify. For example, environmental externalities such GHG emissions are easy to include in any TCA analysis due to a wide availability of relevant data. However, the hidden impacts related to human and social capitals might be more difficult to find. Examples include impacts on working conditions (human capital) and cultural identity (social capital).[23]

In 2019, a study by the World Bank estimated the hidden costs of foodborne diseases (from unsafe food) in low and middle-income countries and found these to amount to USD 95.2 billion.[24]

Three other studies have attempted to estimate the hidden costs of global agrifood systems. FOLU (2019) estimated them at USD 12 trillion, while Hendricks et al (2023) estimated them at USD 19 trillion.[25][26] However, the latter, acknowledges the uncertainly in the estimate and concludes that the value would be between USD 7.2 trillion and USD 51.8 trillion. The third estimate in the 2023 edition of the FAO report: The State of Food and Agriculture estimates global hidden costs from agrifood systems to be USD 12.7 trillion. This study also acknowledges the uncertainty in the estimate. The FAO report shows the global value of the hidden costs has a 95 percent chance of being at least USD 10.8 trillion and a 5 percent chance of being at least USD 16 trillion. Differently from the other two studies, the FAO report assesses hidden costs of agrifood systems at the national level for 154 countries. It states these national numbers are consistent and comparable covering the major dimensions (i.e. environmental, health and social) of agrifood system hidden costs, allowing not only comparison across countries, but also across the different dimensions.[27]

Sustainable food systems

A sustainable food system is a type of food system that provides healthy food to people and creates sustainable environmental, economic, and social systems that surround food. Sustainable food systems start with the development of sustainable agricultural practices, development of more sustainable food distribution systems, creation of sustainable diets, and reduction of food waste throughout the system. Sustainable food systems have been argued to be central to many[28] or all[29] 17 Sustainable Development Goals.[30]

Moving to sustainable food systems, including via shifting consumption to sustainable diets, is an important component of addressing the causes of climate change and adapting to it. A 2020 review conducted for the European Union found that up to 37% of global greenhouse gas emissions could be attributed to the food system, including crop and livestock production, transportation, changing land use (including deforestation), and food loss and waste.[31] Reduction of meat production, which accounts for ~60% of greenhouse gas emissions and ~75% of agriculturally used land,[32][33][34] is one major component of this change.[35]

The global food system is facing major interconnected challenges, including mitigating food insecurity, effects from climate change, biodiversity loss, malnutrition, inequity, soil degradation, pest outbreaks, water and energy scarcity, economic and political crises, natural resource depletion, and preventable ill-health.[36][37][38][39][40]

The concept of sustainable food systems is frequently at the center of sustainability-focused policy programs, such as proposed Green New Deal programs.

Local food systems

A map of wheat production (average percentage of land used for its production times average yield in each grid cell) across the world.

Local food systems are networks of food production and consumption that aim to be geographically and economically accessible and direct. They contrast to industrial food systems by operating with reduced food transportation and more direct marketing, leading to fewer people between the farmer and the consumer. As a result, relationships that are developed in local food systems emerge from face-to-face interactions, potentially leading to a stronger sense of trust and social connectedness between actors.[41] In addition to this, consumers can also encourage farmers to be environmentally friendly by teaching them about practices such as organic farming.[42] As a result, some scholars suggest that local food systems are a good way to revitalize a community.[43] The decreased distance of food transportation has also been promoted for its environmental benefits.[44] Also, farmers can enjoy a better quality of life because producing healthier food will allow them to be paid more, and not live under the poverty line.[45]

Both proponents and critics of local food systems warn that they can lead to narrow inward-looking attitudes or 'local food patriotism',[46] and that price premiums and local food cultures can be elitist and exclusive.[47] In contrast, many food sovereignty activists argue that local production of food is essential to achieving food security, especially among indigenous communities, and thus are crucial to the public health of those communities.[48]

Examples of local food systems include community-supported agriculture, farmers markets and farm to school programs. They have been associated with the 100 Mile Diet and Low Carbon Diet, as well as the slow food movement. The food sovereignty movement is also related to local food production. Food sovereignty activists argue that local communities should not only have access to nutritious and culturally appropriate foods, but that those communities should also be able to define the means by which their food is produced.[49] Various forms of urban agriculture locate food production in densely populated areas not traditionally associated with farming. Garden sharing, where urban and suburban homeowners offer land access to food growers in exchange for a share of the harvest, is a relatively new trend, at the extreme end of direct local food production.

An FAO study on food transport networks of 90 countries finds that where food is transported more locally and where the network is denser – such as in high-income countries and densely populated countries like China, India, Nigeria and Pakistan –, systematic disturbances (i.e., adverse events), have a much lower impact on increases in travel time and food costs than where food is transported further distances.[50]

Organic food systems

An organic certification

Organic food systems are characterized by a reduced dependence on chemical inputs and an increased concern for transparency and information. Organic produce is grown without the chemical pesticides and fertilizers of industrial food systems, and livestock is reared without the use of antibiotics or growth hormones. The reduced inputs of organic agriculture can also lead to a greater reliance on local knowledge, creating a stronger knowledge community amongst farmers.[51][52] The transparency of food information is vital for organic food systems as a means through which consumers are able to identify organic food.[53] As a result, a variety of certification bodies have emerged in organic food systems that set the standards for organic identification. Organic agriculture is promoted for the ecological benefits of reduced chemical application, the health benefits of lower chemical consumption, the economic benefits that accrue to farmers through a price premium, and the social benefits of increased transparency in the food system.

Organic food systems have been criticized for being elitist and inaccessible like local food systems. Critics have also suggested that organic agriculture has been conventionalized such that it mimics industrial food systems using pesticides and fertilizers that are organically derived [54]

Cooperatives in food systems

A greenhouse with salad of a cooperative
An organic food box of an organic food delivery service
A farmers' market offering food produced by community-supported agriculture that is also delivering online orders

Cooperatives can exist both at the farmer end of food production and the consumer end. Farming cooperatives refer to arrangements where farmers pool resources, either to cultivate their crops or get their crops to market. Consumer cooperatives often refer to food cooperatives where members buy a share in the store. Cooperative grocery stores, unlike corporate grocery stores, are socially owned, and thus surpluses cannot be taken from the store as profit. As a result, food co-ops do not work for profit, potentially keeping prices more cost representative. Other forms of cooperatives that have developed more recently include community-supported agriculture, where community members buy a share in a farm's harvest, and may also be engaged in farm labor, operating at both the consumer and producer end of food systems. Garden sharing pairs individual landowners and food growers, while variations on this approach organize groups of food gardeners for mutual assistance.

Producer associations and cooperatives reinforce small-scale agricultural producers' livelihoods by allowing the pooling of resources to achieve scale, facilitating access to productive resources, and enhancing  marketing power.[1] Coordination with other actors is also key to managing market risks.[1] Mutual benefits can be achieved, for example, through forwarding contracts: farmers receive guaranteed prices for their outputs regardless of market conditions, while processors and distributors receive products of a desired quality.[1] For farming cooperatives that share resources, the burden of investment is disbursed to all members rather than being concentrated in a single individual. A criticism of cooperatives is that reduced competition can reduce efficiency[55]

Alternative food systems

Alternative food systems refer to resilient foods or emergency foods, which can be defined as those foods, food production methods or interventions that would allow for significant food availability in the face of a global catastrophic food shock (GCFS).[56] Such alternatives may also help to decouple food production and land use, thereby avoiding the greenhouse gas emissions and habitat loss associated with agriculture.[57] An expected 345.2 million people projected to be food insecure in 2023 – more than double the number in 2020,[58] but a global catastrophe such as nuclear winter could threaten billions with mass starvation.[59] Several studies have argued resilient food could provide the calories to support the global population even without agriculture.[60][61] According to the book Feeding Everyone No Matter What and peer-reviewed study paths to a full solution include: global-scale conversion including natural gas-digesting bacteria (single cell protein), extracting food from leaves,[62][63] and conversion of fiber by enzymes, mushroom or bacteria growth, or a two-step process involving partial decomposition of fiber by fungi and/or bacteria and feeding them to animals such as beetles, ruminants (cattle, sheep, etc.), rats and chickens.[64] Most alternative food work covers carbohydrates and protein, but there are also ways to make synthetic fat[65] Indeed, because fats are generally achiral (see chirality), the may be synthesized without biological processes at high temperatures and pressures, the greater efficiency of which may make them more cost-effective than other synthetic macronutrients.[57] By mixing many alternative foods micro-nutrient balance is possible.[66] Substantially more research is needed in this area to realize resilient food systems for the globe and even wealthy nations.[67]

Fair trade

Fair trade may require decisions that lead to relevant supply-chain management.[68]

Fair trade has emerged in global food systems to create a more excellent balance between food price and the cost of producing it. It is mainly defined by more direct trading and communication systems whereby producers have greater control over the conditions of trade and garner a greater fraction of the sale price. The main goal of Fair Trade is to "change international commercial relations in such a way that disadvantaged producers can increase their control over their own future, have a fair and just return for their work, continuity of income and decent working and living conditions through sustainable development" [69] Like organic food systems, fair trade relies on transparency and the flow of information.[70] Well-known examples of fair trade commodities are coffee and cocoa.

Novel agricultural technologies

Vertical farms, automation, solar energy production, novel alternatives to pesticides, online food delivery ICTs, and other technologies may allow for localization or modified food production alongside policies such as eco-tariffs, targeted subsidies and meat taxes.[citation needed]

Climate change

Effects of climate change

The IPCC Special Report on Climate Change and Land describes the current global food system as potentially having major food security risks due to changes created by climate change, including changing local weather conditions, socioeconomic effects of climate change, vulnerability of certain types of agriculture (such as pastoral) and changes in diets due to availability.[6]

Effects on climate change

The heavy industrialization of USA, Europe and China is responsible for 90% of the world's pollution.
Deforestation in Indonesia is mainly driven by nonintervention in processes related to the production and consumption of palm oil and has a large impact on climate change.
Deforestation in Europe, 2020. The continent reduced its original vegetation cover to less than 30% in order to carry out its agriculture and livestock.

The food system is one of the largest sources of greenhouse gas emissions, attributable for between 21 and 37% of global emissions.[6] In 2020, an evidence review for the European Union's Scientific Advice Mechanism found that, without significant change, emissions would increase by 30–40% by 2050 due to population growth and changing consumption patterns, and concluded that "the combined environmental cost of food production is estimated to amount to some $12 trillion per year, increasing to $16 trillion by 2050".[9] Another 2020 study concluded that reducing emissions from the global food system to be essential for achieving the Paris Agreement's climate goals.[71][72]

The IPCC's and the EU's reports concluded that adapting the food system to reduce greenhouse gas emissions impacts and food security concerns, while shifting towards a sustainable diet, is feasible .[6]

Public policy

European Union

The European Union's Scientific Advice Mechanism has published a systematic review of all European policies related to sustainable food systems, and their analyses in the academic literature.[73]

In September 2019, the EU's Chief Scientific Advisors stated that adapting the European food system for the future should be a high priority for the EU:[74]

Although availability of food is not perceived as an immediate, major concern in Europe, the challenge to ensure a long-term, safe, nutritious and affordable supply of food, from both land and the oceans, remains. A portfolio of coordinated strategies is called for to address this challenge.

In January 2020, the EU put improvements to the food system at the core of the European Green Deal. The European Commission's 'Farm to Fork strategy for a sustainable food system' was published in May 2020, which laid out how European countries will reduce greenhouse gas emissions, protect biodiversity, reduce food waste and chemical pesticide use, and contribute to a circular economy.[75][76]

In April 2020, the EU's Scientific Advice Mechanism delivered to European Commissioners a Scientific Opinion on how to transition to a sustainable food system, informed by an evidence review report undertaken by European academies.[77]

In June 2023, the Scientific Advice Mechanism delivered a second piece of advice, this time on the role of consumers in a sustainable food system, again based on an evidence review report by SAPEA.[78] The main conclusion of this advice was:

Until now, the main policy focus in the EU has been on providing consumers with more information. But this is not enough. People choose food not just through rational reflection, but also based on many other factors: food availability, habits and routines, emotional and impulsive reactions, and their financial and social situation. So we should consider ways to unburden the consumer and make sustainable, healthy food an easy and affordable choice. That will require a mix of incentives, information and binding policies governing all aspects of food production and distribution.

Public–Private Partnerships

Private sector corporations have been successful in building partnerships with governments which allows discussion and collaboration for how food systems work and are governed. Public–private partnerships and private sector led multistakeholder governance have positioned corporations as a leading voice on decisions where public governance authorities have become dependent on private sector funding. Lobbying influences trade agreements for food systems which led to creating barriers to competition and technical barriers to trade.[79] Concerns around corporate governance within food systems as a substitute for regulation were raised by the Institute for Multi-Stakeholder Initiative Integrity.[80] In April 2023, United States Agency for International Development (USAID) and the Global Food Safety Initiative (GFSI) announced a Memorandum of Understanding (MOU) to improve food safety and sustainable food systems in Africa.[81]

Transparency

Transparency within food systems refers to the full disclosure of information about rules, procedures, and practices at all levels within a food production and supply chain.[82] Transparency ensures that consumers have detailed information about the production of a given food item. Traceability, by contrast, is the ability to trace to their origins all components in a food production and marketing chain, whether processed or unprocessed (e.g., meat, vegetables) foods. Concerns about transparency and traceability have been heightened with food safety scares such as bovine spongiform encephalopathy (BSE) and Escherichia coli (E. coli), but do not exclusively refer to food safety. Transparency is also important in identifying foods that possess extrinsic qualities that do not affect the nature of the food per se, but affect its production, such as animal welfare, social justice issues, and environmental concerns.[83]

One of the primary ways transparency is achieved is through certification and/or the use of food labels. In the United States, some certification originates in the public sector, such as the United States Department of Agriculture (USDA) Organic label. Others have their origin in private sector certification (e.g., Humanely Raised, Certified Humane). Some labels do not rely on certification, such as the USDA's Country of Origin Label (COOL).

Participation in local food systems such as Community Supported Agriculture (CSA), Farmers Markets, food cooperatives, and farmer cooperatives also enhances transparency. Diverse program are promoting purchase of locally grown and marketed foods.

In June 2023, the Scientific Advice Mechanism to the European Commission concluded that "Evidence generally supports a moderate impact of nutrition labelling on (un)healthy consumption in different contexts (retail, out-of-home). Sustainability-oriented labels tend to reach those who are already motivated and interested, and they strongly depend on the trustworthiness of labels, given that sustainability cannot be directly observed by consumers. However, there is much less research devoted to sustainability labelling in comparison to nutritional labelling. To conclude, shaping the information environment through labelling is necessary but not sufficient to advance healthy and sustainable diets".[78]

Labeling

USDA Organic Label
Organic (USA) – The USDA Organic label indicates that the product has been produced in accordance with the USDA's Federal Organic Standard, part of the National Organic Program federal regulatory framework. This label is applied to fruits, vegetables, meat, eggs and dairy products. Some states, such as California, have their own organic label. Organic labelling is prominent internationally as well.
Fair Trade Show in UK
Fair Trade – Indicates that the product has been grown and marketed in accordance with Fair Trade standards. This is an independent certification, awarded by FLO-CERT and overseen by FLO International. Major food items that are marketed under Fair Trade are coffee, tea and chocolate. Many items other than food are sold with a Fair Trade label.
Food Alliance Certified – Food Alliance is a nonprofit organization that certifies farms, ranches, and food processors and distributors for safe and fair working conditions, humane treatment of animals, and good environmental stewardship. Food Alliance Certified products come from farms, ranches and food processors that have met meaningful standards for social and environmental responsibility, as determined through an independent third-party audit. Food Alliance does not certify genetically modified crops or livestock. Meat or dairy products come from animals that are not treated with antibiotics or growth hormones. Food Alliance Certified foods never contain artificial colors, flavors, or preservatives.[84]
Examples of COOL Labeling
Country of Origin – This label was created by enactment of the 2002 Farm Bill. The US Department of Agriculture is responsible for its implementation, which began 30 September 2008. The bill mandates country of origin labeling for several products, including beef, lamb, pork, fish, chicken, perishable agricultural commodities and some nuts. USDA rules provide specifics as to documentation, timetables and definitions.[85] There is not one specific label to indicate the country of origin; they will vary by country.
American Humane Certified – This certification is provided by the American Humane Association, and ensures that farm animals are raised according to welfare standards that provide for adequate housing, feed, healthcare and behavior expression. Antibiotics are not used except for therapeutic reasons; growth promoters are not used. Other issues including transport, processing and biosecurity are addressed as well. Species covered are poultry, cattle and swine.[86]
Certified Humane Raised & Handled – This label ensures that production meets the Humane Farm Animal Care Program standards, which addresses housing, diet (excluding routine use of hormones or antibiotics) and natural behavior. Additionally, producers must comply with food safety and environmental protection regulations. They must meet standards set by the American Meat Institute, that are more stringent than those laid out in the Federal Humane Slaughter Act. Certification has been applied to beef, poultry and eggs, pork, lamb, goat, turkey, veal, dairy products and wool.[87]

See also

Sources

 This article incorporates text from a free content work. Licensed under CC BY-SA 3.0 (license statement/permission). Text taken from The State of Food and Agriculture 2019. Moving forward on food loss and waste reduction, In brief​, 24, FAO, FAO.

 This article incorporates text from a free content work. Licensed under CC BY-SA 3.0 (license statement/permission). Text taken from The State of Food and Agriculture 2021. Making agrifood systems more resilient to shocks and stresses, In brief​, FAO, FAO.

 This article incorporates text from a free content work. Licensed under CC BY-SA 3.0 (license statement/permission). Text taken from Robust transport networks support agrifood systems' resilience​, FAO, FAO.

Notes and references

  1. ^ a b c d e The State of Food and Agriculture 2021. Making agrifood systems more resilient to shocks and stresses, In brief. Rome: FAO. 2021. doi:10.4060/cb7351en. ISBN 978-92-5-135208-3. S2CID 244536830.
  2. ^ "A Primer on Community Food Systems: Linking Food, Nutrition and Agriculture" (PDF). Farmland Information Center. n.d. Retrieved 2019-01-12. all processes involved in keeping us fed: growing, harvesting, processing (or transforming or changing), packaging, transporting, marketing, consuming and disposing of food and food packages.
  3. ^ Ericksen, Polly J. (February 2008). "Conceptualizing food systems for global environmental change research" (PDF). Global Environmental Change. 18 (1): 234–245. doi:10.1016/j.gloenvcha.2007.09.002. Retrieved 2019-01-12.
  4. ^ Development Policy Review, 2003, 21 (5-6): 531-553 Food Policy Old and New - Simon Maxwell and Rachel Slater∗
  5. ^ Zurek, Monika; Ingram, John; Sanderson Bellamy, Angelina; Goold, Conor; Lyon, Christopher; Alexander, Peter; Barnes, Andrew; Bebber, Daniel P.; Breeze, Tom D.; Bruce, Ann; Collins, Lisa M.; Davies, Jessica; Doherty, Bob; Ensor, Jonathan; Franco, Sofia C. (2022-10-17). "Food System Resilience: Concepts, Issues, and Challenges". Annual Review of Environment and Resources. 47 (1): 511–534. doi:10.1146/annurev-environ-112320-050744. hdl:20.500.11820/892d615a-5f55-45b7-9afa-d98304809e18. ISSN 1543-5938. S2CID 252457011.
  6. ^ a b c d e f g h i Mbow, C.; Rosenzweig, C.; Barioni, L. G.; Benton, T.; et al. (2019). "Chapter 5: Food Security" (PDF). IPCC Special Report on Climate Change and Land. pp. 439–442.
  7. ^ "FAO - News Article: Food systems account for more than one third of global greenhouse gas emissions". www.fao.org. Retrieved 22 April 2021.
  8. ^ Crippa, M.; Solazzo, E.; Guizzardi, D.; Monforti-Ferrario, F.; Tubiello, F. N.; Leip, A. (March 2021). "Food systems are responsible for a third of global anthropogenic GHG emissions". Nature Food. 2 (3): 198–209. doi:10.1038/s43016-021-00225-9. ISSN 2662-1355. PMID 37117443. S2CID 233831795.
  9. ^ a b SAPEA (2020). A sustainable food system for the European Union (PDF). Berlin: Science Advice for Policy by European Academies. p. 39. doi:10.26356/sustainablefood. ISBN 978-3-9820301-7-3.
  10. ^ "Reduced Food Waste". Project Drawdown. 2020-02-12. Retrieved 2021-10-10.
  11. ^ "Outrage + Optimism: 117. The Seeds Are Sown for a Food Revolution with Agnes Kalibata". outrageandoptimism.libsyn.com. Retrieved 2021-10-10.
  12. ^ Zerssa, Gebeyanesh; Feyssa, Debela; Kim, Dong-Gill; Eichler-Löbermann, Bettina (March 2021). "Challenges of Smallholder Farming in Ethiopia and Opportunities by Adopting Climate-Smart Agriculture". Agriculture. 11 (3): 192. doi:10.3390/agriculture11030192.
  13. ^ (2004); Manning, R.; Against the Grain: How Agriculture Hijacked Civilization, New York:North Point Press
  14. ^ (1994); Toussaint-Samat, M. and Bell, A.; A History of Food ; Blackwell Publishing
  15. ^ (1998); Welch, R., Graham, R.; "A new paradigm for world agriculture: meeting human needs, Productive, sustainable, nutritious"; Field Crops Research #60,.
  16. ^ a b Nestle, Marion. (2013). Food Politics: How the Food Industry Influences Nutrition and Health." Los Angeles, California: University of California Press. ISBN 978-0520275966
  17. ^ (1993); Schnitkey, G.D., Miranda, M.; "The Impact of Pollution Controls on Livestock Crop producers", Journal of Agricultural and Resource Economics
  18. ^ (2001); Bjorndal, T., "The Competitiveness of the Chilean Salmon Aquaculture Industry", Foundation for Research in Economics and Business Administration, Bergen, Norway
  19. ^ (1996); Kuhnlein, H.V., Receveur, O.; Dietary Change and Traditional Food Systems of Indigenous Peoples; Centre for Nutrition and the Environment of Indigenous Peoples, and School of Dietetics and Human Nutrition, McGill University, Quebec, Canada
  20. ^ Food and Agriculture Organization (November 1996). "Rome Declaration on Food Security and World Food Summit Plan of Action". Retrieved 26 March 2020.
  21. ^ "A third of global farmland at 'high' pesticide pollution risk". phys.org. Retrieved 22 April 2021.
  22. ^ Tang, Fiona H. M.; Lenzen, Manfred; McBratney, Alexander; Maggi, Federico (April 2021). "Risk of pesticide pollution at the global scale". Nature Geoscience. 14 (4): 206–210. Bibcode:2021NatGe..14..206T. doi:10.1038/s41561-021-00712-5. ISSN 1752-0908. S2CID 232415314.
  23. ^ a b True cost accounting applications for agrifood systems policymakers. FAO. 2023-11-06. doi:10.4060/cc8341en. ISBN 978-92-5-138282-0.
  24. ^ Jaffee, Steven; Henson, Spencer; Unnevehr, Laurian; Grace, Delia; Cassou, Emilie (2019). The Safe Food Imperative: Accelerating Progress in Low- and Middle-Income Countries. Washington, DC: World Bank. ISBN 978-1-4648-1345-0.
  25. ^ "Global report". Food and Land Use Coalition. Retrieved 2024-01-23.
  26. ^ Hendriks, Sheryl; de Groot Ruiz, Adrian; Acosta, Mario Herrero; Baumers, Hans; Galgani, Pietro; Mason-D’Croz, Daniel; Godde, Cecile; Waha, Katharina; Kanidou, Dimitra (2023), von Braun, Joachim; Afsana, Kaosar; Fresco, Louise O.; Hassan, Mohamed Hag Ali (eds.), "The True Cost of Food: A Preliminary Assessment", Science and Innovations for Food Systems Transformation, Cham: Springer International Publishing, pp. 581–601, doi:10.1007/978-3-031-15703-5_32, ISBN 978-3-031-15703-5, retrieved 2024-01-23
  27. ^ In Brief to The State of Food and Agriculture 2023 (Report). FAO. 2023-11-06. doi:10.4060/cc7937en.
  28. ^ SAPEA (2020). A sustainable food system for the European Union (PDF). Berlin: SAPEA, Science Advice for Policy by European Academies. p. 22. doi:10.26356/sustainablefood. ISBN 978-3-9820301-7-3.
  29. ^ "FOOD SUSTAINABILITY: KEY TO REACH SUSTAINABLE DEVELOPMENT GOALS". BCFN Foundation: Food and Nutrition Sustainability Index. 2018-10-01. Retrieved 2019-11-26.
  30. ^ "Sustainable food systems" (PDF). Food and Agricultural Organization of the United Nations.
  31. ^ SAPEA (2020). A sustainable food system for the European Union (PDF). Berlin: SAPEA, Science Advice for Policy by European Academies. p. 39. doi:10.26356/sustainablefood. ISBN 978-3-9820301-7-3.
  32. ^ Xu, Xiaoming; Sharma, Prateek; Shu, Shijie; Lin, Tzu-Shun; Ciais, Philippe; Tubiello, Francesco N.; Smith, Pete; Campbell, Nelson; Jain, Atul K. (September 2021). "Global greenhouse gas emissions from animal-based foods are twice those of plant-based foods". Nature Food. 2 (9): 724–732. doi:10.1038/s43016-021-00358-x. hdl:2164/18207. ISSN 2662-1355. PMID 37117472. S2CID 240562878.
    News article: "Meat accounts for nearly 60% of all greenhouse gases from food production, study finds". The Guardian. 13 September 2021. Retrieved 27 May 2022.
  33. ^ "If the world adopted a plant-based diet we would reduce global agricultural land use from 4 to 1 billion hectares". Our World in Data. Retrieved 27 May 2022.
  34. ^ "20 meat and dairy firms emit more greenhouse gas than Germany, Britain or France". The Guardian. 7 September 2021. Retrieved 27 May 2022.
  35. ^ Parlasca, Martin C.; Qaim, Matin (5 October 2022). "Meat Consumption and Sustainability". Annual Review of Resource Economics. 14: 17–41. doi:10.1146/annurev-resource-111820-032340. ISSN 1941-1340.
  36. ^ Scarborough, Peter; Clark, Michael; Cobiac, Linda; Papier, Keren; Knuppel, Anika; Lynch, John; Harrington, Richard; Key, Tim; Springmann, Marco (2023). "Vegans, vegetarians, fish-eaters and meat-eaters in the UK show discrepant environmental impacts". Nature Food. 4 (7): 565–574. doi:10.1038/s43016-023-00795-w. PMC 10365988. PMID 37474804.
  37. ^ Singh, Brajesh K.; Arnold, Tom; Biermayr-Jenzano, Patricia; Broerse, Jacqueline; Brunori, Gianluca; Caron, Patrick; De Schutter, Olivier; Fan, Shenggen; Fanzo, Jessica; Fraser, Evan; Gurinovic, Mirjana; Hugas, Marta; McGlade, Jacqueline; Nellemann, Christine; Njuki, Jemimah; Sonnino, Roberta; Tuomisto, Hanna L.; Tutundjian, Seta; Webb, Patrick; Wesseler, Justus (November 2021). "Enhancing science–policy interfaces for food systems transformation". Nature Food. 2 (11): 838–842. doi:10.1038/s43016-021-00406-6. ISSN 2662-1355. PMID 37117505. S2CID 243475557.
  38. ^ Schipanski, Meagan E.; MacDonald, Graham K.; Rosenzweig, Steven; Chappell, M. Jahi; Bennett, Elena M.; Kerr, Rachel Bezner; Blesh, Jennifer; Crews, Timothy; Drinkwater, Laurie; Lundgren, Jonathan G.; Schnarr, Cassandra (2016-05-04). "Realizing Resilient Food Systems". BioScience. 66 (7): 600–610. doi:10.1093/biosci/biw052. ISSN 1525-3244.
  39. ^ Tendall, D. M.; Joerin, J.; Kopainsky, B.; Edwards, P.; Shreck, A.; Le, Q. B.; Kruetli, P.; Grant, M.; Six, J. (2015-10-01). "Food system resilience: Defining the concept". Global Food Security. 6: 17–23. doi:10.1016/j.gfs.2015.08.001. ISSN 2211-9124.
  40. ^ "2022 Global Food Policy Report: Climate Change and Food Systems - World | ReliefWeb". reliefweb.int. 15 May 2022. Retrieved 2023-02-21.
  41. ^ Hinrichs, Clare. 2000. "Embeddedness and local food systems: notes on two types of direct agricultural market" Journal of Rural Studies 16: 295-303
  42. ^ "About Local Food Systems".
  43. ^ Feenstra, Gail. 1997. "Local food systems and sustainable communities" American journal of alternative agriculture 12(1) p. 28-36
  44. ^ Jones, Andy. 2002. "An Environmental Assessment of Food Supply Chains: A Case Study on Dessert Apples" Environmental Management 30(4) p. 560-576
  45. ^ "About Local Food Systems".
  46. ^ Bell and Valentine (1997). D. Bell and G. Valentine Consuming Geographies: We are Where We Eat, Routledge, London and New York
  47. ^ Guthman, Julie. 2004. Agrarian Dreams: the Paradox of Organic Farming in California. Berkeley : University of California Press
  48. ^ Murphy, Andi (2019-07-24). "Indigenous Food Security is Dependent on Food Sovereignty". Civil Eats. Retrieved 2022-07-31.
  49. ^ Declaration of Nyéléni (2007) Retrieved from https://viacampesina.org/en/declaration-of-nyi/
  50. ^ Robust transport networks support agrifood systems' resilience. Rome: FAO. 2021. doi:10.4060/cb7663en. ISBN 978-92-5-135333-2. S2CID 244536912.
  51. ^ Morgan, K and J. Murdoch (2000) "Organic vs. conventional agriculture: knowledge, power and innovation in the food chain" Geoforum 31(2): 159-173
  52. ^ Renkin, A.M., K. Lyons and R.C.N. Laurence (2002) in Proceedings from the 14th IFOAM Organic World Congress, Victoria, BC, August 2002
  53. ^ Raynolds, L. (2000) "Re-embedding global agriculture: The international organic and fair trade movements" Agriculture and Human Values 17(3): 297-309
  54. ^ Altieri, M. and P. Rossett. 1997. "Agroecology versus input substitution: A fundamental contradiction of sustainable agriculture" Society and Natural Resources 10(3): 283 - 296
  55. ^ Deininger, Klaus (1995) Collective agricultural production: A solution for transition economies?. WorldDevelopment, Vol. 23, No. 8, pp. 1317-1334
  56. ^ "Resilient food - EA Forum". forum.effectivealtruism.org. Retrieved 2023-02-26.
  57. ^ a b Davis, Steven J.; Alexander, Kathleen; Moreno-Cruz, Juan; Hong, Chaopeng; Shaner, Matthew; Caldeira, Ken; McKay, Ian (November 2023). "Food without agriculture". Nature Sustainability. doi:10.1038/s41893-023-01241-2.
  58. ^ "A global food crisis | World Food Programme". www.wfp.org. Retrieved 2023-02-26.
  59. ^ Robock, Alan; Toon, Owen Brian (2012-03-01). "Self-assured destruction: The climate impacts of nuclear war". Bulletin of the Atomic Scientists. 68 (5): 66–74. Bibcode:2012BuAtS..68e..66R. doi:10.1177/0096340212459127. ISSN 0096-3402. S2CID 14377214.
  60. ^ stacey. "Publications". ALLFED - Alliance to Feed the Earth in Disasters. Retrieved 2023-02-26.
  61. ^ Baum, Seth D.; Denkenberger, David C.; Pearce, Joshua M.; Robock, Alan; Winkler, Richelle (2015-06-01). "Resilience to global food supply catastrophes". Environment Systems and Decisions. 35 (2): 301–313. Bibcode:2015EnvSD..35..301B. doi:10.1007/s10669-015-9549-2. ISSN 2194-5411. S2CID 44220632.
  62. ^ Fist, Tim; Adesanya, Adewale A.; Denkenberger, David; Pearce, Joshua M. (November 2021). "Global distribution of forest classes and leaf biomass for use as alternative foods to minimize malnutrition". World Food Policy. 7 (2): 128–146. doi:10.1002/wfp2.12030. ISSN 2372-8639. S2CID 240561101.
  63. ^ "Leaf for Life Homepage". www.leafforlife.org. Retrieved 2023-02-26.
  64. ^ Denkenberger, David C.; Pearce, Joshua M. (2015-09-01). "Feeding everyone: Solving the food crisis in event of global catastrophes that kill crops or obscure the sun". Futures. Confronting Future Catastrophic Threats To Humanity. 72: 57–68. doi:10.1016/j.futures.2014.11.008. ISSN 0016-3287. S2CID 153917693.
  65. ^ García Martínez, Juan B.; Alvarado, Kyle A.; Denkenberger, David C. (January 2022). "Synthetic fat from petroleum as a resilient food for global catastrophes: Preliminary techno-economic assessment and technology roadmap". Chemical Engineering Research and Design. 177: 255–272. doi:10.1016/j.cherd.2021.10.017. ISSN 0263-8762. S2CID 239499352.
  66. ^ Denkenberger, David; Pearce, Joshua M. (November 2018). "Micronutrient Availability in Alternative Foods During Agricultural Catastrophes". Agriculture. 8 (11): 169. doi:10.3390/agriculture8110169. ISSN 2077-0472.
  67. ^ https://academic.oup.com/bioscience/article/66/7/600/2463250. Retrieved 2023-02-26. {{cite web}}: Missing or empty |title= (help)
  68. ^ cf. Andreas Wieland, Carl Marcus Wallenburg (2011): Supply-Chain-Management in stürmischen Zeiten. Berlin.
  69. ^ Fairtrade Foundation (1999). "The Fairtrade Foundation." <"The Fairtrade Foundation, London, UK | Home of the FAIRTRADE Mark". Archived from the original on 2005-06-01. Retrieved 2005-05-31.>
  70. ^ Raynolds, L. (2000) "Re-embedding global agriculture: The international organic and fair trade movements" Agriculture and Human Values 17(3): 297-309
  71. ^ "Reducing global food system emissions key to meeting climate goals". phys.org. Retrieved 8 December 2020.
  72. ^ Clark, Michael A.; Domingo, Nina G. G.; Colgan, Kimberly; Thakrar, Sumil K.; Tilman, David; Lynch, John; Azevedo, Inês L.; Hill, Jason D. (6 November 2020). "Global food system emissions could preclude achieving the 1.5° and 2°C climate change targets". Science. 370 (6517): 705–708. Bibcode:2020Sci...370..705C. doi:10.1126/science.aba7357. ISSN 0036-8075. PMID 33154139. S2CID 226254942. Retrieved 8 December 2020.
  73. ^ SAPEA (2020). A sustainable food system for the European Union: A systematic review of the European policy ecosystem (PDF). Berlin: Science Advice for Policy by European Academies. doi:10.26356/sustainablefoodreview. ISBN 978-3-9820301-7-3.
  74. ^ Group of Chief Scientific Advisors (25 September 2019). "Scoping paper: Towards an EU Sustainable Food System" (PDF). EU Scientific Advice Mechanism.
  75. ^ Binns, John (2019-12-10). "Farm to Fork strategy for sustainable food". Food Safety - European Commission. Retrieved 2020-04-14.
  76. ^ "Communication: A Farm to Fork Strategy for a fair, healthy and environmentally-friendly food system | European Commission". commission.europa.eu. Retrieved 2023-04-27.
  77. ^ "The shift to a more sustainable food system is inevitable. Here's how to make it happen | SAPEA". www.sapea.info. Retrieved 2020-04-14.
  78. ^ a b "Towards sustainable food consumption – SAPEA". Retrieved 2023-06-29.
  79. ^ "Who's Tipping the Scales?". ipes-food.org. IPES-Food.
  80. ^ Not Fit-for-Purpose The Grand Experiment of Multi-Stakeholder Initiatives in Corporate Accountability, Human Rights and Global Governance. San Francisco: Institute for Multi-Stakeholder Initiative Integrity: MSI Integrity. July 2020.
  81. ^ "USAID Signs Partnership with the Global Food Safety Initiative". usaid.gov. United States Agency for International Development. 26 April 2023.
  82. ^ VonBailey, D., Jones, E., & Dickinson, D. L. (2002). Knowledge Management and Comparative International Strategies on Vertical Information Flow in the Global Food System. Amer. J. Agr. Econ. 87: 1337-1344.
  83. ^ Unnevehr, L. & Roberts, T. (2002). Food safety incentives in a changing world food system. Food Control 13(2):73-76.
  84. ^ Food Alliance Certified. https://web.archive.org/web/20100919221751/http://foodalliance.org/
  85. ^ Mandatory Country of Origin Labeling - Interim Final Rule for Meat, Perishable Agricultural Commodities, Peanuts, Macadamia Nuts, Pecans, and Ginseng. USDA 8/28/08. http://www.ams.usda.gov/.
  86. ^ American Humane Association. http://www.americanhumane.org/
  87. ^ Humane Farm Animal Care. http://www.certifiedhumane.com

External links