Eight ways to halt a global food crisis - 8 minutes read
Eight ways to halt a global food crisis
There are serious challenges to global food supply everywhere we look. Intensive use of fertilisers in the US Midwest is causing nutrients to run off into rivers and streams, degrading the water quality and causing a Connecticut-size dead zone in the Gulf of Mexico. Chocolate production will soon be challenged in West Africa – home to over half of global production. A variety of nutritional impacts are predicted due to increased atmospheric carbon dioxide—including decreased protein content in food, which has a potential to exacerbate malnutrition. And this is just a very small sample of the risks to the food supply chain that are foreseen.
The future of food then, may sound rather bleak. But this does not have to be the case. The food system could become part of the solution for environmental challenges, if we make some changes to it. It could also be an instrument of human health, well-being, dignity, and livelihood—rather than the opposite.
But this won't happen without a radical rethink of our food systems and consumption patterns across the globe—particularly within the context of our cities. Upwards of 75% of the global north's population is urbanised and the global south is rapidly moving in this direction. Strategies for how these city regions can be fed using more local resources are crucial.
Those living in the urban global north are very comfortable with having any foods desired available at any point across the calendar year. This comes at a high cost. Foods transported by air cause nearly four times the CO₂ released compared to truck and 38 times that of a comparable amount transported by rail. Biodiversity and ecosystem loss threatens food production—and meanwhile, agriculture is a key driver of this loss. Furthermore, excessive water use for export agriculture in water-stressed areas can negatively impact local food and livelihoods—for example to secure large quantities of avocados for global north markets.
If we are to avoid some of these crises, we need to re-imagine where our food comes from and move, at least in part, towards more seasonal diets with a lower use of land and a serious reduction in global trade—especially for fruits, vegetables, and protein.
We can do all of this by addressing eight factors that have exacerbated and reinforced environmental disasters in our food systems.
It is especially important that meat consumption and excess calories in countries with high levels of meat consumption and obesity are reduced. Consuming far less meat provides the greatest ability to feed more people with less land within the US, for example, where meat consumption is particularly high. Every global study of diet and greenhouse gases indicates that reduced meat consumption is the biggest driver of reducing greenhouse gas release via dietary change. Approximately 1.1m hectares of excess corn production are needed to produce the excess calories consumed by just Americans annually.
Greater organic and agroecological strategies should be prioritised over highly industrialised farming practices. These forms of farming use much less fertiliser—which is not only bad for biodiversity but also produces high emissions. In 2011, agriculture in my home state of Michigan collectively purchased about 200,000 metric tons of nitrogen fertiliser at a CO₂ cost of 1.34 million metric tons (the equivalent of that produced by 291,000 US cars in a year). Meanwhile, organic bread wheat production in the UK appears to use less energy per ton than conventional production, with very little of it accrued from nitrogen fertiliser production and use.
Large quantities of food are needed for any city region—an American city region of a million people will require about 900m kg of food annually. Although "food miles" are problematic as a discriminator for greenhouse gas release, shorter supply chains are probably more amenable to electric vehicle transportation than long-distance transport—and hence ultimately to renewable energy use. As such, cities should aim to source their food from the surrounding region rather than globally. Within city regions it should also be possible to use waste recycling more robustly, creating carbon cycles as well as biogeochemical cycles for plant nutrients such as phosphorus and nitrogen. Since phosphorus is essential and non-renewable while production of nitrogen fertilisers requires a great input of energy this is very useful.
Although food is lost throughout the supply chain, it's estimated the greatest losses occur at the consumer level in the global north. In addition, a large amount of produce is wasted for not meeting retail cosmetic standards. All of the energy towards production, transportation, and processing of this food is also wasted. This modern culture of waste must be addressed.
Some crops are grown in an intensely concentrated manner, which leaves them vulnerable to climate changes and pests. For example, over half of US fresh produce and nuts are grown in California, and a number of these crops will be negatively impacted this century. While there is research to develop more draught and heat tolerant varieties across a range of crops it also seems prescient to distribute production more broadly. Variations in weather patterns can make this a challenge. But structures such as poly tunnels can markedly expand the season – to 12 months for lettuce and an additional two-to-three months for tomatoes. And a number of crops, for example apples, can be stored fresh for several months with controlled atmosphere storage.
Making negative effects (or costs) of production (such as soil loss) transparent so that all costs are accounted for and then rewarding farmers for things such as soil carbon sequestration, minimised external inputs, and low energy use instead of just total production would greatly help reduce these impacts.
The idea of farming insects and jellyfish are just some examples of the innovative suggestions that have been made for diversifying protein sources beyond meat and, say, soya. This would allow for reduced levels of animal protein in the global north and increased levels in much of the global south.
Very little of the global north's enormous farm policy budgets tend to be spent on policies such as conservation, agroecological research, and organic production. Policies that stimulate new farmer development, regional market and supply chain development (such as food hubs), prioritise appropriate technology development at smaller scales and price points (including robotics), sustainable energy production and research to minimise external inputs while maintaining high productivity are needed in order to help propel their development.
All in all, much more attention needs to be paid on the sustainability of the planet's urban food systems. If the situation continues unchanged, our food supply chains will soon be in deep trouble.
This article is republished from The Conversation under a Creative Commons license. Read the original article.
Source: Phys.org
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Keywords:
2007–08 world food price crisis • Food security • Intensive farming • Fertilizer • Midwestern United States • Nutrient • Surface runoff • Riparian zone • Stream • Water quality • Connecticut • Dead zone (ecology) • Gulf of Mexico • Chocolate • West Africa • Earth • Nutrition • Carbon dioxide • Protein • Malnutrition • Food security • Supply chain • The Future of Food • Food systems • Environmentalism • Health • Quality of life • Consumption (economics) • North–South divide • World population • Urbanization • North–South divide • Resource • North–South divide • Calendar year • Food • Atmosphere of Earth • Carbon dioxide • Biodiversity • Ecosystem • Food industry • Agriculture • Water use • Agriculture • Local food • North–South divide • Market (economics) • Food • Season • Diet (nutrition) • Land • Fruit • Vegetable • Protein • Calorie • Meat • Consumption (economics) • Obesity • Land • Meat • Consumption (economics) • Globalization • Diet (nutrition) • Greenhouse gas • Meat • Greenhouse gas • Diet (nutrition) • Maize • Manufacturing • Calorie • Organic farming • Agroecology • Industrialisation • Agriculture • Agriculture • Fertilizer • Biodiversity • Air pollution • Agriculture • Michigan • Tonne • Fertilizer • Carbon dioxide • Tonne • Carbon dioxide equivalent • United States dollar • Car • Organic farming • Common wheat • Manufacturing • Energy • Ton • Intensive farming • Manufacturing • Fertilizer • Manufacturing • Food • Food miles • Greenhouse gas • Supply chain • Electric vehicle • Transport • Transport • Renewable energy commercialization • Recycling • Carbon • Biogeochemical cycle • Plant nutrition • Phosphorus • Nitrogen • Phosphorus • Essential amino acid • Non-renewable resource • Manufacturing • Nitrogen • Fertilizer • Factors of production • Energy • Food • Supply chain • Consumer • North–South divide • Production (economics) • Retail • Cosmetics • Standards organization • Energy • Manufacturing • Transport • Food processing • Food • Waste • Crop • Climate • Pest (organism) • California • Crop • Working animal • Weather • Season • Lettuce • Tomato • Crop • Apple • Controlled atmosphere • Manufacturing • Erosion • Soil carbon • Carbon sequestration • Efficient energy use • Manufacturing • Agriculture • Jellyfish • Protein • Beyond Meat • Soybean • Protein • North–South divide • North–South divide • North–South divide • Farm • Policy • Policy • Conservation biology • Agroecology • Research • Organic farming • Policy • Farmer • Economic development • Regional planning • Market (economics) • Supply chain • Food hubs • Appropriate technology • Research and development • Robotics • Sustainable energy • Energy development • Research • Factors of production • Productivity • Urban planning • Sustainability • Urban planning • Food systems • Creative Commons license •
There are serious challenges to global food supply everywhere we look. Intensive use of fertilisers in the US Midwest is causing nutrients to run off into rivers and streams, degrading the water quality and causing a Connecticut-size dead zone in the Gulf of Mexico. Chocolate production will soon be challenged in West Africa – home to over half of global production. A variety of nutritional impacts are predicted due to increased atmospheric carbon dioxide—including decreased protein content in food, which has a potential to exacerbate malnutrition. And this is just a very small sample of the risks to the food supply chain that are foreseen.
The future of food then, may sound rather bleak. But this does not have to be the case. The food system could become part of the solution for environmental challenges, if we make some changes to it. It could also be an instrument of human health, well-being, dignity, and livelihood—rather than the opposite.
But this won't happen without a radical rethink of our food systems and consumption patterns across the globe—particularly within the context of our cities. Upwards of 75% of the global north's population is urbanised and the global south is rapidly moving in this direction. Strategies for how these city regions can be fed using more local resources are crucial.
Those living in the urban global north are very comfortable with having any foods desired available at any point across the calendar year. This comes at a high cost. Foods transported by air cause nearly four times the CO₂ released compared to truck and 38 times that of a comparable amount transported by rail. Biodiversity and ecosystem loss threatens food production—and meanwhile, agriculture is a key driver of this loss. Furthermore, excessive water use for export agriculture in water-stressed areas can negatively impact local food and livelihoods—for example to secure large quantities of avocados for global north markets.
If we are to avoid some of these crises, we need to re-imagine where our food comes from and move, at least in part, towards more seasonal diets with a lower use of land and a serious reduction in global trade—especially for fruits, vegetables, and protein.
We can do all of this by addressing eight factors that have exacerbated and reinforced environmental disasters in our food systems.
It is especially important that meat consumption and excess calories in countries with high levels of meat consumption and obesity are reduced. Consuming far less meat provides the greatest ability to feed more people with less land within the US, for example, where meat consumption is particularly high. Every global study of diet and greenhouse gases indicates that reduced meat consumption is the biggest driver of reducing greenhouse gas release via dietary change. Approximately 1.1m hectares of excess corn production are needed to produce the excess calories consumed by just Americans annually.
Greater organic and agroecological strategies should be prioritised over highly industrialised farming practices. These forms of farming use much less fertiliser—which is not only bad for biodiversity but also produces high emissions. In 2011, agriculture in my home state of Michigan collectively purchased about 200,000 metric tons of nitrogen fertiliser at a CO₂ cost of 1.34 million metric tons (the equivalent of that produced by 291,000 US cars in a year). Meanwhile, organic bread wheat production in the UK appears to use less energy per ton than conventional production, with very little of it accrued from nitrogen fertiliser production and use.
Large quantities of food are needed for any city region—an American city region of a million people will require about 900m kg of food annually. Although "food miles" are problematic as a discriminator for greenhouse gas release, shorter supply chains are probably more amenable to electric vehicle transportation than long-distance transport—and hence ultimately to renewable energy use. As such, cities should aim to source their food from the surrounding region rather than globally. Within city regions it should also be possible to use waste recycling more robustly, creating carbon cycles as well as biogeochemical cycles for plant nutrients such as phosphorus and nitrogen. Since phosphorus is essential and non-renewable while production of nitrogen fertilisers requires a great input of energy this is very useful.
Although food is lost throughout the supply chain, it's estimated the greatest losses occur at the consumer level in the global north. In addition, a large amount of produce is wasted for not meeting retail cosmetic standards. All of the energy towards production, transportation, and processing of this food is also wasted. This modern culture of waste must be addressed.
Some crops are grown in an intensely concentrated manner, which leaves them vulnerable to climate changes and pests. For example, over half of US fresh produce and nuts are grown in California, and a number of these crops will be negatively impacted this century. While there is research to develop more draught and heat tolerant varieties across a range of crops it also seems prescient to distribute production more broadly. Variations in weather patterns can make this a challenge. But structures such as poly tunnels can markedly expand the season – to 12 months for lettuce and an additional two-to-three months for tomatoes. And a number of crops, for example apples, can be stored fresh for several months with controlled atmosphere storage.
Making negative effects (or costs) of production (such as soil loss) transparent so that all costs are accounted for and then rewarding farmers for things such as soil carbon sequestration, minimised external inputs, and low energy use instead of just total production would greatly help reduce these impacts.
The idea of farming insects and jellyfish are just some examples of the innovative suggestions that have been made for diversifying protein sources beyond meat and, say, soya. This would allow for reduced levels of animal protein in the global north and increased levels in much of the global south.
Very little of the global north's enormous farm policy budgets tend to be spent on policies such as conservation, agroecological research, and organic production. Policies that stimulate new farmer development, regional market and supply chain development (such as food hubs), prioritise appropriate technology development at smaller scales and price points (including robotics), sustainable energy production and research to minimise external inputs while maintaining high productivity are needed in order to help propel their development.
All in all, much more attention needs to be paid on the sustainability of the planet's urban food systems. If the situation continues unchanged, our food supply chains will soon be in deep trouble.
This article is republished from The Conversation under a Creative Commons license. Read the original article.
Source: Phys.org
Powered by NewsAPI.org
Keywords:
2007–08 world food price crisis • Food security • Intensive farming • Fertilizer • Midwestern United States • Nutrient • Surface runoff • Riparian zone • Stream • Water quality • Connecticut • Dead zone (ecology) • Gulf of Mexico • Chocolate • West Africa • Earth • Nutrition • Carbon dioxide • Protein • Malnutrition • Food security • Supply chain • The Future of Food • Food systems • Environmentalism • Health • Quality of life • Consumption (economics) • North–South divide • World population • Urbanization • North–South divide • Resource • North–South divide • Calendar year • Food • Atmosphere of Earth • Carbon dioxide • Biodiversity • Ecosystem • Food industry • Agriculture • Water use • Agriculture • Local food • North–South divide • Market (economics) • Food • Season • Diet (nutrition) • Land • Fruit • Vegetable • Protein • Calorie • Meat • Consumption (economics) • Obesity • Land • Meat • Consumption (economics) • Globalization • Diet (nutrition) • Greenhouse gas • Meat • Greenhouse gas • Diet (nutrition) • Maize • Manufacturing • Calorie • Organic farming • Agroecology • Industrialisation • Agriculture • Agriculture • Fertilizer • Biodiversity • Air pollution • Agriculture • Michigan • Tonne • Fertilizer • Carbon dioxide • Tonne • Carbon dioxide equivalent • United States dollar • Car • Organic farming • Common wheat • Manufacturing • Energy • Ton • Intensive farming • Manufacturing • Fertilizer • Manufacturing • Food • Food miles • Greenhouse gas • Supply chain • Electric vehicle • Transport • Transport • Renewable energy commercialization • Recycling • Carbon • Biogeochemical cycle • Plant nutrition • Phosphorus • Nitrogen • Phosphorus • Essential amino acid • Non-renewable resource • Manufacturing • Nitrogen • Fertilizer • Factors of production • Energy • Food • Supply chain • Consumer • North–South divide • Production (economics) • Retail • Cosmetics • Standards organization • Energy • Manufacturing • Transport • Food processing • Food • Waste • Crop • Climate • Pest (organism) • California • Crop • Working animal • Weather • Season • Lettuce • Tomato • Crop • Apple • Controlled atmosphere • Manufacturing • Erosion • Soil carbon • Carbon sequestration • Efficient energy use • Manufacturing • Agriculture • Jellyfish • Protein • Beyond Meat • Soybean • Protein • North–South divide • North–South divide • North–South divide • Farm • Policy • Policy • Conservation biology • Agroecology • Research • Organic farming • Policy • Farmer • Economic development • Regional planning • Market (economics) • Supply chain • Food hubs • Appropriate technology • Research and development • Robotics • Sustainable energy • Energy development • Research • Factors of production • Productivity • Urban planning • Sustainability • Urban planning • Food systems • Creative Commons license •