Abstract
How much and what we eat and where it is produced can create huge differences in GHG emissions. On the basis of detailed household-expenditure data, we evaluate the unequal distribution of dietary emissions from 140 food products in 139 countries or areas and further model changes in emissions of global diet shifts. Within countries, consumer groups with higher expenditures generally cause more dietary emissions due to higher red meat and dairy intake. Such inequality is more pronounced in low-income countries. The present global annual dietary emissions would fall by 17% with the worldwide adoption of the EAT-Lancet planetary health diet, primarily attributed to shifts from red meat to legumes and nuts as principal protein sources. More than half (56.9%) of the global population, which is presently overconsuming, would save 32.4% of global emissions through diet shifts, offsetting the 15.4% increase in global emissions from presently underconsuming populations moving towards healthier diets.
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Main
Food choices impact both our health and the environment1,2. The food system is responsible for about one-third of global anthropogenic GHG emissions3,4 and climate goals become unattainable without efforts to reduce food-related emissions5,6. However, not everyone contributes the same way to food-related emissions because of disparities in lifestyle, food preferences and affordability within and across countries7,8,9. High levels of food consumption (especially animal-based diets), one of the leading causes of obesity and non-communicable diseases10,11, lead to substantial emissions9,12. Simultaneously, >800 million people still suffer from hunger and almost 3.1 billion people cannot afford a healthy diet13. Ending hunger and malnutrition while feeding the growing population by extending food production will further exacerbate climate change14,15. Given the notable increase in emissions driven by food consumption despite efficiency gains16, changing consumer lifestyles and choices are needed to mitigate climate change17.
Research shows that widespread shifts towards healthier diets, aligned with the sustainable development goals (SDGs) of the United Nations18, offer solutions to this complex problem by eradicating hunger (SDG 2), ensuring health (SDG 3) and mitigating emissions (SDG 13)19,20,21,22. Numerous dietary options have been proposed as guidelines for diet shifts1,23,24. The planetary health diet12, proposed by the EAT-Lancet Commission, stands out as a prominent option. It aims to improve health while limiting the impacts of the food system within planetary boundaries by providing reference intake levels for different food categories9,25. It is flexibly compatible with diversities and preferences of regional and local diets12. Previous research has estimated changes in country-specific environmental impacts, including GHG emissions26,27,28 and water consumption25, resulting from adopting the planetary health diet. However, there is limited evidence on how different population groups will contribute differently in this process7.
Food consumption and associated emissions differ as a result of disparities in consumer choices guided by social and cultural preferences, wealth and income29. Quantifying food-related emissions along the entire supply chain for different products and population groups provides information for emission mitigation through changing consumer choices17. With the improved availability of household consumption data, recent studies have revealed inequality in energy consumption30,31 and carbon emissions17,32,33,34. Although there are several studies on income- or expenditure-specific food-related emissions within individual countries based on survey-based data35,36,37,38, previous studies have not assessed global food-related emissions with a detailed breakdown into specific products and population groups. Furthermore, reducing the overconsumption of wealthy or otherwise overconsuming groups can increase the availability of resources for reducing hunger and malnutrition7. However, it remains unclear how emissions from different population groups would change in response to global diet shifts.
To fill these gaps, this study evaluates GHG emissions (CO2, CH4 and N2O) throughout the global food supply chains (including agricultural land use and land-use change, agricultural production and beyond-farm processes)16 induced by diets, termed ‘dietary emissions’, in 2019 and the potential emission changes of global diet shifts. Food loss and waste during household consumption25,39,40 have been subtracted from the national food supply to obtain dietary intake. We quantify dietary emissions of 140 products16 (classified into 13 food categories12) on the basis of the global consumption-based emissions inventory of detailed food products16. By linking detailed food intake amounts to the food consumption patterns of 201 global expenditure groups (grouped according to the per capita total expenditure of each group) from the household-expenditure dataset41 based on the World Bank Global Consumption Database (WBGCD)42, we analyse the unequal distribution of dietary emissions in 139 countries or areas, covering 95% of the global population. Despite limitations, the total expenditure of consumers, which effectively reflects patterns in household income, consumption and asset accumulation, is a useful approximation to represent levels of income and wealth31,43. Additionally, we build a scenario of shifting from diets in 2019 to the global planetary health diet to estimate emission changes (Methods). This study investigates differences in dietary emissions among regions, countries and population groups, identifying areas where efforts are needed to mitigate emissions during the global transition towards a healthier and more planet-friendly diet.
Present dietary emissions across countries
In this study, dietary emissions account for emissions along the entire global food production supply chains, which are allocated to final consumers of diets. We use the term ‘GHG footprints’ to specifically refer to the dietary emissions of an individual over 1 year17,34. The total dietary emissions and country-average per capita GHG footprints show different distributions across countries in 2019 (Fig. 1a; for detailed food categories see Supplementary Figs. 1–9). The present total global dietary emissions reach 11.4 GtCO2e (95% confidence interval 8.2–14.7 Gt) (details of uncertainty ranges in Supplementary Tables 1 and 2). China (contributing 13.5% of emissions) and India (8.9%), the world’s most populous countries (Supplementary Table 3), are the largest contributors to global dietary emissions. Alongside Indonesia, Brazil, the United States, the Democratic Republic of Congo, Pakistan, Russia, Japan and Mexico, the top ten contributors represent 57.3% of global dietary emissions but with very unequal per capita emissions within and between countries. We find the highest country-average per capita footprints in Bolivia, with 6.1 tCO2e, followed by Luxembourg, Slovakia, Mongolia, the Netherlands and Namibia, with >5.0 tCO2e (Supplementary Discussion 2.1). Haiti (0.36 tCO2e) and Yemen (0.38 tCO2e) have the lowest country-average footprints, followed by Burundi, Ghana and Togo. Insufficient food intake of residents due to limited food affordability44,45 is the root cause of low footprints in these low- and lower-middle-income countries46.
While animal-based (52%) and plant-based (48%) products contribute nearly equally to global dietary emissions4,16, the latter accounts for 87% of calories in global diets (Supplementary Table 4). The three main sources of emissions, namely red meat (beef, lamb and pork) (5% of calories), grains (51%) and dairy products (5%), contribute to 29%, 21% and 19% of global emissions, respectively. The substantial emissions from red meat and dairy products are attributed to their considerably higher emissions per unit of calories compared to other categories (Supplementary Table 4).
To highlight emission differences at a regional level, we further group the country-level results into 18 regions according to geographical locations and development levels (Fig. 1b and Supplementary Fig. 10). In most regions, animal-based products contribute fewer calories (less than a quarter) (Supplementary Data 21) but yield more emissions than plant-based products, especially in Australia (84% from animal-based products), the United States (71%) and the region Rest of East Asia (71%) where residents excessively consume both red meat and dairy products. However, the consumption of plant-based products in Indonesia (83% of total calories), Rest of Southeast Asia (92%) and Sub-Saharan Africa (77%) accounts for the most emissions, at 92%, 73% and 64%, respectively. Southeast Asia including Indonesia has a high-emission proportion from grains (42%) due to the prevalent meals dominated by rice. The typical food basket in Sub-Saharan Africa is broadly made up of grains, tubers, legumes and nuts25,47, representing over half of the regional emissions.
Unequal distribution of dietary emissions within countries
We find substantial differences in per capita GHG footprints within countries and regions. To clearly present the distribution of footprints within each country and region, individuals are sorted in ascending order of their total expenditure levels and then sequentially allocated to ten expenditure deciles with equal population size (Supplementary Fig. 11 and Fig. 2a). As expenditures increase, individuals tend to have higher levels of footprints, with the largest increase attributed to red meat and dairy products. Richer populations usually have higher per capita footprints related to animal-based products than the poorer in most regions (Fig. 2b). However, there are differences in per capita footprints within expenditure deciles. For example, even in high-income countries such as Australia and Japan, the dietary intake of red meat for some people in the poorest deciles falls below the recommended levels (Supplementary Data 15). Rest of East Asia is one exception, with the poorest decile having high footprints due to a substantial intake of red meat, as seen in Mongolia where beef and mutton are the most common dish48.
Footprints related to plant-based products in specific regions show a different trend from animal-based products as expenditures increase. The middle expenditure groups are responsible for the highest footprints associated with grains in Sub-Saharan Africa and Southeast Asia and the highest footprints of tubers, vegetables and fruits (mainly starchy tropical fruits49) in the Rest of Oceania. These locally produced, high-carbohydrate products are traditional staple foods. In poor countries, agricultural policy primarily targets improving the productivity of staple food, with little investment in the market and facilities for nutrient-rich products50,51. Consequently, the need for dietary diversity for middle- and low-income people is not adequately addressed50, leading to increased consumption of these lower-cost products. However, wealthier consumers can afford more expensive products, such as red meat, reducing their reliance on these staple products.
We use the GHG footprint Gini (GF-Gini) coefficient, calculated on the basis of data from 201 expenditure groups, to measure the dietary emission inequality within a country (Fig. 3), with 0 indicating perfect equality and 1 indicating perfect inequality. The inequality of dietary emissions tends to decline with the increase of the per capita GDP of a country, especially for animal-based products. We find the highest inequality of dietary emissions of food products generally in low-income countries, most of which are located in Sub-Saharan Africa. In Sub-Saharan Africa, the highest spending 10% of the population contributes 40% of the regional emissions from red meat, 39% from poultry and 35% from dairy products. In contrast, high-income countries generally have relatively low inequality with high levels of emissions despite country-to-country variations. The GF-Gini coefficients for all types of products of most Western European countries are <0.20 (Supplementary Tables 9 and 10), which is lower than for other high-income countries such as the United States, Australia, Canada and Japan.
Dietary emission shares across consumer groups
There are notable differences in dietary emission shares associated with food categories across expenditure deciles between regions (Fig. 4). In high-income countries, expenditure groups have relatively similar patterns of dietary emissions, with large shares of red meat and dairy products contributing the largest amount of emissions. Even poor consumer groups in high-income countries tend to be more likely to be able to afford animal-based products as a result of relatively lower prices for dairy products, eggs, white meat and processed red meat. This contrasts with the high prices of animal-based products due to supply constraints in most low- and lower-middle-income countries52,53. Except in high-income countries, starchy staple foods (including grains and tubers), with low prices but high-carbohydrate content44,54, constitute a large proportion of dietary emissions because of the high level of consumption, especially in Southeast Asia and Sub-Saharan Africa. As individuals’ expenditures increase in these countries, emission shares from starchy staple foods in total emissions decrease substantially. These changes demonstrate that as the affordability of food increases, populations tend to adopt instead more diverse diets composed of fewer starchy staple foods and more meat, dairy products, vegetables and fruits. This trend generally aligns with Bennett’s Law25,55,56. For example, research shows that with rapid economic growth, China’s urban or high-income groups increase their intake of non-starchy foods to fulfil their requirements of dietary diversity35, while poorer groups, often engaging in strenuous physical jobs, predominantly consume inexpensive starchy staple foods. One exception is Rest of Oceania, where poorer groups have higher percentages of emissions from not only tubers but also vegetables and fruits. Owing to relatively low expenditure on food, poor populations in this island region usually choose locally cultivated tubers and fruits (such as cassava, taro and bananas)57,58 with high intensities of land-use emissions59.
Emission changes from adopting the planetary health diet
To estimate the emission changes from a global diet shift, we build a hypothetical scenario by assuming that everyone in all countries adopts the planetary health diet (Methods). Results indicate that the global dietary emissions would decrease by 17% (1.94 (1.51–2.39) GtCO2e) compared with the 2019 level (details of the uncertainty ranges can be found in Supplementary Tables 11 and 12). The presently overconsuming groups (56.9% of the global population) would save 32.4% of global emissions through diet shifts, more than offsetting the 15.4% increase in global emissions from the presently underconsuming groups (43.1% of the global population) as a result of adopting healthier diets (Supplementary Table 13). National dietary emissions in 100 countries would decline by 2.88 GtCO2e, whereas the other 39 countries (mainly low- and lower-middle-income countries46 in Sub-Saharan Africa and South Asia) would have an increase in emissions by 938 MtCO2e (Fig. 5a; for detailed food categories see Supplementary Figs. 12–20).
Countries would be affected differently regarding emission changes by adopting the planetary health diet, reflected in the percentage change in national emissions (Fig. 5a). Uzbekistan (−74%), Australia (−70%), Qatar (−67%), Turkey (−65%) and Tajikistan (−64%) would see the largest percentage decrease. In comparison, most of the countries with an estimated considerable percentage increase are located in Sub-Saharan Africa and the Middle East, with the largest percentage increase from Iraq (+155%). Notably, with the increase in per capita GDP, the percentage change in overall dietary emissions of countries shows a shift from a positive to a negative trend, primarily led by changes in animal-based emissions (Supplementary Fig. 21).
Global emission reduction would be dominantly driven by red meat and grains (Fig. 5b). The reduction in meat, eggs and fish would lead to 2.04 GtCO2e of emission reduction, of which 94% is driven by the decrease in red meat. China (22%), the United States (15%) and Brazil (14%) would be the largest contributors to emission reduction associated with a decrease in red meat consumption. A decline in grains would result in 914 MtCO2e of emission reduction, of which 56% would happen in Asia. A further 240 and 89 MtCO2e reduction in emissions would come from reduced sugars and tubers, respectively. However, increased proteins (legumes and nuts and dairy products), added fats and vegetables and fruits would partly offset the above-reduced emissions by 41%. Intake of legumes and nuts would increase in all regions, leading to a further 757 MtCO2e of emissions, whereas most of the emission increase related to added fats (largely vegetable oils) (279 Mt) and dairy products (143 Mt) would take place in Sub-Saharan Africa, China and other Asian countries. Global dietary emissions associated with vegetables and fruits would increase by 163 Mt, despite declines in China and Rest of Oceania.
The decline in per capita GHG footprints would be achieved primarily in wealthy consumer groups in high- and upper-middle-income countries, while increased footprints would occur mainly in poor groups in most countries (Fig. 6a). Results show that the shifts of chief protein sources from animal-based to plant-based proteins according to the planetary health diet12 would contribute the most to changes in footprints globally (Fig. 6b). For example, in Australia, Brazil, Canada and the United States where diets are dominated by red meat and dairy products, the top and upper-middle expenditure groups would have notable reductions in footprints. However, most populations in South and Southeast Asia and Sub-Saharan Africa would have a considerable increase in footprints because of the present low levels of red meat intake. Meanwhile, the present intake of plant-based proteins in all countries is below the recommended level25. Footprints related to legumes and nuts would increase for most expenditure groups in all regions to meet nutrient demands. This increase is particularly substantial in Rest of Oceania, Brazil, Indonesia and Sub-Saharan Africa, where most of the consumed legumes and nuts are domestically produced with high land-use emission intensities59,60, assuming the present production and trade patterns remain unchanged.
Discussion and conclusions
This study uncovers the extent of inequality of dietary emissions within countries based on detailed expenditure data17,34 and underlines the dependence of dietary emissions on expenditure and income levels. Emissions aggregated at expenditure deciles may lose some fine-grained information from the 201 expenditure groups. For example, people from the lowest expenditure groups in affluent countries may experience malnutrition or even hunger, which is not adequately captured at a decile level. Nevertheless, the GF-Gini coefficient calculated from 201 groups provides an accurate reflection of emission inequality. Results show that affluent countries consume high-emission diets but show relatively lower levels of inequality, whereas many poor countries tend to have diets with lower emissions but higher levels of inequality.
The objective of the diet shift scenario is to assess the potential implications of emission mitigation of the food system resulting from changing consumer choices. Widespread diet shifts offer dual benefits by moving 43.1% of the global population out of underconsumption and mitigating 17% of global dietary emissions. The simulated changes in the volume of global emissions under the planetary health diet approximate the findings by ref. 26 (Supplementary Discussion 1). However, worldwide diet shifts require tailored policies targeted at regions, countries, expenditure groups and products instead of ‘one-size-fits-all’ policies.
We find that, compared to plant-based products, animal-based products, particularly red meat and dairy products, exhibit greater potential for reducing both emission volumes and emission disparities among different expenditure groups. Priorities lie in reducing the overconsumption of specific emission-intensive products in affluent countries (particularly the high-expenditure groups), such as beef in Australia and the United States, to achieve health9,12 and climate benefits25,26,28. Incentives, such as implementing subsidies or taxation on environmental externalities through food or carbon pricing61, ecolabelling62 and expanding the availability of less emission-intensive products (for instance, menu design for diverse vegetarian foods63), can encourage consumers to make dietary changes. Moreover, a well-designed (primarily urban) food environment can reshape residents’ dietary patterns35 and the parallel development of urban planning and infrastructure can alleviate the time and financial burdens of shifts to healthier diets64. However, in countries such as Mongolia, where diets heavily rely on red meat and dairy products because of their traditional nomadic lifestyle and limited accessibility of diverse foods, especially in rural areas48, diet shifts may not be feasible but there is a need to improve national nutritional education48.
Low-income countries face more severe challenges in reaching healthier diets. On the one hand, diet shifts require increased food consumption in these countries. For example, in Sub-Saharan Africa, the planetary health diet requires a 3.4-fold increase in dairy consumption for the entire population and a 69-fold increase for the poorest decile (Supplementary Fig. 22). However, Sub-Saharan Africa and South and Southeast Asia, which have experienced stagnating agriculture production efficiency for decades8, cannot produce domestically nor afford to import the food required for diet shifts65. It is crucial to enhance the production efficiency of feed and food crops through various measures such as crop and soil management techniques8,66 and the introduction of high-yielding crop varieties and hybrids67,68. Moreover, increasing the proportions of nutrient-rich products in food imports65 and reducing restrictive trade policies which tend to raise food prices25,69 help to address this challenge. On the other hand, poor populations often opt for lower-cost, calorie-dense but less nutritionally beneficial foods. High cost and low affordability remain the largest barriers for these individuals to select healthier diets44,54,70,71. Others44 found that >1.58 billion low-income populations worldwide cannot afford the cost of the planetary health diet. Therefore, policy efforts (for instance, pricing interventions72, technical assistance to reduce food production costs73 and so on) should focus on making food more affordable and accessible, especially for lower expenditure groups37,74. However, studies indicate that lower food prices may decrease the income of agricultural households75,76, widen wealth gaps between individuals employed in food- and non-food sectors, especially in low-income agrarian countries and exacerbate rural poverty1,77. In this sense, policies aimed at promoting diet shifts should be deliberately and cautiously designed with vulnerable groups in mind to reduce inequality37,61.
Lastly, altered food demand due to diet shifts can induce notable structural adjustments within the global agri-food system. Although this study does not assess the feasibility of countries supplying sufficient food if the planetary health diet was adopted, results indicate that the composition of global food production would change considerably to adapt to the substantial changes in demand8,25,77. The diet shifts would necessitate the global supply (in calorie content) of red meat decrease by 81%, all sugars by 72%, tubers by 76% and grains by 50%, while that of legumes and nuts increase by 438%, added fats by 62% and vegetables and fruits by 28% (Supplementary Data 16). Research77,78 confirms that changed food demand could cause fluctuating prices of agricultural products and land in global markets, triggering spillover effects between different food categories or to other non-food sectors (for example, stimulating biofuel production) and partly offsetting the benefits of diet shifts. Therefore, policy-making should focus on alleviating these effects. Incentives such as increased subsidies or tax breaks can generate new economic opportunities and motivations for industries that need to scale up production to meet the heightened demand for products (for example, plant-based proteins). By contrast, for emission-intensive food industries that need to downsize, measures such as gradual crop substitution25,79 could be adopted to optimize production and reduce the costs of production transformations while safeguarding the interests of producers.
Methods
Overview
In this study, we first assess the GHG emissions from diets comprising 140 products16 (Supplementary Table 14) in 139 countries or areas (we collectively use the term ‘country’ because most of them are individual countries) (Supplementary Data 1) in 2019 based on the global consumption-based emission inventory of detailed food products from ref. 16. The inventory16 provides data (in mass units) of GHG emissions (including CO2, CH4 and N2O) generated during supply chain processes, including agricultural land use and land-use change (LULUC), agricultural activities and beyond-farm processes (excluding emissions from household and end of life)4. All emissions are allocated to final consumers of food products. The year 2019 (the latest year before the COVID-19 pandemic) is selected as a baseline year, which can reflect the level of present dietary intake without the interference of the pandemic80,81. Subsequently, dietary emissions from different expenditure groups are quantified by matching diets with the household-expenditure dataset42 to reflect the differences and potential inequality of dietary emissions. Finally, to measure the magnitude of the emission impact of the global diet shift, we model the transition from diets in 2019 to the widespread adoption of the planetary health diet. The research framework of this study is shown in Supplementary Fig. 23.
The following data sources are mainly used in this study. The consumption-based food emissions inventory16 is based on data derived from the FAOSTAT82, comprising national emission accounts of supply chain processes and data on food trade and production. Data on food loss and waste throughout the global supply chain and at the household level as well as food supply data, all used for linking emissions with diets, are obtained from FAOSTAT83 and previous research25,39. The household-expenditure data41 are built on the basis of the WBGCD42 and further refined and supplemented by consumer expenditure surveys from high-income countries17,41 to bridge the dietary emissions with different expenditure groups. Detailed data sources used for calculation are provided in Supplementary Table 15. Data processing, assumptions and uncertainties for all calculations are also given.
Dietary energy intake and emissions
Accounting of food consumption and supply chain emissions
The estimation of the present dietary emissions and the emission changes for adopting the EAT-Lancet planetary health diet12 is based on the accounting framework designed by ref. 16. They assess global GHG emissions induced by the consumption of food products in 181 countries based on the physical trade flow approach84,85. Consumption-based GHG emissions along global supply chains, including local production and international trade, are calculated as follows16,84:
where Ei,r refers to the consumption-based GHG emission of product i in country r. Gi/Pi represents the vector of direct emission intensity of product i from entire food supply chain processes, of which Gi denotes total emissions generated from entire supply chain process of product i, Pi is the production vector of product i. \({(I-{A}^{i})}^{-1}\) is the trade structure of product i, of which Ai is the matrix of export shares and I is the identity matrix with the same dimension as matrix Ai. DMIi refers to the vector of direct material input of product i and DMCi,r is the vector of domestic material consumption of product i in country r with values set to zero for other countries. The DMI of a country is defined as the total inputs of products and the DMC is defined as the amount of products consumed domestically. DMI equals DMC plus exports of products (or production plus imports). Fi refers to the vector of total (or consumption-based) emission intensity of product i from food supply chain processes, that is, total emissions induced by per unit of domestic consumption of product i. All variables in equation (1) are in units of mass (metric tonnes).
Feed products are excluded from diets because emissions from feed crops have been allocated to livestock products that consume feed during production16. Food loss and waste (FLW) along supply chains and households are subtracted to quantify the net intake amount of food products from the household stage.
Dietary calorie conversions
We use the annual per capita food supply (FS) quantity of 140 food products from the supply utilization accounts of FAOSTAT83 and population from the United Nations86 to calculate the total supply amount of product i in country r (FSi,r, in the unit of mass):
where \({{\rm{FS}}}_{{\rm{per}}}^{i}\) denotes the per capita supply of product i per year and pr refers to the population in country r.
To be consistently matched with the DMC, the FS values should be limited within the coverage of the DMC and values that exceed this range are removed. At the same time, to aggregate food products into food categories and compare their nutritional contents with the reference level from the planetary health diet, we convert the quantity of food consumption or supply into calorie content using product-specific nutritive factors (calories per unit weight of product)87,88 from FAO (Supplementary Table 14).
Subtracting food loss and waste at the household level
The food supply derived from FAOSTAT datasets does not exclude FLW that happens during household consumption25. FLW before dietary intake can be divided into two parts: the FLW during supply chain processes (including agricultural production, postharvest handling and storage, processing and packaging and distribution) as well as the FLW during the food preparation and supply for household consumption39,40. The food supply value provided by FAOSTAT only excludes FLW during supply chain processes. Therefore, we exclude household FLW using the method by ref. 25 to calculate the annual dietary intake for each product as follows:
where DIi,r and \({{\rm{DI}}}_{{\rm{per}}}^{i,r}\) refer to the national and per capita caloric intake amount of product i in country r each year, respectively. \({{\rm{FS}}}_{{\rm{energy}}}^{i,r}\) and \({{\rm{FS}}}_{{\rm{energy}\_per}}^{i,r}\) are the national and per capita supply quantity (in calorie content) of product i annually, respectively. Parameter \({f}_{{\rm{FLW}}}^{\;i,r}\) is the FLW factor in the household consumption stage39 of food product i in country r. Others39 provide regional FLW factors, expressed as the weight percentage of food that is lost or wasted at different stages of food production and consumption, for different food categories. As a result, household food waste is subtracted from the FS to obtain the dietary intake amount of each product. Detailed household FLW factors are shown in Supplementary Table 16.
Quantifying dietary GHG emissions
Our equation (1) can be transformed into the following equation to calculate the total emission intensity of food calorie consumption:
where \({F}_{{\rm{energy}}}^{\,i,r}\) represents total emissions per unit of calorie content of product i in country r, \({{\rm{DMC}}}_{{\rm{energy}}}^{i,r}\) refers to total calorie content of product i consumed domestically in country r. Then, emissions from the dietary intake (without FLW) of product i in country r (\({E}_{{\rm{intake}}}^{\,i,r}\)) are calculated as follows:
Classification of food categories
The EAT-Lancet Commission report provides coverage of different food categories in the planetary health diet and their recommended caloric intake levels at 2,500 kcal for adults each day12 (Supplementary Table 17). In this study, we classify 140 products into 13 aggregated food categories according to the planetary health diet12, including grains, tubers or starchy vegetables, vegetables, fruits, dairy products, red meat (beef, lamb and pork), chicken and other poultry, eggs, fish, legumes, nuts, added fats (both unsaturated and saturated oils) and all sugars. On the basis of the data availability of the FAOSTAT4,82, the food products in this study include both primary and processed products (primary and secondary food processing) which can be classified into specific food categories16. Ultraprocessed products that combine ingredients from several food categories, such as ice creams made from both dairy and sugar, are not considered. Detailed coverages of each food category and their mapping relationship with specific products are shown in Supplementary Table 18.
Matching diets with the household-expenditure dataset
We explore the dietary emissions from consumers with different expenditure levels (defined as expenditure groups) using the household-expenditure dataset41 for the year 2011. The dataset, containing 116 countries and almost 90% of the global population (Supplementary Table 19), is primarily based on the household survey microdata from the WBGCD42, supplemented by consumer expenditure surveys of national statistical offices from high-income countries such as the United States and European countries17,41. For every country in the dataset, 201 expenditure groups (grouped according to the per capita total expenditure of each group) and the corresponding population share are listed. The annual per capita expenditure of people in different expenditure groups ranges from <US$50 to ~US$1 million per year (expressed in 2011 Purchasing Power Parities, PPP)31,34. For each expenditure group, the expenditure for 33 different sectors of goods and services (including 11 food items) and the corresponding expenditure share in national consumption of each sector are provided31,34,41. For some affluent (or poor) countries that do not have a sufficient representative number of people at the bottom (or top) end of the expenditure spectrum, the population in the corresponding expenditure groups is empty. Expenditure shares of 11 food items are matched with the 140 products in this study (Supplementary Table 20). We calculate the dietary intake of different food products for each expenditure group in each country by multiplying the food expenditure share of groups with the total dietary intake amounts of food products of each country.
This study assumes that the amount of food consumption is proportionate to food expenditures and the purchasing price for the same product is unchanged across 201 groups ignoring higher prices for high-quality or luxury food items within the same food category. Although the assumption of an unchanged purchasing price is an unsolved limitation shared by similar studies using monetary expenditure data31,34,41, household expenditures on food can still effectively highlight the differences in food consumption and emissions across consumer groups with different affordability of, and spending on, food. We also assume that the proportion of food sources from local production and trade for the same food category remains constant across the 201 groups. In other words, the magnitude of dietary emissions is solely determined by the size and pattern of food expenditure of each group and the associated supply chains for each food consumption item.
For countries that are major food consumers (and emitters) but without data in WBGCD, expenditure shares from countries with similar development levels and eating habits and neighbouring geographical locations are used to calculate the distribution of their food expenditure. We finally select 201 expenditure groups in 139 countries/areas, covering 95% of the global population in 2019 (Supplementary Table 3 and Supplementary Data 3). Details for dealing with missing data are provided in Supplementary Table 7. Countries or areas are then classified into 18 regions for comparison according to geographical locations (Supplementary Table 8). The WBGCD expenditure data from the year 2011 are adjusted to PPP in 2019 to represent the expenditure level of populations in figures. Results of emissions from 13 types of food categories of 201 expenditure groups at the national and regional levels are shown in Supplementary Data 8, 10 and 11.
Analysis of GF-Gini coefficients
Calculation of GF-Gini coefficients
This study uses the GF-Gini coefficient33,89, which is based on the well-known Gini coefficient90, to measure the inequality of GHG footprints from 201 expenditure groups within countries, regions and globally. The GF-Gini coefficient ranges from 0 to 1, indicating the emission distribution across expenditure groups changes from perfect equality to perfect inequality. The GF-Gini coefficient of each food category is calculated as33:
where Ginij indicate the GF-Gini coefficient of food category j (including product i, i = 1, 2, 3, …, n). Expenditure groups and their population are reordered in ascending order of per capita GHG footprint of food category j and m refers to the reordered number of groups (m = 1, 2, 3, …, 201). \({D}_{m}^{j}\) and \({Y}_{m}^{j}\) represent the proportions of population and GHG footprints (of food category j) for each expenditure group, respectively. \({T}_{m}^{j}\) is the cumulative proportion of GHG footprints of each expenditure group. The results of national, regional and global GF-Gini coefficients are shown in Supplementary Tables 9 and 10.
Regression analysis
We use the regression approach to examine the relationship between the national GF-Gini coefficients and the per capita GDP91,92 of 139 countries/areas. The GF-Gini coefficient of each country is regarded as the dependent variable (y) and the national per capita GDP acts as the independent variable (x). Initially, locally weighted regression is applied to illustrate the trend lines within the scatterplot. Subsequently, we test different regression methods for validation based on the general trend. Ultimately, we found that logarithmic regression is the most fitting for dietary emissions of most food categories, particularly in the case of animal-based products. Thus, the logarithmic regression is applied.
Scenario of the planetary health diet
Scenario setting and assumptions
To estimate the emission changes resulting from the transition from the 2019 diet to the global planetary health diet, we build a hypothetical scenario by assuming that individuals belonging to 201 different expenditure groups in all countries will all reach the reference intake level of 13 types of food categories12. First, we assume that the proportion of food sources from local production and trade in each country is unchanged, that is, emission changes from dietary shifts would be calculated on the basis of emissions from local production and imports accounting for emissions along global food supply chains, similar to studies by refs. 25,26. At the same time, emission changes induced by decreased food consumption in countries following the planetary health diet, such as carbon uptake from agriculture abandonment59 or emission increase from non-food biomass production in saved agricultural land77, are not considered in this study. Second, we assume that agricultural and food-related production technology, trade patterns and emission intensities of food supply chain processes remain unchanged during the diet transition. Third, fluctuations in food prices induced by altered food demand or the affordability of the planetary health diet for different consumer groups are not considered in this study.
Diet gaps for different food categories
The diet gap (DG) reflects gaps between present dietary intake and the planetary health diet12,25, as follows:
where \({{\rm{DG}}}_{{\rm{per}}}^{j,r}\) is defined as the percentage ratio of the present per capita caloric intake of food category j in country r each year (\({{\rm{DI}}}_{{\rm{per}}}^{\,j,r}\)) to the annual reference level (\({{\rm{DI}}}_{{\rm{EAT}}\_{\rm{per}}}^{i}\)). \({{\rm{DI}}}_{{\rm{EAT}\_day\_per}}^{\,j}\) is the recommended per capita caloric intake of food category j each day12 (Supplementary Table 17). We assume a uniform annual calorie reference level for each food category across all populations in all countries. We allow flexibility in local diets by keeping the composition of each food category unchanged, requiring only that the calorie content reaches the reference level. According to the definition, present food intake is considered insufficient compared with reference levels when DG is <100%, while it is deemed excessive and should be reduced when DG is >100%. Daily per capita caloric intake of food categories from 201 expenditure groups of countries or regions are shown in Supplementary Data 12 and 13. We calculate the DG for food categories of 201 expenditure groups at national and regional levels (Supplementary Data 14 and 15).
Emission changes from adopting the planetary health diet
According to equation (1), the total emissions per unit of calorie content of food category j in country r (\({F}_{{\rm{energy}}}^{\;j,r}\)) can be calculated as:
where Ej,r refers to the national emissions due to consumption of food category j in country r. Thus, emission changes for adopting the planetary health diet are calculated as follows:
where \(\Delta {E}_{{\rm{intake}}}^{\;j,r}\) represents the national emission changes of food category j in country r, \({E}_{{\rm{intake}}}^{\;j,r}\) is the national emissions from intake of food category j in country r. Changes in dietary emissions of food categories from 201 groups are shown in Supplementary Data 9. The number of people with increased/decreased emissions from 201 groups is shown in Supplementary Data 19.
Uncertainty analysis
We assess the uncertainty range of dietary emissions from different food products using a Monte Carlo approach, which simulates the uncertainties caused by activity data, emission factors and parameters in each emission process16,59,93. More details can be found in Supplementary Methods 1.
Limitations
This study has the following limitations regarding data analysis and scenario setting.
In terms of data analysis, this study is limited by the data availability. First, we use regional household food loss and waste factors of aggregated food categories without more detailed product division at the national level because of a lack of data. There might also be differences between calculated and actual food intake amounts that are unable to be removed, such as animal bones or fruit skins25. Second, we use the consumer household-expenditure dataset based on WBGCD for the year 2011, which provides the most precise and detailed differentiation of consumer groups and their consumption patterns within countries so far. We assume that the shares in food expenditure and population for each expenditure group are the same as in 2011. Third, we assume that the composition of different products aggregated in one category consumed by expenditure groups is the same as the national consumption composition and there is no difference in the price of food products purchased by people from different expenditure groups. In addition, data for some populous high- or upper-middle-income countries are missing from the household-expenditure dataset. However, the countries are the world’s major food consumers and emitters, their emission changes due to diet shifts are important for the global food system. We use the expenditure shares of similar countries in the household-expenditure dataset to allocate the distributions of food expenditure in these countries.
In terms of scenario setting, we focus on the impact induced by changes in consumer choices without changing the proportion of food supply sources (domestic production and imports). We do not consider altering the proportions of supply sources and associated emissions in this study. However, future studies may explore the impacts of the production side and supply chains for diet shifts. Moreover, as we focus on the present emission inequality and mitigation potentials within the food system, we assume that the income and expenditure levels of expenditure groups remain unchanged. However, a shift in food supply may affect household income and subsequently alter the household food budgets, especially for populations employed in, or countries reliant on, food-related sectors. Additionally, as a result of data and model limitations, this study does not consider price fluctuations induced by food demand and subsequent changes in household affordability or spillover effects (between food categories or to non-food sectors). Future studies may combine assessment models incorporating elasticities to project the long-term feasibilities and consequences of diet shifts.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
Data for LULUC, agricultural and beyond-farm emissions and data for physical food consumption are curated by the FAO and can be freely obtained from FAOSTAT82, available from ref. 16. Data of food loss and waste rate are retrieved from FAOSTAT82 and ref. 25. The global household-expenditure data are obtained from the World Bank42 and refs. 17,41. Population data used in this study are obtained from World Population Prospects of the United Nations86. Data on per capita GDP in countries can be collected from the World Bank91 and the International Monetary Fund92. Supplementary datasets are also available on Zenodo (https://doi.org/10.5281/zenodo.11934909)94. Source data are provided with this paper.
Code availability
Data collection is performed in MATLAB and Microsoft Excel. Code developed for data processing in MATLAB and R in this study is available from Zenodo (https://doi.org/10.5281/zenodo.11880402)95.
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Acknowledgements
This study was supported by the National Natural Science Foundation of China (grant nos 72243004, 32101315, 71904098). Y.S. and S.S. acknowledge support from the National Natural Science Foundation of China (grant no. 72243004). Yu Li acknowledges support from the National Natural Science Foundation of China (grant no. 32101315). P.H. acknowledges support from the National Natural Science Foundation of China under a Young Scholar Programme Grant (grant no. 71904098). Yanxian Li and Y.H. acknowledge the funding support by the China Scholarship Council PhD programme. We thank Y. Zhou for supporting visualization and J. Yan for assisting in writing and revising. For the purpose of open access, a CC BY public copyright license is applied to any author accepted manuscript arising from this submission.
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Yanxian Li, Y.S. and K.H. designed the research. Yanxian Li performed the analysis with support from P.H., Yu Li, Y.H. and S.S. on analytical approaches and visualization. Yanxian Li led the writing with efforts from P.H., Y.S., F.R. and K.H. Y.S. and K.H. supervised and coordinated the overall research. All co-authors reviewed and commented on the manuscript.
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Li, Y., He, P., Shan, Y. et al. Reducing climate change impacts from the global food system through diet shifts. Nat. Clim. Chang. 14, 943–953 (2024). https://doi.org/10.1038/s41558-024-02084-1
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DOI: https://doi.org/10.1038/s41558-024-02084-1