Hostname: page-component-78c5997874-s2hrs Total loading time: 0 Render date: 2024-11-04T19:31:36.860Z Has data issue: false hasContentIssue false

Water scarcity and consumer behavior: an analysis of diet-related water footprint

Published online by Cambridge University Press:  31 October 2024

Enrica Nadia Frola
Affiliation:
Department of Environmental Science and Policy, University of Milan, Milan, Italy
Alessia Cavaliere
Affiliation:
Department of Environmental Science and Policy, University of Milan, Milan, Italy
Elisa De Marchi*
Affiliation:
Department of Environmental Science and Policy, University of Milan, Milan, Italy
Felice D'Alessandro
Affiliation:
Department of Environmental Science and Policy, University of Milan, Milan, Italy
Alessandro Benfenati
Affiliation:
Department of Environmental Science and Policy, University of Milan, Milan, Italy
Giacomo Aletti
Affiliation:
Department of Environmental Science and Policy, University of Milan, Milan, Italy
Alessandro Banterle
Affiliation:
Department of Environmental Science and Policy, University of Milan, Milan, Italy
*
Corresponding author: Elisa De Marchi; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Within the framework of an increasing water scarcity, fostered by the climate change, in this study we investigate the environmental impact associated with current food consumption by means of the Water footprint indicator focusing on the case of Italy. For the analysis of the real food consumption and its impact, we selected the Mediterranean diet as a benchmark, since previous evidence shows that Italians are shifting their dietary habits away from the traditional Mediterranean Diet in favor of dietary patterns rich in animal-based products, especially meat. To promote more sustainable food choices, we applied a Sustainable Diet Model to analyze alternative diets that can reduce the Water footprint associated with food consumption. The results of the analysis show that by adopting slight changes in the consumption of certain categories of foods, it is possible to reduce the Water footprint of diets. The findings of this research are useful for supporting policies for the promotion of sustainable food consumption that would lead to a reduction in the exploitation of a scarce resource such as water, improving the allocation of this resource and achieving the objectives of the 2030 Agenda.

Type
Research Paper
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - SA
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-ShareAlike licence (http://creativecommons.org/licenses/by-sa/4.0), which permits re-use, distribution, and reproduction in any medium, provided the same Creative Commons licence is used to distribute the re-used or adapted article and the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

Introduction

Global freshwater resources are limited, and the efficient and sustainable management of water is a critical concern for the planet's future. Agriculture depletes considerable amounts of freshwater, accounting for 70% of its use (FAO, 2017). Over 2 billion people are already living in a situation of severe water stress; population growth, urbanization, changing diets, and the need for increased agricultural production are all contributing factors that pose additional pressure on water resources (UN, 2018). Climate change is expected to intensify both extreme events linked to water, like floods and droughts, and water scarcity issues, worsening the situation at worldwide level.

Recent data point to an increasing frequency of extreme climatic events, especially droughts, in the Mediterranean region (Ali et al., Reference Ali, Cramer, Carnicer, Georgopoulou, Hilmi, Le Cozannet, Lionello, Pörtner, Roberts, Tignor, Poloczanska, Mintenbeck, Alegría, Craig, Langsdorf, Löschke, Möller, Okem and Rama2022). These events, may lead to a decline in crop yields (Semenov et al., Reference Semenov, Stratonovitch, Alghabari and Gooding2014; Senapati et al., Reference Senapati, Stratonovitch, Paul and Semenov2018).

Italy is not exempt from such events. For instance, in 2022, Italy experienced a severe drought due to insufficient winter precipitation, particularly in the Po River region (Toreti et al., Reference Toreti, Bavera, Avanzi, Cammalleri, De Felice, de Jager, Di Ciollo, Gabellani, Maetens, Magni, Manfron, Masante, Mazzeschi, McCormick, Naumann, Niemeyer, Rossi, Seguini, Spinoni and van den Berg2022). Additionally, the Italian population ranks among the top countries globally in terms of per capita water consumption and wastage of water (The European House—Ambrosetti, 2021). Furthermore, previous studies have indicated that the gradual shift away from the Mediterranean Diet (MD) toward diets rich in animal products is already leading to increased environmental impacts, including heightened water usage (Capone et al., Reference Capone, Iannetta, El Bilali, Colonna, Debs, Dernini, Maiani, Intorre, Polito, Turrini, Cardone, Lorusso and Belsanti2013).

In such context, addressing climate change and finding solutions to limit water consumption is crucial to ensure water security. Diets with low environmental impact can play a significant role in diminishing the stress on water resources.

The impacts of diets on the environment have been largely investigated in recent years, generally by means of the Carbon footprint (CF) indicator. For instance, a vast literature demonstrates that the production and consumption of food are significant contributors to greenhouse gas (GHG) emissions (Notarnicola et al., Reference Notarnicola, Tassielli, Renzulli, Castellani and Sala2017), especially concerning animal-based products. Cutting on animal-based foods consumption and substituting them with alternative foods would reduce the GHG emissions associated with diets (van de Kamp et al., Reference Van de Kamp, van Dooren, Hollander, Geurts, Brink, van Rossum, Biesbroek, de Valk, Toxopeus and Temme2018). However, environmental externalities extend beyond atmospheric pollution and include significant impacts on water consumption (Ritchie and Roser, Reference Ritchie and Roser2020). This aspect is of growing interest.

The literature supports the idea that the Water footprint (WF) of animal products is higher than the one of plant-based foods (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2012; Hoekstra, Reference Hoekstra2014). Reducing animal-based food consumption, in particular red meat, would lead to a reduction in resource use and contribute to an overall reduction of the environmental impact caused by dietary choices (Ridoutt, Hendrie and Noakes, Reference Ridoutt, Hendrie and Noakes2017). Moreover, decreasing the intake of meat products could prove beneficial in lowering the risks of cardiovascular diseases and some types of cancer (González et al., Reference González, Marquès, Nadal and Domingo2020).

Embracing sustainable eating habits can contribute to enhancing environmental sustainability while ensuring that nutritional sufficiency is maintained (Cavaliere, De Marchi and Banterle, Reference Cavaliere, De Marchi and Banterle2018). In 2015, FAO acknowledged the MD as a model of a sustainable diet. Indeed, it has been demonstrated to have a preventive effects against obesity, diabetes, and various other diseases (Katz and Meller, Reference Katz and Meller2014), while having low environmental impacts (Vanham, Hoekstra and Bidoglio, Reference Vanham, Hoekstra and Bidoglio2013). This is due to the modest consumption of animal-based foods in favor of a higher consumption of plant-based ones, such as cereals, fruits, and vegetables. There are slight variations in the MD among the Mediterranean countries. Such differences concern the type of foods consumed, which slightly change from one country to another because of cultural and religious traditions, the types of available crops, as well as climatic factors (Noah and Truswell, Reference Noah and Truswell2001).

Previous evidence suggests that in Mediterranean countries, including Italy, there is a trend of moving away from the MD model (FAO, 2015) in favor of diets that are more abundant in animal-based foods. As previous literature has shown, this transition is associated with an increased environmental impact. For instance, the study conducted by Cavaliere et al. (Reference Cavaliere, De Marchi, Frola, Benfenati, Aletti, Bacenetti and Banterle2023) examined food consumption patterns in Italy and showed that elevated consumption of animal-based products is associated with higher environmental impacts. This shift in dietary preferences is also expected to have negative impacts on water usage, given that animal products are known for being high-water intensive (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2012; Hoekstra, Reference Hoekstra2014). However, the latter aspect has been scarcely investigated.

This study has two primary objectives: (i) to expand the existing research in this field by presenting new evidence concerning diet-related WF, and (ii) to propose potential alternative dietary patterns that could help mitigate the strain on water resources, always ensuring that consumers receive adequate nutrition.

Literature background

WF indicator

The concept of ‘virtual water’ originated in the early 1990s and was first introduced by Tony Allan (Allan, Reference Allan1993, Reference Allan, Rogers and Lydon1994). It referred to the amount of water ‘virtually’ embedded in a product. However, it wasn't until the early 2000s that the WF indicator was introduced. Hoekstra and Hung (Reference Hoekstra and Hung2002) defined the WF as ‘the cumulative virtual water content of all goods and services consumed by one individual or by the individuals of one country.’ This definition, along with the calculation methodology, underwent further refinement and expansion by Hoekstra et al. (Reference Hoekstra, Chapagain, Aldaya and Mekonnen2011) and by Hoekstra (Reference Hoekstra2012).

The current WF indicator comprises three key components, as defined by Hoekstra et al. (Reference Hoekstra, Chapagain, Aldaya and Mekonnen2011):

  1. 1. Blue Water, this component represents the quantity of water consumed during the production of a good or service. The water consumed can either be evaporated or incorporated into a product and may or may not return to the catchment area (such as seas, lakes, rivers) from which it was initially obtained.

  2. 2. Green Water, encompasses the amount of water from rainfall that is either retained in the soil or temporarily remains on the surface of the soil or vegetation. Over time, a portion of this precipitation undergoes evaporation or transpiration through plants.

  3. 3. Grey Water, is associated with the contamination of freshwater caused by the production processes. More specifically, it symbolizes the quantity of water required to disperse pollutants that originate from the manufacturing of particular products throughout their entire supply chain, ensuring that the water quality adheres to established standards.

The concept of WF is less popular among consumers compared to the CF (Guenther, Saunders and Tait, Reference Guenther, Saunders and Tait2012), which has become more and more widespread thanks to the implementation of carbon labels on various food products since 2006 (Liu, Wang and Su, Reference Liu, Wang and Su2016). Consequently, there are promising opportunities for scientific research to delve deeper into and explore the role of WF of diets, which is a relatively new area of investigation (Tamea, Antonelli and Vallino, Reference Tamea, Antonelli and Vallino2021a; Vanham et al., Reference Vanham, Guenther, Ros-Baró and Bach-Faig2021).

Literature background: diet-related WF

Several studies have investigated the environmental implications of dietary choices using various approaches and indicators, such as GHGs emissions, land use, energy consumption, resource depletion, and water utilization (for instance, Rosi et al., Reference Rosi, Mena, Pellegrini, Turroni, Neviani, Ferrocino, Di Cagno, Ruini, Ciati, Angelino and Maddock2017; Bahn, EL Labban and Hwalla, Reference Bahn, EL Labban and Hwalla2019; Athare, Pradhan and Kropp, Reference Athare, Pradhan and Kropp2020; Benvenuti, De Santis and Cacchione, Reference Benvenuti, De Santis and Cacchione2021).

In a recent study by Cavaliere et al. (Reference Cavaliere, De Marchi, Frola, Benfenati, Aletti, Bacenetti and Banterle2023), the environmental impact of the Italian diet was assessed in terms of both CF and Ecological footprint. Their findings revealed that shifts in dietary patterns toward diets richer in meat products led to increased diet-related environmental impacts.

To date, only a limited number of studies have explored the environmental consequences of food consumption solely from the perspective of WF, and these studies are relatively recent (Capone et al., Reference Capone, Iannetta, El Bilali, Colonna, Debs, Dernini, Maiani, Intorre, Polito, Turrini, Cardone, Lorusso and Belsanti2013; Vanham, Hoekstra and Bidoglio, Reference Vanham, Hoekstra and Bidoglio2013; Vanham et al., Reference Vanham, Guenther, Ros-Baró and Bach-Faig2021; Tamea, Antonelli and Vallino, Reference Tamea, Antonelli and Vallino2021a). Therefore, our objective is to contribute to the existing literature in this field, aiming to address the main limitations of previous studies and expand knowledge in the field.

Capone et al. (Reference Capone, Iannetta, El Bilali, Colonna, Debs, Dernini, Maiani, Intorre, Polito, Turrini, Cardone, Lorusso and Belsanti2013) and Vanham, Hoekstra and Bidoglio (Reference Vanham, Hoekstra and Bidoglio2013) both conducted investigations into the WF associated with food consumption and dietary patterns. Specifically, Capone et al. (Reference Capone, Iannetta, El Bilali, Colonna, Debs, Dernini, Maiani, Intorre, Polito, Turrini, Cardone, Lorusso and Belsanti2013) focused their analysis on evaluating the WF of the Italian dietary pattern, utilizing consumption data from the Italian Food Consumption Survey 2005–2006. They compared the WF of the Italian diet with those of North American and Scandinavian diets. Additionally, they estimated the WF of a recommended diet proposed by the Italian Institute of Food Science at La Sapienza University in 2006, which adheres to MD guidelines. Their findings indicated that the WF of the Italian diet was 69.9% higher when compared to the MD. However, they did not provide alternative diets to improve the current situation.

Vanham, Hoekstra and Bidoglio (Reference Vanham, Hoekstra and Bidoglio2013) explored alternative dietary scenarios aimed at reducing the WF. In their study, they examined the WF of food consumption in the EU28 (the authors included EU27 + Croatia, who became a EU member on 1 July 2013) for the period from 1996 to 2005. They proposed three alternative diets: a healthy diet, a vegetarian diet, and a combination diet. Their findings revealed that the consumption of animal products, particularly red meat and milk, contributed significantly to a high WF. It is worth noting that Vanham, Hoekstra and Bidoglio (Reference Vanham, Hoekstra and Bidoglio2013) based their analysis on an average diet across all EU28 countries. However, dietary preferences and habits vary significantly from one country to another, influenced by factors such as culture, traditions, climate, and more.

In a subsequent study, Vanham et al. (Reference Vanham, Guenther, Ros-Baró and Bach-Faig2021) expanded upon their earlier research by assessing the WF in Mediterranean countries, including Algeria, Egypt, France, Greece, Italy, Morocco, Spain, Tunisia, and Turkey. They compared the WF of the real diets in these countries with the MD and with the EAT-Lancet one. Their findings revealed that, in most of the countries studied, real food consumption resulted in a higher WF compared to the MD, except for Tunisia and Algeria, where the opposite trend was observed. Finally, Tamea, Antonelli and Vallino (Reference Tamea, Antonelli and Vallino2021a) conducted a study on WF and virtual water trade associated with agricultural production in Italy. Virtual water refers to the water necessary for the production of an item and it is also known as ‘embedded water’ or ‘exogenous water’, as defined by Hoekstra in 2003. The study points out that virtual water trade implies a dependency on goods produced in other countries, resulting in vulnerability to external crises, externalized costs, and water management issues. What distinguishes this study is the use of an innovative database called CWASI, developed by Tamea et al. (Reference Tamea, Tuninetti, Soligno and Laio2021b). This database represents an improvement over the WaterStat database since it distinguishes between the WF of production and the WF of the supply side, with the latter encompassing the concept of virtual water trade, i.e., the water ‘imported’ through products. Additionally, the CWASI database is updated to the year 2016, providing more recent data compared to WaterStat, which provided average WF values only up to the year 2005.

Materials and methods

To obtain a comprehensive understanding of food consumption patterns in Italy, we examined real food consumption data spanning a 16-years period. After analyzing such trend data, we narrowed our focus to the most recent available data (year 2021) to estimate the WF associated with the real Italian diet (RID). Subsequently, we compared the WF of RID with that of the Italian Mediterranean diet (IMD). In Appendix A it is possible to see the standard portions of each food category in the IMD. Lastly, adopting the approach employed in Cavaliere et al. (Reference Cavaliere, De Marchi, Frola, Benfenati, Aletti, Bacenetti and Banterle2023), we developed three alternative dietary scenarios that could minimize WF and provide adequate nutrition to consumers. Detailed descriptions of each of these methodological steps are provided in the following subsections.

Trends in food consumption in Italy and analysis of WF

For the analysis of food consumption trends in Italy we used the data of the periodical household surveys provided by the Italian Institute of Statistics (ISTAT). We analyzed data of available years over a time span of 16-years, specifically: 2005; 2009; 2013; 2017; 2021. Data provided by the survey were representative of the Italian population, with a sample ranging between N = 45,000 and N = 50,000 (with the only exception of year 2013, when the sample was N = 20,275).

The ISTAT survey gathered information on food consumption by utilizing various questions about how often individuals consumed 14 primary food categories:

  • bread, pasta and rice;

  • potatoes;

  • fruits;

  • leaf vegetables;

  • vegetables;

  • red meat;

  • white meat;

  • fish;

  • pulses;

  • milk;

  • cheese;

  • cured meat;

  • sweets;

  • snacks.

The survey did not include data on individual consumption of beverages, olive oil, and eggs. As such, the estimated average calorie intake of RID is approximately 1600 kcal day−1, which is a bit lower compared to the recommended daily calorie intake of the IMD (around 2000 kcal day−1) For the sake of comparison, we kept the calorie intake constant at 1600 kcal day−1 in all diet scenarios.

Participants in the survey were requested to disclose their eating habits in terms of how often they consumed various foods, using a semantic scale ranging from ‘more than once a day’ (= 1) to ‘never’ (= 5). The consumption frequencies were then switched into weekly portion sizes, measured in grams that subsequently let us calculate the individual weekly diet.

After analyzing variations in food consumption of the specific food categories across the considered years, we focused on the most recent consumption data (2021) and estimated the WF of the RID. The latter was calculated by multiplying the unit water footprint (uWF, i.e., the quantity of water needed to produce a unit amount of the product) by the daily individual consumption (in grams) of that food. The same approach was adopted to calculate the WF of the IMD. The WF of the RID was then compared to the one of the IMD to evaluate differences and the factors influencing them.

The WF data—the CWASI database and the WF of fish

The first and most widely used WF database, named WaterStat, has been created by the Water Footprint Network (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2010a, Reference Mekonnen and Hoekstra2010b). The WaterStat database encompasses average uWF measurements for both the green and blue water components spanning from 1996 to 2005. These measurements are available for a variety of agrifood products, originating from both crops and animals, including both primary and processed goods. The uWF, expressed in m3 t−1 or, equivalently, in L kg−1, quantifies the volume of water needed to produce a specific quantity of products.

Tamea et al. (Reference Tamea, Tuninetti, Soligno and Laio2021b) improved this database within the CWASI—Coping with water scarcity in a globalized world—project (project funded by the European Research Council (ERC-2014-CoG, project 647473) and led by Prof. F. Laio from Politecnico of Turin, Italy), the one from which we retrieved the WF data for the present study. The novelty of the CWASI database is represented by a differentiation between the production and supply side of annual values of uWF of primary and processed crops.

The uWF of production (uWFp) pertains to crop products that are cultivated locally, and it refers to factors such as evapotranspiration and crop yield. These values are estimated on an annual basis, beginning from 1961 to 2016, and are available for a total of N = 255 countries.

The uWF of supply (uWFs) represents the domestic provision of primary and processed crops, originating from both local production and international trade. These figures are calculated as an average value between the quantities of local production and imports from the year 1986 to 2016 (see Tamea et al., Reference Tamea, Tuninetti, Soligno and Laio2021b for a comprehensive review).

The CWASI database kept the WaterStat values for uWF of animal-based foods, with no temporal variation.

For the purpose of our analysis, we used data of uWF of supply both for crop and animal-based products. This choice has been made since the supply data better represent human consumption, which is the focus of this research. We used data of uWFs of crops of the year 2016, the most recent available.

For the assessment of the WF of fish we used the study from Pahlow et al. (Reference Pahlow, van Oel, Mekonnen and Hoekstra2015), like previous studies (see for instance Vanham et al., Reference Vanham, Guenther, Ros-Baró and Bach-Faig2021), since the WF of fish is not included either in the WaterStat database or in the CWASI one. The motivation is that computing the WF of marine fish like any other agrifood products, meaning calculating it as proportion between the average worldwide ocean evaporation and the total amount of caught fish (Fereres et al., Reference Fereres, Villalobos, Orgaz, Minguez, van Halsema and Perry2017), would return an unreasonably high value, besides being devoid of significance, given the fact that ocean evaporation (a component of the calculation) is a process that would occur anyway (Fereres et al., Reference Fereres, Villalobos, Orgaz, Minguez, van Halsema and Perry2017). Nonetheless, it is possible to approximate the WF of aquaculture fish by assessing the amount of water used and polluted during the production of their food. This methodology mirrors the approach used for determining the WF of various other animal products.

We considered the blue and green WF values of aquaculture fish referred to the year 2008 from Pahlow et al. (Reference Pahlow, van Oel, Mekonnen and Hoekstra2015).

The Sustainable Diet Model and alternative dietary scenarios

To examine different dietary options that can reduce the WF while maintaining nutritional adequacy, we employed a modified version of the sustainable diet model (SDM), originally developed by Cavaliere et al. (Reference Cavaliere, De Marchi, Frola, Benfenati, Aletti, Bacenetti and Banterle2023).

By adapting the formula, the SDM solves the following problem:

(1)$$\arg \min _{\matrix{ {m_i \le x_i \le M_i, } \cr {\sum\nolimits_{i = 1}^{14} {k_ix_i = K} } \cr } }{\rm \omega }_w\mathop \sum \limits_{i = 1}^{14} \displaystyle{{w_ix_i} \over {1\left[{\displaystyle{{{\rm liter}} \over {{\rm pers}\cdot {\rm day}}}} \right]}} + {\rm \beta }\mathop \sum \limits_{i = 1}^{14} \left({\displaystyle{{x_i-p_i} \over {\,p_i}}} \right)^2$$

In equation (1), the vector x i = (x 1, x 2, … , x 14) is the weekly consumption, measured in grams, of all 14 food categories included in the analysis. The values mi and Mi represent the lower and upper bounds for the range of intake for each food category. The variable K is the total weekly caloric intake of the diet and it is constant. The variable ki represents calories of each specific food category and it can vary depending on the chosen diet model being tested.

The variable wi is the WF associated with the weekly consumption of each food category. The first term, $\sum\nolimits_{i = 1}^{14} {w_ix_i}$ equals the total WF of the diet.

The term ${\rm \beta }\sum\nolimits_{i = 1}^{14} {{( {( {x_i \hbox{-} p_i} ) /p_i} ) }^2}$ quantifies people's resistance to modify their dietary patterns when substantial variations are involved, such as the complete removal of specific food categories from the diet. Higher values for β indicate that people have a low acceptability of new dietary patterns, while low β means a greater willingness to alter the diets.

Therefore, the solution to equation (1) seeks to find best dietary solution that minimizes both the total WF and the deviation from the RID. In this equation, the parameter β is set to different values: 0.2 for the mainly animal-based diet, 0.6 for the mainly plant-based diet, and 1 for the exclusively plant-based diet.

The mainly animal-based diet is built upon the Atlantic Diet (AD) guidelines. The AD is the traditional dietary pattern of Portugal and Galicia (Vaz Velho, Pinheiro and Rodrigues, Reference Vaz Velho, Pinheiro and Rodrigues2016) and it is considered a variation of the IMD, offering similar health advantages, especially on preventing cardiovascular diseases (Oliveira, Lopes and Rodriguez-Artalejo, Reference Oliveira, Lopes and Rodriguez-Artalejo2010; Guallar-Castillón et al., Reference Guallar-Castillón, Oliveira, Lopes, López-García and Rodríguez-Artalejo2013). It differs from the IMD for its higher intake of fish, red meat, milk, cheese, and potatoes, as observed in the findings of García-Gómez et al. (Reference García-Gómez, Rivas-Casais, Lorences-Touzón, Piedrafita-Páez, Muñoz-Ferreiro, Vázquez-Odériz and Romero-Rodríguez2022). This diet is included in the study, as it is quite similar to the IMD and people may shift to such dietary model with relatively low efforts, while contributing to reduce diet-related environmental impacts. For the AD, we assume the parameter β = 0.2, meaning a low resistance in changing the eating habits.

The mainly plant-based diet is based on the EAT-Lancet diet. Introduced in 2019 by the EAT–Lancet Commission, the EAT-Lancet diet is regarded as an exemplary model of a sustainable diet. This diet, as outlined by Willett et al. (Reference Willett, Rockström, Loken, Springmann, Lang, Vermeulen, Garnett, Tilman, DeClerck, Wood and Jonell2019), is not only health-conscious but also environmentally sustainable, playing a pivotal role in reshaping the global food systems while staying within the limits of planetary boundaries (Steffen et al., Reference Steffen, Richardson, Rockström, Cornell, Fetzer, Bennett, Biggs, Carpenter, de Vries, de Wit, Folke, Gerten, Heinke, Mace, Persson, Ramanathan, Reyers and Sörlin2015). The EAT-Lancet is a primarily plant-based diet, which also allows for a moderate consumption of meat and dairy products. It shares similarities with the IMD but incorporates a higher quantity of fruits and vegetables, whose consumption is low in the RID.

For the EAT-Lancet diet we assume a greater resistance to changing dietary habits toward a predominantly plant-based diet (β = 0.6). This suggests that people are assumed to be less inclined to adopt such dietary changes, reflecting the challenges associated with transitioning to a diet that places a greater emphasis on plant-based foods, such as social, religious, cultural, neophobic, and economic obstacles (Abe-Inge et al., Reference Abe-Inge, Aidoo, Moncada de la Fuente and Kwofie2024).

Moreover, we assess the WF for an exclusively plant-based diet. This choice aligns with prior research findings indicating that predominantly or entirely plant-based diets, such as vegetarian and vegan diets, exhibit minimal environmental impact, as supported by studies like those conducted by Hallström, Carlsson-Kanyama and Börjesson. (Reference Hallström, Carlsson-Kanyama and Börjesson2015), Chai et al. (Reference Chai, van der Voort, Grofelnik, Eliasdottir, Klöss and Perez-Cueto2019), and Cavaliere et al. (Reference Cavaliere, De Marchi, Frola, Benfenati, Aletti, Bacenetti and Banterle2023).

The exclusively plant-based diet avoids all animal-based foods, thus red meat, white meat, cured meat, fish, milk and cheese. We increase the minimum amount (in terms of grams per day) of pulses in order to compensate for nutritional lack of proteins deriving from the complete exclusion of animal-based products. Nevertheless, it's important to acknowledge that adopting a vegan diet may lead to nutritional inadequacies, and nutritional integration may be necessary to address the absence of nutrients like vitamin B12, essential fatty acids, and calcium (Alles et al., Reference Alles, Baudry, Mejean, Touvier, Peneau, Hercberg and Kesse-Guyot2019; Schupbach et al., Reference Schupbach, Wegmuller, Berguerand, Bui and Herter-Aeberli2017; Jeitler et al., Reference Jeitler, Storz, Steckhan, Matthiae, Dressler, Hanslian, Koppold, Kandil, Michalsen and Kessler2022). Our study prioritises optimizing the WF of the diets, addressing nutritional concerns is not the main focus. For the plant-based diet, we set β = 1.

Results

Trends in food consumption in Italy and WF comparison: RID vs IMD

Data show that food consumption in Italy has remained overall constant over time (see Appendix B for the weekly intake of each food category over time). In detail, the analysis shows slight increases in the consumption of white meat (+2.37%), leaf vegetables (+4.77%), and vegetables (+6.78%). Larger increases can be noticed in the consumption of fish (+9.96%), pulses (+13.94%), and snacks (+18.73%). On the other hand, we notice decreases in the consumption of the following food categories: sweets (−2.41%); cured meat (−4.04%); potatoes (−6.62%); cheese (−8.06%); red meat (−8.44%); fruits (−10.67%); bread, pasta, and rice (−13.87%); and milk (−21.40%). Figure 1 shows the positive and negative variations of changes in food consumption in Italy over the 2005–2021 period. Despite the decreasing consumption trend of certain animal-based food categories over the past years, especially cheese, red meat, and milk, which have a greater impact in terms of water consumption (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2012; Hoekstra, Reference Hoekstra2014), the WF of the RID is still 95.96% higher than that of the IMD (Table 1). This is because the Italian population consumes quantities of animal products that largely exceed the amount recommended in the IMD. In 2021, red meat consumption in Italy (+381 g week -1 compared to the MD) was the major contributor to WF (Fig. 2), associated with a uWF value equals to 18.65 L g−1.

Figure 1. Changes in real food consumption in Italy from 2005 to 2021.

Table 1. Water Footprint by food categories respectively for the Real Italian Diet and the Italian Mediterranean Diet

Figure 2. Graphic representation of the WF of the RID vs the WF of the IMD for each food category (L person−1 day−1).

As a result, the WF of red meat category of the RID is equal to 1228.95 L person−1 day−1 (+476.61% higher than the one of the IMD). The second most impactful food in terms of WF is represented by the sweets, whose current consumption is + 215 g week−1 compared to the IMD recommended portion (50 g week−1). The WF of sweets is equal to 686.06 L person−1 day−1 (+434.46% higher than the one of the IMD). The other most impactful food categories in the RID are: cheese, which has a WF equals to 284.63 L person−1 day−1 (+63.76% with respect to the IMD); fish, with a WF of 138.07 L person−1 day−1 (+90.92% with respect to the IMD); cured meat, which has a WF equals to 130.85 L person−1 day−1 (+460.24% with respect to the IMD); and white meat, with a WF of 116.11 L person−1 day−1 (+115.36% with respect to the IMD). On the other hand, we found an opposite situation for certain food categories which have a low uWF and whose weekly consumption in the RID is lower than that of the IMD. As a consequence, the WF of these food categories is lower than it would be in the IMD. This is the case of milk (57.09 L person−1 day−1, −72.49% with respect to the IMD); it is the same for vegetables, with a WF of 49.82 L person−1 day−1 (−59.19% with respect to the one of the IMD); leafy vegetables, with a WF equals to 10.54 L person−1 day−1 (−56.15% with respect to the one of the IMD); fruits (WF of 102.76 L person−1 day−1, −50.97% with respect to the WF of the recommended IMD portion); bread, pasta, and rice (143.30 L person−1 day−1, −37.93% with respect to the IMD); and pulses (98.79 L person−1 day−1, −3.24% with respect to the IMD).

To summarize, it can be noticed how the biggest contributor in terms of WF of the RID are animal-based foods, namely red meat, cheese, fish, cured meat, and white meat, accounting for more than 80% of the total WF of the RID (Fig. 3).

Figure 3. Pie charts of the contribution of animal-based foods and plant-based ones to the WF of the RID 2021 and of the IMD (L person−1 day−1).

WF of alternative dieatry scenarios

As for the SDM, we use the following procedure. Firstly, we assign the maximum and minimum values (Mi and mi) of food intake to each of the 14 categories. The Mi and mi values are expressed in grams per day and have been identified starting from the guidelines of the IMD (CREA, 2018). We then establish the β value for each diet as explained in the Materials and Methods section.

By solving the SDM as described, we obtain the WF values respectively for (i) the mainly animal-based, (ii) the mainly plant-based, and (iii) the exclusively plant-based diets (Fig. 4).

Figure 4. Bar charts of the WF of all dietary patterns.

The mainly and exclusively plant-based diets have a substantially lower environmental impact in terms of WF with respect to both the RID and the IMD.

In fact, the mainly plant-based diet has a WF equals to 1131.38 L person−1 day−1, which corresponds to −63.21% with respect to the WF of the RID and −27.91% with respect to impact of the IMD. The exclusively plant-based diet improves the WF related to food consumption even more: with a WF of 729.34 L person−1 day−1, it represents the least impactful diet.

On the other hand, the mainly animal-based diet, which includes moderate amount of meat products, has a WF of 1885.92 L person−1 day−1, which represents a reduction of −38.70% with respect to the WF of the RID, but is + 21.12% higher than the one of the IMD.

Discussion

The analysis of food consumption in Italy from 2005 to 2021 reveals that the current consumption of red meat is approximately four times higher compared to the recommended intake of the IMD, which is 100 grams week−1 per capita.

Vegetable consumption, instead, is relatively low, at around 1100 grams week−1 per capita, compared to the recommended portion in the IMD, which is 2800 grams week−1 per capita. Consequently, the overall WF of the RID is very high.

This aligns with previous research demonstrating that animal-based foods are the primary contributors to diet-related WF, as highlighted by studies by Hoekstra (Reference Hoekstra2012) and Gerbens-Leenes, Mekonnen and Hoekstra (Reference Gerbens-Leenes, Mekonnen and Hoekstra2013). Through the SDM, we show that a reduction in WF can be obtained with modest changes in consumption habits, which could be easily acceptable for consumers to undertake. Transitioning to a dietary pattern akin to the AD, which involves higher consumption of animal-based foods compared to the IMD, would still represent an improvement relative to the RID. This finding is consistent with previous studies (Esteve-Llorens et al., Reference Esteve-Llorens, Darriba, Moreira, Feijoo and González-García2019; González-García et al., Reference González-García, Green, Scheelbeek, Harris and Dangour2020). More substantial reductions in WF can be attained following the IMD recommendations or other primarily plant-based dietary patterns, such as the EAT-Lancet diet, which allows only moderate meat consumption (Kassem, Rudbeck Jepsen and Salhofer, Reference Kassem, Rudbeck Jepsen and Salhofer2021). Completely avoiding all animal-based products can bring additional environmental benefits (Rosi et al., Reference Rosi, Mena, Pellegrini, Turroni, Neviani, Ferrocino, Di Cagno, Ruini, Ciati, Angelino and Maddock2017; Castañé and Antón, Reference Castañé and Antón2017), although such drastic changes may face challenges in gaining widespread consumer acceptance.

In addition to the results presented, this paper makes a unique contribution to the field by expanding the literature concerning the environmental consequences of food consumption from the perspective of WF. Compared to previous studies (such as Capone et al., Reference Capone, Iannetta, El Bilali, Colonna, Debs, Dernini, Maiani, Intorre, Polito, Turrini, Cardone, Lorusso and Belsanti2013; Vanham, Hoekstra and Bidoglio, Reference Vanham, Hoekstra and Bidoglio2013), our study relies on recent real consumption data in Italy and proposes alternative dietary scenarios tailored for the Italian case, taking into account the level of resistance that individuals might encounter in changing their dietary habits.

Despite these results, it is important to acknowledge that this study has some caveats. First, our analysis relies on self-reported food consumption data and the food intake calculation is based on the conversion of frequencies into standard portion sizes of each food. However, the data do not allow for controlling that respondents' real consumption correspond to such portion sizes. Food Frequency Surveys have some limitations (Wild et al., Reference Wild, Andersson, O'Brien, Wilson and Woods2001). In fact, people often struggle to accurately discern both frequencies and the quantities of the foods that they consume (Shim, Oh and Kim, Reference Shim, Oh and Kim2014). This may lead to potential over- or underestimation of food consumption and their related environmental impact. Second, the uWF values for each food category are derived from an average calculation of uWF values for specific food products selected from the CWASI database. As a result, the estimated WF of diets may have some slight bias, as different products within the same food category (e.g., fruits) may have different uWF values. This also occurs, for example, in the assessment of the CF of food consumption. Indeed, even within the same food category, different products can have significantly different GHG emissions, as demonstrated by Hallström, Carlsson-Kanyama and Börjesson (Reference Hallström, Carlsson-Kanyama and Börjesson2015) and Tilman and Clark (Reference Tilman and Clark2014). For these reasons, the use of an average category value may not accurately represent individual product differences.

Conclusion

The results presented in this article show that the RID does not align with the IMD recommendations. Specifically, the high animal-based food consumption (especially of meat), is responsible for high WF. Improvements in terms of WF can be achieved by partially or completely eliminating animal-based foods, as demonstrated in the cases of exclusively or mainly plant-based diets. However, shifting toward vegetarian or vegan diet might be challenging for consumers. Alternative diets, such as mainly animal-based’ diets with reduced portions of these products could represent an advantage in terms of WF reduction and might be more easily adopted by the population.

These results offer novel insights for guiding policies aimed at promoting sustainable food consumption. Indeed, adopting diets with low environmental impact can help diminishing the stress on water resources, especially in a context of increasing water scarcity, exacerbated by climate change. The Mediterranean basin is likely to become severely affected by extreme climatic events in the next future. These aspects stresses the importance of tackling the WF of current food habits in Mediterranean countries, as well as the intent to find alternative diets to reduce the impact of the RID in terms of WF.

Designing policies to foster the adoption of sustainable food consumption can significantly contribute to reducing the WF of diets, aligning with the objectives of the Agenda 2030. To facilitate the shift towards more sustainable choices, increasing consumer awareness about the WF of food can be crucial. The implementation of informative campaigns and the introduction of specific labels signaling the WF of food products can guide consumers in making informed decisions when selecting among different food options.

Future research could focus on individual consumption data to obtain a more precise understanding of the environmental impact of each individual's dietary choices and identify tailored solutions to reduce their impact.

Competing interests

None.

Appendix

Appendix A. Standard IMD portions for each food category

Appendix B. Trend of food consumption of each food category over the period 2005–2021

References

Abe-Inge, V., Aidoo, R., Moncada de la Fuente, M. and Kwofie, E.M. (2024) ‘Plant-based dietary shift: current trends, barriers, and carriers’, Trends in Food Science & Technology, 143, p. 104292.CrossRefGoogle Scholar
Ali, E., Cramer, W., Carnicer, J., Georgopoulou, E., Hilmi, N.J.M., Le Cozannet, G. and Lionello, P. (2022) ‘Cross-chapter paper 4: Mediterranean region’ in Pörtner, H.-O., Roberts, D.C., Tignor, M., Poloczanska, E.S., Mintenbeck, K., Alegría, A., Craig, M., Langsdorf, S., Löschke, S., Möller, V., Okem, A. and Rama, B. (eds.) Climate change 2022: impacts, adaptation and vulnerability. Contribution of working group II to the sixth assessment report of the intergovernmental panel on climate change. Cambridge, UK and New York, NY, USA: Cambridge University Press, pp. 2233–72.Google Scholar
Allan, J.A. (1993) ‘Fortunately there are substitutes for water otherwise our hydro-political future would be impossible’ in Priorities for water resources allocation and management. London: Overseas Development Administration, pp. 1326.Google Scholar
Allan, J.A. (1994) ‘Overall perspectives on countries and regions’ in Rogers, P. and Lydon, P. (eds.) Water in the Arab world: perspectives and progresses. Cambridge, MA: Harvard University Press, pp. 65100.Google Scholar
Alles, B., Baudry, J., Mejean, C., Touvier, M., Peneau, S., Hercberg, S. and Kesse-Guyot, E. (2019) ‘Comparison of sociodemographic and nutritional characteristics between self-reported vegetarians, vegans, and meat-eaters from the NutriNet-Santé Study’, Nutrients, 9(9), p. 1023.CrossRefGoogle Scholar
Athare, T.R., Pradhan, P. and Kropp, J.P. (2020) ‘Environmental implications and socioeconomic characterisation of Indian diets’, Science of the Total Environment, 737, p. 139881.CrossRefGoogle ScholarPubMed
Bahn, R., EL Labban, S. and Hwalla, N. (2019) ‘Impacts of shifting to healthier food consumption patterns on environmental sustainability in MENA countries’, Sustainability Science, 14, pp. 1131–46.CrossRefGoogle Scholar
Benvenuti, L., De Santis, A. and Cacchione, P. (2021) ‘Multi-indicator design and assessment of sustainable diet plans’, Journal of Cleaner Production, 313, p. 127699.CrossRefGoogle Scholar
Capone, R., Iannetta, M., El Bilali, H., Colonna, N., Debs, P., Dernini, S., Maiani, G., Intorre, F., Polito, A., Turrini, A., Cardone, G., Lorusso, F. and Belsanti, V. (2013) ‘A preliminary assessment of the environmental sustainability of the current Italian dietary pattern: water footprint related to food consumption’, Journal of Food and Nutrition Research, 4, pp. 5967.Google Scholar
Castañé, S. and Antón, A. (2017) ‘Assessment of the nutritional quality and environmental impact of two food diets: a Mediterranean and a vegan diet’, Journal of Cleaner Production, 167, pp. 929–37.CrossRefGoogle Scholar
Cavaliere, A., De Marchi, E. and Banterle, A. (2018) ‘Exploring the adherence to the Mediterranean Diet and its relationship with individual lifestyle: the role of healthy behaviors, pro-environmental behaviors, income, and education’, Nutrients, 10, p. 141.CrossRefGoogle Scholar
Cavaliere, A., De Marchi, E., Frola, E.N., Benfenati, A., Aletti, G., Bacenetti, J. and Banterle, A. (2023) ‘Exploring the environmental impact associated with the abandonment of the Mediterranean Diet, and how to reduce it with alternative sustainable diets’, Ecological Economics, 209, p. 107818.CrossRefGoogle Scholar
Chai, B.C., van der Voort, J.R., Grofelnik, K., Eliasdottir, H.G., Klöss, I. and Perez-Cueto, F.J.A. (2019) ‘Which diet has the least environmental impact on our planet? A systematic review of vegan, vegetarian and omnivorous diets’, Sustainability, 11(15), p. 4110.CrossRefGoogle Scholar
CREA. (2018) Linee guida per una sana alimentazione. Revisione 2018. Available at: https://www.crea.gov.it/web/alimenti-e-nutrizione/-/linee-guida-per-una-sana-alimentazione-2018 (Accessed: 28 September 2022).Google Scholar
Esteve-Llorens, X., Darriba, C., Moreira, M.T., Feijoo, G. and González-García, S. (2019) ‘Towards an environmentally sustainable and healthy Atlantic dietary pattern: life cycle carbon footprint and nutritional quality’, Science of the Total Environment, 646, pp. 704–15.CrossRefGoogle ScholarPubMed
FAO. (2015) Mediterranean food consumption patterns: diet, environment, society, economy and health. A white paper priority 5 of feeding knowledge programme, expo Milan. Rome: ciheam-iamB, Bari/Fao.Google Scholar
FAO. (2017) Water for Sustainable Food and Agriculture. A report produced for the G20 Presidency of Germany. Available at: https://www.fao.org/3/i7959e/i7959e.pdf (Accessed: 24 October 2022).Google Scholar
Fereres, E., Villalobos, F.J., Orgaz, F., Minguez, M.I., van Halsema, G. and Perry, C.J. (2017) ‘Commentary: on the water footprint as an indicator of water use in food production’, Irrigation Science, 35, pp. 83–5.CrossRefGoogle Scholar
García-Gómez, B., Rivas-Casais, A., Lorences-Touzón, R., Piedrafita-Páez, N., Muñoz-Ferreiro, N., Vázquez-Odériz, L. and Romero-Rodríguez, A. (2022) ‘Adherence to and knowledge about the Atlantic Diet pattern in the senior population of the Galician region (NW-Spain)’, Journal of Functional Foods, 91, p. 105015.CrossRefGoogle Scholar
Gerbens-Leenes, P.W., Mekonnen, M.M. and Hoekstra, A.Y. (2013) ‘The water footprint of poultry, pork and beef: a comparative study in different countries and production systems’, Water Resources and Industry, 1(2), pp. 2536.CrossRefGoogle Scholar
González-García, S., Green, R.F., Scheelbeek, P., Harris, F. and Dangour, A.D. (2020) ‘Dietary recommendations in Spain—affordability and environmental sustainability?’, Journal of Cleaner Production, 254, p. 120125.CrossRefGoogle ScholarPubMed
González, N., Marquès, M., Nadal, M. and Domingo, J.L. (2020) ‘Meat consumption: which are the current global risks? A review of recent (2010–2020) evidences’, Food Research International, 137, p. 109341.CrossRefGoogle ScholarPubMed
Guallar-Castillón, P., Oliveira, A., Lopes, C., López-García, E. and Rodríguez-Artalejo, F. (2013) ‘The southern European Atlantic Diet is associated with lower concentrations of markers of coronary risk’, Atherosclerosis, 226, pp. 502–9.CrossRefGoogle ScholarPubMed
Guenther, M., Saunders, C.M. and Tait, P.R. (2012) ‘Carbon labeling and consumer attitudes’, Carbon Management, 3(5), pp. 445–55.CrossRefGoogle Scholar
Hallström, E., Carlsson-Kanyama, A. and Börjesson, P. (2015) ‘Environmental impact of dietary change: a systematic review’, Journal of Cleaner Production, 91, pp. 111.CrossRefGoogle Scholar
Hoekstra, A.Y. (2012) ‘The hidden water resource use behind meat and dairy’, Animal Frontiers, 2(2), pp. 38.CrossRefGoogle Scholar
Hoekstra, A.Y. (2014) ‘Water for animal products: a blind spot in water policy’, Environmental Research Letters, 9, p. 091003.CrossRefGoogle Scholar
Hoekstra, A.Y., Chapagain, A.K., Aldaya, M.M. and Mekonnen, M.M. (2011) The water footprint assessment manual: setting the global standard. London, USA: Earthscan.Google Scholar
Hoekstra, A.Y. and Hung, P.Q. (2002) Virtual water trade: a quantification of virtual water flows between nations in relation to international crop trade, value of water research report series no. 11. Delft, the Netherlands: IHE.Google Scholar
Jeitler, M., Storz, M.A., Steckhan, N., Matthiae, D., Dressler, J., Hanslian, E., Koppold, D.A., Kandil, F.I., Michalsen, A. and Kessler, C.S. (2022) ‘Knowledge, attitudes and application of critical nutrient supplementation in vegan diets among healthcare professionals—survey results from a medical congress on plant-based nutrition’, Foods, 11(24), p. 4033.CrossRefGoogle ScholarPubMed
Kassem, R., Rudbeck Jepsen, M. and Salhofer, S.P. (2021) ‘The water consumption of different diets in Denmark’, Journal Cleaner Production, 286, p. 124938.CrossRefGoogle Scholar
Katz, D.L. and Meller, S. (2014) ‘Can we say what diet is best for health?’, Annual Review of Public Health, 35, pp. 83103.CrossRefGoogle ScholarPubMed
Liu, T., Wang, Q. and Su, B. (2016) ‘A review of carbon labeling: standards, implementation, and impact’, Renewable and Sustainable Energy Reviews, 53, pp. 6879.CrossRefGoogle Scholar
Mekonnen, M.M. and Hoekstra, A.Y. (2010a) The green, blue and grey water footprint of crops and derived crop products, value of water research report series, no. 47. Delft, the Netherlands: UNESCO-IHE.Google Scholar
Mekonnen, M.M. and Hoekstra, A.Y. (2010b) The green, blue and grey water footprint of farm animals and animal products, value of water research report series, no. 48. Delft, the Netherlands: UNESCO-IHE.Google Scholar
Mekonnen, M.M. and Hoekstra, A.Y. (2012) ‘A global assessment of the water footprint of farm animal products’, Ecosystems, 15(3), pp. 401–15.CrossRefGoogle Scholar
Noah, A. and Truswell, A.S. (2001) ‘There are many Mediterranean diets’, Asia Pacific Journal of Clinical Nutrition, 10(1), pp. 29.CrossRefGoogle ScholarPubMed
Notarnicola, B., Tassielli, G., Renzulli, P.A., Castellani, V. and Sala, S. (2017) ‘Environmental impacts of food consumption in Europe’, Journal of Cleaner Production, 140, pp. 753–65.CrossRefGoogle Scholar
Oliveira, A., Lopes, C. and Rodriguez-Artalejo, F. (2010) ‘Adherence to the southern European Atlantic Diet and occurrence of nonfatal acute myocardial infarction’, The American Journal of Clinical Nutrition, 92(1), pp. 211–7.CrossRefGoogle Scholar
Pahlow, M., van Oel, P.R., Mekonnen, M.M. and Hoekstra, A.Y. (2015) ‘Increasing pressure on freshwater resources due to terrestrial feed ingredients for aquaculture production’, Science of The Total Environment, 536, pp. 847–57.CrossRefGoogle ScholarPubMed
Ridoutt, B.G., Hendrie, G.A. and Noakes, M. (2017) ‘Dietary strategies to reduce environmental impact: a critical review of the evidence base’, Advances in Nutrition, 8(6), pp. 933–46.CrossRefGoogle ScholarPubMed
Ritchie, H. and Roser, M. (2020) Environmental Impacts of Food Production. Our World in Data. Available at: https://ourworldindata.org/environmental-impacts-of-food.Google Scholar
Rosi, A., Mena, P., Pellegrini, N., Turroni, S., Neviani, E., Ferrocino, I., Di Cagno, R., Ruini, L., Ciati, R., Angelino, D. and Maddock, J. (2017) ‘Environmental impact of omnivorous, ovo-lacto-vegetarian, and vegan diet’, Scientific Reports, 7, p. 6105.CrossRefGoogle ScholarPubMed
Schupbach, R., Wegmuller, R., Berguerand, C., Bui, M. and Herter-Aeberli, I. (2017) ‘Micronutrient status and intake in omnivores, vegetarians and vegans in Switzerland’, European Journal of Nutrition, 56, pp. 283–93.CrossRefGoogle ScholarPubMed
Semenov, M.A., Stratonovitch, P., Alghabari, F. and Gooding, M.J. (2014) ‘Adapting wheat in Europe for climate change’, Journal of Cereal Science, 59, pp. 245–56.CrossRefGoogle ScholarPubMed
Senapati, N., Stratonovitch, P., Paul, M.J. and Semenov, M.A. (2018) ‘Drought tolerance during reproductive development is important for increasing wheat yield potential under climate change in Europe’, Journal of Experimental Botany, 70(9), pp. 2549–60.CrossRefGoogle Scholar
Shim, J., Oh, K. and Kim, H. (2014) ‘Dietary assessment methods in epidemiologic studies’, Epidemiology and Health, 36, p. e2014009.CrossRefGoogle ScholarPubMed
Steffen, W., Richardson, K., Rockström, J., Cornell, S., Fetzer, I., Bennett, E., Biggs, R., Carpenter, S.R., de Vries, W., de Wit, C.A., Folke, C., Gerten, D., Heinke, J., Mace, G.M., Persson, L.M., Ramanathan, V., Reyers, B. and Sörlin, S. (2015) ‘Planetary boundaries: guiding human development on a changing planet’, Science, 347(6223), p. 1259855.CrossRefGoogle ScholarPubMed
Tamea, S., Antonelli, M. and Vallino, E. (2021) ‘The Italian virtual water trade and water footprint of agricultural production: trends and perspectives' in Turrini, P., Massarutto, A., Pertile, M. and de Carli, A. (eds.) Water law, policy and economics in Italy. Global issues in water policy, vol. 28. Cham: Springer. https://doi.org/10.1007/978-3-030-69075-5_10Google Scholar
Tamea, S., Tuninetti, M., Soligno, I. and Laio, F. (2021b) ‘Virtual water trade and water footprint of agricultural goods: the 1961–2016 CWASI database’, Earth System Science Data, 13, pp. 2025–51.CrossRefGoogle Scholar
The European House—Ambrosetti S.p.A. (2021) Valore acqua per l'Italia. Seconda edizione. Available at: .Google Scholar
Tilman, D. and Clark, M. (2014) ‘Global diets link environmental sustainability and human health’, Nature, 515(7528), pp. 518–22.CrossRefGoogle ScholarPubMed
Toreti, A., Bavera, D., Avanzi, F., Cammalleri, C., De Felice, M., de Jager, A., Di Ciollo, C., Gabellani, S., Maetens, W., Magni, D., Manfron, G., Masante, D., Mazzeschi, M., McCormick, N., Naumann, G., Niemeyer, S., Rossi, L., Seguini, L., Spinoni, J. and van den Berg, M. (2022) Drought in northern Italy—March 2022: GDO analytical report. Luxembourg: Publications Office of the European Union. https://doi.org/10.2760/781876. Available at: https://publications.jrc.ec.europa.eu/repository/handle/JRC128974.Google Scholar
UN, The United Nations World Water Development Report (2018) United Nations Educational, Scientific and Cultural Organization. New York, USA: UN, The United Nations World Water Development Report. Available at: www.unwater.org/publications/world-water-development-report-2018 (Accessed: 24 October 2022).Google Scholar
Van de Kamp, M., van Dooren, C., Hollander, A., Geurts, M., Brink, E., van Rossum, C., Biesbroek, S., de Valk, E., Toxopeus, I. and Temme, E. (2018) ‘Healthy diets with reduced environmental impact?—The greenhouse gas emissions of various diets adhering to the Dutch food based dietary guidelines’, Food Research International, 104, pp. 1424.CrossRefGoogle Scholar
Vanham, D., Guenther, S., Ros-Baró, M. and Bach-Faig, A. (2021) ‘Which diet has the lower water footprint in Mediterranean countries?’, Resources, Conservation and Recycling, 171, p. 105631.CrossRefGoogle ScholarPubMed
Vanham, D., Hoekstra, A.Y. and Bidoglio, G. (2013) ‘Potential water saving through changes in European diets’, Environment International, 61, pp. 4556.CrossRefGoogle ScholarPubMed
Vaz Velho, M., Pinheiro, R. and Rodrigues, A.S. (2016) ‘The Atlantic Diet—origin and features’, International Journal of Food Studies, 5, pp. 106–19.CrossRefGoogle Scholar
Wild, C.P., Andersson, C., O'Brien, N.M., Wilson, L. and Woods, J.A. (2001) ‘A critical valuation of the application of biomarkers in epidemiological studies on diet and health’, British Journal of Nutrition, 86(1), pp. S3753.CrossRefGoogle Scholar
Willett, W., Rockström, J., Loken, B., Springmann, M., Lang, T., Vermeulen, S., Garnett, T., Tilman, D., DeClerck, F., Wood, A. and Jonell, M. (2019) ‘Food in the Anthropocene: the EAT Lancet Commission on healthy diets from sustainable food systems’, Lancet, 393, pp. 447–92.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Changes in real food consumption in Italy from 2005 to 2021.

Figure 1

Table 1. Water Footprint by food categories respectively for the Real Italian Diet and the Italian Mediterranean Diet

Figure 2

Figure 2. Graphic representation of the WF of the RID vs the WF of the IMD for each food category (L person−1 day−1).

Figure 3

Figure 3. Pie charts of the contribution of animal-based foods and plant-based ones to the WF of the RID 2021 and of the IMD (L person−1 day−1).

Figure 4

Figure 4. Bar charts of the WF of all dietary patterns.

Figure 5

Appendix A. Standard IMD portions for each food category

Figure 6

Appendix B. Trend of food consumption of each food category over the period 2005–2021