1 Introduction

Human development depends on safeguarding the stability of the planet (Steffen et al., 2018; Xu et al., 2020). Current human activities, especially of high consuming wealthy societies, are threatening the stability of Earth's life support systems and its capacity to support our future well-being in the Anthropocene (Steffen, Broadgate, et al., 2015). Simultaneously, key human development needs remain, including attaining the UN Sustainable Development Goals for all by 2030, and ensuring continued human well-being for a world population of possibly 10 billion people in 2050. Addressing these challenges requires a full integration of people's lives and the planet's stability.

Critical to achieving a full integration of ‘safe’ and ‘just’ is to scientifically assess a safe and just corridor for human development on Earth (Figure 1), which we define as follows:

This corridor bounds pathways of future human development that are both safe and just over time. This safe and just corridor will provide high-level “outcome” goals and the context for companies, cities, governments, and other actors who want to take action by operationalizing scientifically guided sustainability in their ventures (Andersen et al., 2020). Safe and just also implies that the Earth's natural resources, such as budgets for carbon, nutrients, water, and land, are finite (defined by safety) and have to be shared between people and with nature.

We use target in the general sense of a measurable goal or objective, such as the target to limit climate change to “well below 2°C” (UNFCCC, 2015; Xu & Ramanathan, 2017), and target range to emphasize both (i) the uncertainty in science for both safe and just target setting, and (ii) our goal of synthesizing a range of safe and just conditions rather than prescribing any specific solution. We distinguish between scientific Earth system targets, targets at the global or near-global scale that are generated primarily by scientific inquiry but may be informed by societal judgments about risks (Pickering & Persson, 2020), and science-based targets, targets for actors that are aligned with scientific evidence but which may involve negotiations based on responsibility and feasibility (Andersen et al., 2020). Hence, practical downscaling of global scientific targets to specific science-based targets for different actors is beyond the scope of this study.

Previous frameworks, such as the planetary boundaries (Rockström et al., 2009) and donut economics (Raworth, 2018), have advanced our understanding of safe ceilings on human disruptions of the Earth system and just foundations for human access to natural resources. These frameworks, however, do not fully integrate safe and just, representing them with different dimensions (Earth system processes vs. social goals) and uncomparable variables. How biophysically “safe” targets can be achieved while also meeting goals for human well-being and justice is difficult to explore in such frameworks, for example, determining a safe and just allocation of land for food production. Furthermore, these prior frameworks explicitly incorporate neither sub-global scales (Dearing et al., 2014), interactions and feedbacks between variables (Lade et al., 2020), nor potential trade-offs between planetary targets and development and equity (Biermann & Kim, 2020; Pickering & Persson, 2020). An integrated framework is needed that aligns safe and just Earth system variables while also accounting for sub-global scales and interactions between Earth system processes. We now expand on the motivation, definition, and challenges associated with our proposal of an integrated safe and just corridor.

2 Defining Safe Earth System Targets

We are now experiencing rapid global changes due to human pressures in the Anthropocene, likely exceeding ‘safe' levels in several dimensions. Species extinction rates are tens to hundreds of times higher than they were on average over the last 10 million years with an average of 68% decline in wild animal populations since just the 1970s (WWF, 2020); we have the highest atmospheric concentration of greenhouse gases in the last 3 million years, a geological period (the Quaternary) when global mean temperatures never exceeded 2°C of global warming above pre-industrial levels (Steffen et al., 2018); nine tipping elements that regulate the state of the Earth system have known tipping points that show worrying signs of destabilization (Lenton et al., 2019); and we have widespread pollution of air and water through our use of minerals, chemicals, and novel substances. The frequency of spillover of zoonotic diseases from animals to humans has increased (Karesh et al., 2012), most recently manifested in the COVID-19 pandemic, with zoonotic host diversity rising with human degradation of natural habitats (Gibb et al., 2020). There is an urgent need to define the safe targets for a stable Earth system, where risks of human-triggered irreversible changes and crossing of tipping points (Lenton et al., 2019) are avoided.

The scientific community has provided evidence-based targets to avoid dangerous climate change (Hoegh-Guldberg et al., 2018) or loss of biodiversity and its contributions to people (IPBES, 2019): for example, the “safe” climate target of holding global mean temperature rise well below 2°C (aiming at 1.5°C) above pre-industrial levels (UNFCCC, 2015). “Safe” targets are needed for the other vital processes and systems that regulate the state of the planet—including the appropriate allocation and configuration of land use, the health of the oceans, and the global cycling of nitrogen, phosphorus, and water that supports life.

Identifying safe ranges for these systems in isolation, for example as the planetary boundary framework has done (Rockström et al., 2009; Steffen, Richardson, et al., 2015), will not be enough to describe a safe corridor. The complex interactions and feedbacks among Earth system processes must be considered and can make a corridor much narrower (Lade et al., 2020). It is crucial to establish the key feedbacks regulating, or destabilizing, each safety variable, and how they interact on different timescales. To quantitatively assess and combine these feedbacks, an established but under-used approach of calculating and combining feedback “gain” factors (Lashof, 1989) can provide a useful framework. This framework needs to be fed with information on key relationships from running Earth system and integrated assessment models, including “off-line” model coupling (using the outputs of one as inputs to the other) to relate safety variables that are in separate models. Setting “safe” targets also need to account for timescales in the Earth system, for example, incorporating the change to future states of the Earth system committed by pressures now. And, the Earth system interactions may mean the safe corridor changes over time.

A useful reference Earth system state for defining safe targets is the Holocene, which began around 11,700 years ago. The Holocene's relatively stable climate, together with its configurations of biogeochemical cycling, and nature's contributions to people, have enabled extraordinary human development—from multiple independent origins of agriculture to increasingly integrated complex cities, economies, energy, agricultural, and communication systems. Only within a Holocene-like inter-glacial climate can we be certain that Earth can continue to support human development (Steffen et al., 2018). There is no evidence that billions of humans and complex societies can thrive in other known climates, such as the glacial ice age or Hothouse Earth (Steffen et al., 2018).

3 Integrating Justice in Earth System Targets

Human choices and actions could narrow or widen the safe and just corridor for human development. Considering the complex interactions, feedbacks, and non-linearities within and between societal activities and Earth system behavior, we need to advance beyond previous frameworks such as the “donut” (Raworth, 2018) to understand when “safe” and “just” ranges do and do not overlap.

First, an “unsafe” world is likely to increase inequality, so “safe” would seem a necessary pre-condition for “just”—but not always a sufficient one. A “safe” target from a biophysical perspective may not be adequate to prevent large-scale risks to humans in specific contexts. For example, there are large risks for many human populations even with a 1.5°C climate target (Hoegh-Guldberg et al., 2018).

Second, a key question is how biophysically “safe” targets can be achieved while also meeting goals for human well-being and justice. For example, meeting the social goals of Agenda 2030 without widespread transformations may lead to crossing safe targets for the biophysical state of the Earth system (Sachs et al., 2019). Achieving biophysical targets, such as 1.5°C for climate or increasing ecosystem protection, can undermine well-being, if, for example, bioenergy competes with food production, or protected areas undermine local livelihoods (Hasegawa et al., 2020).

Third, risks of exceeding safe and just targets are amplified for vulnerable people and can affect human health, displace people, and destabilize societies. At the same time, those most negatively impacted by environmental changes are often those who contribute the least environmental impact and have the lowest resilience and capacity to adapt (Gupta et al., 2020). A quarter of all death and disease is attributable to environmental causes (McClain et al., 2019). Extreme weather events disproportionately kill or harm the poor, women, the elderly, children, and indigenous people (McClain et al., 2019). Climate change may displace millions of people particularly in poorer parts of the world (Xu et al., 2020). The COVID-19 pandemic, linked in part to natural decline and greater human-wildlife contact (Gibb et al., 2020), has disproportionally affected the more vulnerable (Mesa Vieira et al., 2020). Their vulnerability is not innate but is often created by societal structures, attitudes, and governance systems that are unjust and do not prioritize well-being for all.

We propose that the stricter of the safe and just target ranges for each variable should define the safe and just corridor (Figure 2). Furthermore, we propose to identify a spread of safe and just targets corresponding to different physical risk tolerances and different understandings of environmental justice. For example, a climate target that is just for all humans could be stricter than a target that avoids most climate tipping points, which in turn could be stricter than a target that is just for only a minority of humans.

4 Levers of Transformation and Challenges of Translation

By identifying safe and just target ranges, the question arises: How can we achieve these targets and live within the corridor? Transforming toward a “just” world may be a pre-condition for being able to achieve a “safe” world. Leverage points to achieve such transformations are essential for governing our commons. They need to be explored from equity, responsibility, and risk sharing, and participatory perspective to be effective (Ostrom et al., 1999) in the increasingly crowded, hyper-connected, turbulent, and high-risk world of the Anthropocene.

A key challenge is to identify systems that enable sharing of Earth's limited resources and nature's benefits to ensure human well-being in equitable ways. Agenda 2030 (UNGA, 2015) provides a global consensus on key justice principles of access and a starting point for an analysis of a safe and just corridor that aims to ensure that “no one will be left behind.” But while it calls for reducing inequality, it has yet to set targets relating to how resources and risks should be shared. Although it calls for strengthening the means of implementation, it is unclear how such transformations will actually be leveraged. Learning the lessons regarding equity in sharing resources, rights, responsibilities, and risks is critical (Ensor & Hoddy, 2020). For example, the evolution of transboundary water law has led to the identification of key criteria for sharing water between nations (UNGA, 1997). Furthermore, the politics of who gets what, when, where, and how is often determined by those who are more powerful in the system. Rules of access and distribution then become locked-in and difficult to transform. Existing environmental assessments, with a few exceptions (IPBES, 2019), often do not make space to discuss the critical political science and international relations literature with respect to these issues.

An independent synthesis of the broader social science literature is needed to map out: which response strategies are most effective in managing not just the symptoms of a problem but its underlying causes; which response strategies match the diversity and evolving nature of societies, cultures, economies, and technologies, and fulfill minimum criteria for ethics, transparency, trust, collaboration, recognition, and inclusive governance; the trade-offs and synergies between different goals and targets; and which actors and levers are most effective in enabling a transformation which shares the remaining Earth's resources in a just way, to ensure the continued functioning of Earth system processes for human development.

To put any of these ideas into practice requires the involvement of diverse actors across scales from the local to global (Ostrom et al., 1999). While cross-scale translation is necessary to inform decisions by such actors at sub-global scales, translation is complicated by the spatial heterogeneity of pressures and impacts (Biermann & Kim, 2020) and the value-laden (Biermann & Kalfagianni, 2020; Häyhä et al., 2016) and potentially iterative (Pickering & Persson, 2020) judgments involved in the allocation of these targets. Therefore, a synthesis of the challenges associated with translating global-scale Earth system targets to actors at other scales is needed.

5 Conclusions

We have introduced a conceptual framework for defining a safe and just corridor for human development in the Anthropocene. The Earth Commission (https://earthcommission.org/), convened by Future Earth, is an independent international scientific assessment initiative that will use this framework to conduct a scientific assessment of the safe and just corridor. As part of the Global Commons Alliance (https://globalcommonsalliance.org/), the Commission's theory of change includes providing results to the Science-Based Targets Network (SBTN), the Systems Change Lab, and Earth HQ, who jointly will mobilize actors to take appropriate measures. In particular, the Earth Commission's report will be used to underpin the development of science-based targets for business and cities by SBTN.

The Earth Commission now faces the challenge of identifying an integrated safe and just corridor for people on Earth, based on safe and just targets for all Earth system regulating systems and processes such as land, oceans, biodiversity, water, and nutrient cycles (nitrogen and phosphorous). We will then analyze levers of transformation and review methods and challenges associated with translating the safe and just corridor to actors across scales. We see this task as a much-needed advancement of integrated global sustainability research aimed at finding solutions for human development in the Anthropocene. We welcome scientific inputs based on new or existing work from scholars around the world to secure our future on Earth by defining a safe and just corridor and addressing this grand challenge on how to define scientific targets and levers of transformation (please submit through https://earthcommission.org/contribute/). Earth system and integrated assessment modeling groups are specifically sought to join in formulating the protocol and running a set of simulations for a new Earth and human system model inter-comparison project.

The present mutually reinforcing crises of climate change, biodiversity decline, and health problems illustrate that this frontier research is overdue. The COVID-19 pandemic shows that many jurisdictions are willing to prioritize health over monetary wealth, even if briefly, opening up transformation lessons for the future.