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Planetary boundaries

February 16, 2024

Not to be confused with Planetary boundary layer.

Planetary boundaries are a framework to describe limits to the impacts of human activities on the Earth system. Beyond these limits, the environment may not be able to self-regulate anymore. This would mean the Earth system would leave the period of stability of the Holocene, in which human society developed.[2][3][4] The framework is based on scientific evidence that human actions, especially those of industrialized societies since the Industrial Revolution, have become the main driver of global environmental change. According to the framework, "transgressing one or more planetary boundaries may be deleterious or even catastrophic due to the risk of crossing thresholds that will trigger non-linear, abrupt environmental change within continental-scale to planetary-scale systems."[2]

Planetary boundaries diagram; orange sections indicate "overshoot" of boundaries, green sections indicate a "safe" state within the boundaries (data for September 2023).[1]

The normative component of the framework is that human societies have been able to thrive under the comparatively stable climatic and ecological conditions of the Holocene. To the extent that these Earth system process boundaries have not been crossed, they mark the "safe zone" for human societies on the planet.[3] Proponents of the planetary boundary framework propose returning to this environmental and climatic system; as opposed to human science and technology deliberately creating a more beneficial climate. The concept doesn't address how humans have massively altered ecological conditions to better suit themselves. The climatic and ecological Holocene this framework considers as a "safe zone" doesn't involve massive industrial farming. So this framework begs a reassessment of how to feed modern populations.

The concept has since become influential in the international community (e.g. United Nations Conference on Sustainable Development), including governments at all levels, international organizations, civil society and the scientific community.[5] The framework consists of nine global change processes. In 2009, according to Rockström and others, three boundaries were already crossed (biodiversity loss, climate change and nitrogen cycle), while others were in imminent danger of being crossed.[6]

In 2015, several of the scientists in the original group published an update, bringing in new co-authors and new model-based analysis. According to this update, four of the boundaries were crossed: climate change, loss of biosphere integrity, land-system change, altered biogeochemical cycles (phosphorus and nitrogen).[7] The scientists also changed the name of the boundary "Loss of biodiversity" to "Change in biosphere integrity" to emphasize that not only the number of species but also the functioning of the biosphere as a whole is important for Earth system stability. Similarly, the "Chemical pollution" boundary was renamed to "Introduction of novel entities", widening the scope to consider different kinds of human-generated materials that disrupt Earth system processes.

In 2022, based on the available literature, the introduction of novel entities was concluded to be the 5th transgressed planetary boundary.[8] Freshwater change was concluded to be the 6th transgressed planetary boundary in 2023.[1]

Framework overview and principles edit

The basic idea of the Planetary Boundaries framework is that maintaining the observed resilience of the Earth system in the Holocene is a precondition for humanity's pursuit of long-term social and economic development.[9] The Planetary Boundaries framework contributes to an understanding of global sustainability because it brings a planetary scale and a long timeframe into focus.[7]

The framework described nine "planetary life support systems" essential for maintaining a "desired Holocene state", and attempted to quantify how far seven of these systems had been pushed already.[6] Boundaries were defined to help define a "safe space for human development", which was an improvement on approaches aiming at minimizing human impacts on the planet.[9]

The framework is based on scientific evidence that human actions, especially those of industrialized societies since the Industrial Revolution, have become the main driver of global environmental change. According to the framework, "transgressing one or more planetary boundaries may be deleterious or even catastrophic due to the risk of crossing thresholds that will trigger non-linear, abrupt environmental change within continental-scale to planetary-scale systems."[9] The framework consists of nine global change processes. In 2009, two boundaries were already crossed, while others were in imminent danger of being crossed.[6] Later estimates indicated that three of these boundaries—climate change, biodiversity loss, and the biogeochemical flow boundary—appear to have been crossed.

The scientists outlined how breaching the boundaries increases the threat of functional disruption, even collapse, in Earth's biophysical systems in ways that could be catastrophic for human wellbeing. While they highlighted scientific uncertainty, they indicated that breaching boundaries could "trigger feedbacks that may result in crossing thresholds that drastically reduce the ability to return within safe levels". The boundaries were "rough, first estimates only, surrounded by large uncertainties and knowledge gaps" which interact in complex ways that are not yet well understood.[9]

The planetary boundaries framework lays the groundwork for a shifting approach to governance and management, away from the essentially sectoral analyses of limits to growth aimed at minimizing negative externalities, toward the estimation of the safe space for human development. Planetary boundaries demarcate, as it were, the "planetary playing field" for humanity if major human-induced environmental change on a global scale is to be avoided.[7]

Authors edit

The authors of this framework was a group of Earth System and environmental scientists in 2009 led by Johan Rockström from the Stockholm Resilience Centre and Will Steffen from the Australian National University. They collaborated with 26 leading academics, including Nobel laureate Paul Crutzen, Goddard Institute for Space Studies climate scientist James Hansen, oceanographer Katherine Richardson, geographer Diana Liverman and the German Chancellor's chief climate adviser Hans Joachim Schellnhuber.

Most of the contributing scientists were involved in strategy-setting for the Earth System Science Partnership, the precursor to the international global change research network Future Earth. The group wanted to define a "safe operating space for humanity" for the wider scientific community, as a precondition for sustainable development.

Nine boundaries edit

Thresholds and tipping points edit

The 2009 study identified nine planetary boundaries and, drawing on current scientific understanding, the researchers proposed quantifications for seven of them. These are:

  1. climate change (CO2 concentration in the atmosphere < 350 ppm and/or a maximum change of +1 W/m2 in radiative forcing);
  2. ocean acidification (mean surface seawater saturation state with respect to aragonite ≥ 80% of pre-industrial levels);
  3. stratospheric ozone depletion (less than 5% reduction in total atmospheric O3 from a pre-industrial level of 290 Dobson Units);
  4. biogeochemical flows in the nitrogen (N) cycle (limit industrial and agricultural fixation of N2 to 35 Tg N/yr) and phosphorus (P) cycle (annual P inflow to oceans not to exceed 10 times the natural background weathering of P);
  5. global freshwater use (< 4000 km3/yr of consumptive use of runoff resources);
  6. land system change (< 15% of the ice-free land surface under cropland);
  7. the erosion of biosphere integrity (an annual rate of loss of biological diversity of < 10 extinctions per million species).
  8. chemical pollution (introduction of novel entities in the environment).

For one process in the planetary boundaries framework, the scientists have not specified a global boundary quantification:

  1. atmospheric aerosol loading;

The quantification of individual planetary boundaries is based on the observed dynamics of the interacting Earth system processes included in the framework. The control variables were chosen because together they provide an effective way to track the human-caused shift away from Holocene conditions.

For some of Earth's dynamic processes, historic data display clear thresholds between comparatively stable conditions. For example, past ice-ages show that during peak glacial conditions, the atmospheric concentration of CO2 was ~180-200 ppm. In interglacial periods (including the Holocene), CO2 concentration has fluctuated around 280 ppm. To know what past climate conditions were like with an atmosphere with over 350 ppm CO2, scientists need to look back about 3 million years. The paleo record of climatic, ecological and biogeochemical changes shows that the Earth system has experienced tipping points, when a very small increment for a control variable (like CO2) triggers a larger, possibly catastrophic, change in the response variable (global warming) through feedbacks in the natural Earth System itself.

For several of the processes in the planetary boundaries framework, it is difficult to locate individual points that mark the threshold shift away from Holocene-like conditions. This is because the Earth system is complex and the scientific evidence base is still partial and fragmented. Instead, the planetary boundaries framework identifies many Earth system thresholds at multiple scales that will be influenced by increases in the control variables.[6] Examples include shifts in monsoon behavior linked to the aerosol loading and freshwater use planetary boundaries.

Planetary Boundaries (as defined in 2023)[1]
Earth-system
process		 Control variable[1] Boundary
value in 2023		 "Current" value


(i.e. for the year provided in the source)

Boundary now
exceeded beyond the 2023 values? (based on "current" value)		 Preindustrial Holocene base value
1. Climate change Atmospheric carbon dioxide concentration (ppm by volume)[10]
See also: Tipping point (climatology)
 350 417[11] yes 280
Total anthropogenic radiative forcing at top-of-atmosphere (W/m2) since the start of the industrial revolution (~1750) 1.0 2.91[11] yes 0
2. Change in biosphere integrity[1] Genetic diversity: Extinction rate measured as E/MSY (extinctions per million species-years) <10 E/MSY but with an aspirational goal of ca. 1 E/MSY (assumed background rate of extinction loss) >100 E/MSY yes 1 E/MSY
Functional diversity: energy available to ecosystems (NPP) (% HANPP) HANPP (in billion tonnes of C year−1) <10% of preindustrial Holocene NPP, i.e., >90% remaining for supporting biosphere function 30% HANPP yes 1.9% (2σ variability of preindustrial Holocene century-mean NPP)
3. Biogeochemical Phosphate global: P flow from freshwater systems into the ocean; regional: P flow from fertilizers to erodible soils (Tg of P year−1) Phosphate global: 11 Tg of P year−1; regional: 6.2 Tg of P year−1 mined and applied to erodible (agricultural) soils. Global: 22 Tg of P year−1;[12] regional: 17.5 Tg of P year−1 yes 0
Nitrogen global: industrial and intentional fixation of N (Tg of N year−1) 62 190 yes 0
4. Ocean acidification Global mean saturation state of calcium carbonate in surface seawater (omega units) 2.75 2.8 no 3.44
5. Land use Part of forests rested intact (percent)[7] 75 from all forests including 85 from Boreal forest, 50 from Temperate forests and 85 from Tropical forests[7] Global: 60[7] yes 100
6. Freshwater change Blue water: human induced disturbance of blue water flow Upper limit (95th percentile) of global land area with deviations greater than during preindustrial, Blue water: 10.2% 18.2% yes 9.4%
Green water: human induced disturbance of water available to plants (% land area with deviations from preindustrial variability) 11.1% 15.8% yes 9.8%
7. Ozone depletion Stratospheric ozone concentration (Dobson units) 276 284.6 no 290
8. Atmospheric aerosols Interhemispheric difference in AOD 0.1 (mean annual interhemispheric difference) 0.076 no 0.03
9. Novel entities Percentage of synthetic chemicals released to the environment without adequate safety testing 0 Transgressed yes 0

"Safe operating spaces" edit

The planetary boundaries framework proposes a range of values for its control variables. This range is supposed to span the threshold between a 'safe operating space' where Holocene-like dynamics can be maintained and a highly uncertain, poorly predictable world where Earth system changes likely increase risks to societies. The boundary is defined as the lower end of that range. If the boundaries are persistently crossed, the world goes further into a danger zone.[6]

It is difficult to restore a 'safe operating space' for humanity that is described by the planetary boundary concept. Even if past biophysical changes could be mitigated, the predominant paradigms of social and economic development appear largely indifferent to the looming possibilities of large scale environmental disasters triggered by human actions.[9][13] Legal boundaries can help keep human activities in check, but are only as effective as the political will to make and enforce them.[14]

Interaction among boundaries edit

Understanding the Earth system is fundamentally about understanding interactions among environmental change processes. The planetary boundaries are defined with reference to dynamic conditions of the Earth system, but scientific discussions about how different planetary boundaries relate to each other are often philosophically and analytically muddled. Clearer definitions of the basic concepts and terms might help give clarity.

There are many many interactions among the processes in the planetary boundaries framework.[7][3] While these interactions can create both stabilizing and destabilizing feedbacks in the Earth system, the authors suggested that a transgressed planetary boundary will reduce the safe operating space for other processes in the framework rather than expand it from the proposed boundary levels.[3] They give the example that the land use boundary could "shift downward" if the freshwater boundary is breached, causing lands to become arid and unavailable for agriculture. At a regional level, water resources may decline in Asia if deforestation continues in the Amazon. That way of framing the interactions shifts from the framework's biophysical definition of boundaries based on Holocene-like conditions to an anthropocentric definition (demand for agricultural land). Despite this conceptual slippage, considerations of known Earth system interactions across scales suggest the need for "extreme caution in approaching or transgressing any individual planetary boundaries."[3]

Another example has to do with coral reefs and marine ecosystems: In 2009, researchers showed that, since 1990, calcification in the reefs of the Great Barrier that they examined decreased at a rate unprecedented over the last 400 years (14% in less than 20 years).[15] Their evidence suggests that the increasing temperature stress and the declining ocean saturation state of aragonite is making it difficult for reef corals to deposit calcium carbonate. Multiple stressors, such as increased nutrient loads and fishing pressure, moves corals into less desirable ecosystem states.[16] Ocean acidification will significantly change the distribution and abundance of a whole range of marine life, particularly species "that build skeletons, shells, and tests of biogenic calcium carbonate. Increasing temperatures, surface UV radiation levels and ocean acidity all stress marine biota, and the combination of these stresses may well cause perturbations in the abundance and diversity of marine biological systems that go well beyond the effects of a single stressor acting alone."[17][18]

Proposed new or expanded boundaries since 2012 edit

In 2012, Steven Running suggested a tenth boundary, the annual net global primary production of all terrestrial plants, as an easily determinable measure integrating many variables that will give "a clear signal about the health of ecosystems".[19][20][21]

In 2015, a second paper was published in Science to update the Planetary Boundaries concept.[7] The update concluded four boundaries had now been transgressed: climate, biodiversity, land use and biogeochemical cycles. The 2015 paper emphasized interactions of the nine boundaries and identified climate change and loss of biodiversity integrity as 'core boundaries' of central importance to the framework because the interactions of climate and the biosphere are what scientifically defines Earth system conditions.[22]

In 2017, some authors argued that marine systems are underrepresented in the framework. Their proposed remedy was to include the seabed as a component of the earth surface change boundary. They also wrote that the framework should account for "changes in vertical mixing and ocean circulation patterns".[22]

Subsequent work on planetary boundaries begins to relate these thresholds at the regional scale.[23]

Debate and further research per boundary edit

See also: List of environmental issues

Climate change edit

See also: Effects of climate change

A 2018 study calls into question the adequacy of efforts to limit warming to 2 °C above pre-industrial temperatures, as set out in the Paris Agreement.[23] The scientists raise the possibility that even if greenhouse gas emissions are substantially reduced to limit warming to 2 °C, that might exceed the "threshold" at which self-reinforcing climate feedbacks add additional warming until the climate system stabilizes in a hothouse climate state. This would make parts of the world uninhabitable for people, raise sea levels by up to 60 metres (200 ft), and raise temperatures by 4–5 °C (7.2–9.0 °F) to levels that are higher than any interglacial period in the past 1.2 million years.[24]

Change in biosphere integrity edit

See also: Biodiversity loss, Deforestation, Decline in insect populations, and Holocene extinction

According to the biologist Cristián Samper, a "boundary that expresses the probability of families of species disappearing over time would better reflect our potential impacts on the future of life on Earth."[25] The biodiversity boundary has also been criticized for framing biodiversity solely in terms of the extinction rate. The global extinction rate has been highly variable over the Earth's history, and thus using it as the only biodiversity variable can be of limited usefulness.[22]

Nitrogen and phosphorus edit

The biogeochemist William Schlesinger thinks waiting until we near some suggested limit for nitrogen deposition and other pollutions will just permit us to continue to a point where it is too late. He says the boundary suggested for phosphorus is not sustainable, and would exhaust the known phosphorus reserves in less than 200 years.[26]

The ocean chemist Peter Brewer queries whether it is "truly useful to create a list of environmental limits without serious plans for how they may be achieved ... they may become just another stick to beat citizens with. Disruption of the global nitrogen cycle is one clear example: it is likely that a large fraction of people on Earth would not be alive today without the artificial production of fertilizer. How can such ethical and economic issues be matched with a simple call to set limits? ... food is not optional."[27]

Peak phosphorus is a concept to describe the point in time at which the maximum global phosphorus production rate is reached. Phosphorus is a scarce finite resource on earth and means of production other than mining are unavailable because of its non-gaseous environmental cycle.[28] According to some researchers, Earth's phosphorus reserves are expected to be completely depleted in 50–100 years and peak phosphorus to be reached by approximately 2030.[29][30]

Ocean acidification edit

Surface ocean acidity is clearly interconnected with the climate change boundaries, since the concentration of carbon dioxide in the atmosphere is also the underlying control variable for the ocean acidification boundary.[31]

The ocean chemist Peter Brewer thinks "ocean acidification has impacts other than simple changes in pH, and these may need boundaries too."[27]

Land-system change edit

Across the planet, forests, wetlands and other vegetation types are being converted to agricultural and other land uses, impacting freshwater, carbon and other cycles, and reducing biodiversity.[31] In the year 2015 the boundary was defined as 75% of forests rested intact, including 85% of boreal forests, 50% of temperate forests and 85% of tropical forests. The boundary is crossed because only 62% of forests rested intact as of the year 2015.[7]

The boundary for land use has been criticized as follows: "The boundary of 15 per cent land-use change is, in practice, a premature policy guideline that dilutes the authors' overall scientific proposition. Instead, the authors might want to consider a limit on soil degradation or soil loss. This would be a more valid and useful indicator of the state of terrestrial health."[32]

Freshwater edit

The freshwater cycle is another boundary significantly affected by climate change.[31] Overexploitation of freshwater occurs if a water resource is mined or extracted at a rate that exceeds the recharge rate. Water pollution and saltwater intrusion can also turn much of the world's underground water and lakes into finite resources with "peak water" usage debates similar to oil.[33][34]

The hydrologist David Molden stated in 2009 that planetary boundaries are a welcome new approach in the "limits to growth" debate but said "a global limit on water consumption is necessary, but the suggested planetary boundary of 4,000 cubic kilometres per year is too generous."[35]

Green and blue water edit

A study concludes that the 'Freshwater use' boundary should be renamed to the 'Freshwater change', composed of "green" and "blue" water components.[36] 'Green water' refers to disturbances of terrestrial precipitation, evaporation and soil moisture.[36] Water scarcity can have substantial effects in agriculture.[37][38] When measuring and projecting water scarcity in agriculture for climate change scenarios, both "green water" and "blue water" are of relevance.[37][38]

In April 2022, scientists proposed and preliminarily evaluated 'green water' in the water cycle as a likely transgressed planetary boundary, as measured by root-zone soil moisture deviation from Holocene variability.[36][additional citation(s) needed]

Ozone depletion edit

Main article: Ozone depletion

The stratospheric ozone layer protectively filters ultraviolet radiation (UV) from the Sun, which would otherwise damage biological systems. The actions taken after the Montreal Protocol appeared to be keeping the planet within a safe boundary.[31]

The Nobel laureate in chemistry, Mario Molina, says "five per cent is a reasonable limit for acceptable ozone depletion, but it doesn't represent a tipping point".[39]

Atmospheric aerosols edit

Worldwide each year, aerosol particles result in about 800,000 premature deaths from air pollution.[citation needed] Aerosol loading is sufficiently important to be included among the planetary boundaries, but it is not yet clear whether an appropriate safe threshold measure can be identified.[31]

Novel entities (chemical pollution) edit

See also: Chemical waste
 
State parties to the Stockholm Convention on Persistent Organic Pollutants

Some chemicals, such as persistent organic pollutants, heavy metals and radionuclides, have potentially irreversible additive and synergic effects on biological organisms, reducing fertility and resulting in permanent genetic damage. Sublethal uptakes are drastically reducing marine bird and mammal populations. This boundary seems important, although it is hard to quantify.[31][8][40] In 2019, it was suggested that novel entities could include genetically modified organisms, pesticides and even artificial intelligence.[5]

A Bayesian emulator for persistent organic pollutants has been developed which can potentially be used to quantify the boundaries for chemical pollution.[41] To date, critical exposure levels of polychlorinated biphenyls (PCBs) above which mass mortality events of marine mammals are likely to occur, have been proposed as a chemical pollution planetary boundary.[42]

There are at least 350,000 artificial chemicals in the world. They are coming from "plastics, pesticides, industrial chemicals, chemicals in consumer products, antibiotics and other pharmaceuticals". They have mostly "negative effects on planetary health". Their production increased 50 times since 1950 and is expected to increase 3 times more by 2050. Plastic alone contain more than 10,000 chemicals and create large problems. The researchers are calling for limit on chemical production and shift to circular economy, meaning to products that can be reused and recycled.[43]

In January 2022 a group of scientists concluded that this planetary boundary is already exceeded, which puts in risk the stability of the Earth system.[44] They integrated the literature information on how production and release of a number of novel entities, including plastics and hazardous chemicals, have rapidly increased in the last decades with significant impact on the planetary processes.[8]

In August 2022, scientists concluded that the (overall transgressed) boundary is a placeholder for multiple different boundaries for NEs that may emerge, reporting that PFAS pollution is one such new boundary. They show that levels of these so-called "forever chemicals" in rainwater are ubiquitously, and often greatly, above guideline safe levels worldwide.[45][46] There are some moves to restrict and replace their use.[45]

Related concepts edit

Planetary integrity edit

See also: Sustainable Development Goals § Weak on environmental sustainability

Planetary integrity is also called earth's life-support systems or ecological integrity.[47]: 140  Scholars have pointed out that planetary integrity "needs to be maintained for long-term sustainability".[47]: 140  The current biodiversity loss is threatening ecological integrity on a global scale.[47]: 140  The term integrity refers to ecological health in this context. The concept of planetary integrity is interlinked within the concept of planetary boundaries.[47]: 141 

An expert Panel on Ecological Integrity in 1998 has defined ecological integrity as follows: "Ecosystems have integrity when they have their native components (plants, animals and other organisms) and processes (such as growth and reproduction) intact."[48]

The Sustainable Development Goals might be able to act as a steering mechanism to address the current loss of planetary integrity.[47]: 142  There are many negative human impacts on the environment that are causing a reduction in planetary integrity.[47]: 142 

The "Limits to Growth" (1972) and Gaia theory edit

The idea that there are limits to the burden placed upon our planet by human activities has been around for a long time. The Planetary Boundaries framework acknowledges the influence of the 1972 study, The Limits to Growth, that presented a model in which exponential growth in world population, industrialization, pollution, food production, and resources depletion outstrip the ability of technology to increase resources availability.[49] Subsequently, the report was widely dismissed, particularly by economists and business people,[50] and it has often been claimed that history has proved the projections to be incorrect.[51] In 2008, Graham Turner from the Commonwealth Scientific and Industrial Research Organisation (CSIRO) published "A comparison of The Limits to Growth with thirty years of reality".[52] The Limits to Growth has been widely discussed, both by critics of the modelling approach and its conclusions[53][54] and by analysts who argue that the insight that societies do not live in an unlimited world and that historical data since the 1970s support the report's findings.[55][56] The Limits to Growth approach explores how the socio-technical dynamics of the world economy may limit humanity's opportunities and introduce risks of collapse. In contrast, the Planetary Boundaries framework focuses on the biophysical dynamics of the Earth system.[7]

Our Common Future was published in 1987 by United Nations' World Commission on Environment and Development.[57] It tried to recapture the spirit of the Stockholm Conference. Its aim was to interlock the concepts of development and environment for future political discussions. It introduced the famous definition for sustainable development: "Development that meets the needs of the present without compromising the ability of future generations to meet their own needs."[57]

Another key idea influencing the Planetary Boundaries framework is the Gaia theory or hypothesis. In the 1970s, James Lovelock and microbiologist Lynn Margulis presented the idea that all organisms and their inorganic surroundings on Earth are integrated into a single self-regulating system.[58] The system has the ability to react to perturbations or deviations, much like a living organism adjusts its regulation mechanisms to accommodate environmental changes such as temperature (homeostasis). Nevertheless, this capacity has limits. For instance, when a living organism is subjected to a temperature that is lower or higher than its living range, it can perish because its regulating mechanism cannot make the necessary adjustments. Similarly the Earth may not be able to react to large deviations in critical parameters.[7] In Lovelock's book The Revenge of Gaia, he suggests that the destruction of rainforests and biodiversity, compounded with global warming resulting from the increase of greenhouse gases made by humans, could shift feedbacks in the Earth system away from a self-regulating balance to a positive (intensifying) feedback loop.

Anthropocene edit

Main article: Anthropocene

Science indicates that we are transgressing planetary boundaries that have kept civilization safe for the past 10,000 years. Evidence is growing that human pressures are starting to overwhelm the Earth’s buffering capacity. Humans are now the most significant driver of global change, propelling the planet into a new geological epoch, the Anthropocene. We can no longer exclude the possibility that our collective actions will trigger tipping points, risking abrupt and irreversible consequences for human communities and ecological systems.

Stockholm Memorandum (2011)

Scientists have affirmed that the planet has entered a new epoch, the Anthropocene.[59] In the Anthropocene, humans have become the main agents of not only change to the Earth System[60] but also the driver of Earth System rupture,[61] disruption of the Earth System's ability to be resilient and recover from that change, potentially ultimately threatening planetary habitability. The previous geological epoch, the Holocene began about 10,000 years ago. It is the current interglacial period, and was a relatively stable environment of the Earth. There have been natural environmental fluctuations during the Holocene, but the key atmospheric and biogeochemical parameters have remained within relatively narrow bounds.[62] This stability has allowed societies to thrive worldwide, developing agriculture, large-scale settlements and complex networks of trade.[63]

According to Rockström et al., we "have now become so dependent on those investments for our way of life, and how we have organized society, technologies, and economies around them, that we must take the range within which Earth System processes varied in the Holocene as a scientific reference point for a desirable planetary state."[9]

Various biophysical processes that are important in maintaining the resilience of the Earth system are also undergoing large and rapid change because of human actions.[64] For example, since the advent of the Anthropocene, the rate at which species are going extinct has increased over 100 times,[65] and humans are now the driving force altering global river flows[66] as well as water vapor flows from the land surface.[67] Continuing perturbation of Earth system processes by human activities raises the possibility that further pressure could be destabilizing, leading to non-linear, abrupt, large-scale or irreversible environmental change responses by the Earth system within continental- to planetary-scale systems.[7]

Reception and debate edit

See also: § Debate and further research per boundary

In summary, the planetary boundary concept is a very important one, and its proposal should now be followed by discussions of the connections between the various boundaries and of their association with other concepts such as the 'limits to growth'. Importantly, this novel concept highlights the risk of reaching thresholds or tipping points for non-linear or abrupt changes in Earth-system processes. As such, it can help society to reach the agreements required for dealing effectively with existing global environmental threats, such as climate change.

– Nobel laureate Mario J. Molina[39]

The 2009 report[3] was presented to the General Assembly of the Club of Rome in Amsterdam.[68] An edited summary of the report was published as the featured article in a special 2009 edition of Nature[2] alongside invited critical commentary from leading academics like Nobel laureate Mario J. Molina and biologist Cristián Samper.[39]

Development studies scholars have been critical of aspects of the framework and constraints that its adoption could place on the Global South. Proposals to conserve a certain proportion of Earth's remaining forests can be seen as rewarding the countries such as those in Europe that have already economically benefitted from exhausting their forests and converting land for agriculture. In contrast, countries that have yet to industrialize are asked to make sacrifices for global environmental damage they may have had little role in creating.[22]

The biogeochemist William Schlesinger queries whether thresholds are a good idea for pollutions at all. He thinks waiting until we near some suggested limit will just permit us to continue to a point where it is too late. "Management based on thresholds, although attractive in its simplicity, allows pernicious, slow and diffuse degradation to persist nearly indefinitely."[26]

In a global empirical study, researchers investigated how students of environmental and sustainability studies in 35 countries assessed the planetary boundaries. It was found that there are substantial global differences in the perception of planetary boundaries.[69]

Subsequent developments edit

The "safe and just space" doughnut edit

 
Doughnut (economic model)
This section is an excerpt from Doughnut (economic model).[edit]

The Doughnut, or Doughnut economics, is a visual framework for sustainable development – shaped like a doughnut or lifebelt – combining the concept of planetary boundaries with the complementary concept of social boundaries.[70] The name derives from the shape of the diagram, i.e. a disc with a hole in the middle. The centre hole of the model depicts the proportion of people that lack access to life's essentials (healthcare, education, equity and so on) while the crust represents the ecological ceilings (planetary boundaries) that life depends on and must not be overshot.[71] The diagram was developed by University of Oxford economist Kate Raworth in her 2012 Oxfam paper A Safe and Just Space for Humanity and elaborated upon in her 2017 book Doughnut Economics: Seven Ways to Think Like a 21st-Century Economist and paper.[72]

The framework was proposed to regard the performance of an economy by the extent to which the needs of people are met without overshooting Earth's ecological ceiling.[73] The main goal of the new model is to re-frame economic problems and set new goals. In this context, the model is also referred to as a "wake-up call to transform our capitalist worldview".[74] In this model, an economy is considered prosperous when all twelve social foundations are met without overshooting any of the nine ecological ceilings. This situation is represented by the area between the two rings, considered by its creator as a safe and just space for humanity.[75]

National environmental footprints edit

Several studies have assessed environmental footprints of nations based on planetary boundaries: for Portugal,[76] Sweden,[77] Switzerland,[78] the Netherlands,[79] the European Union,[80] India,[81][82] many of Belt and Road Initiative countries [83] as well as for the world's most important economies.[84][85] While the metrics and allocation approaches applied varied, there is a converging outcome that resource use of wealthier nations – if extrapolated to world population – is not compatible with planetary boundaries.

Boundaries related to agriculture and food consumption edit

 
Visualization of the planetary boundaries related to agriculture and nutrition[86]

Human activities related to agriculture and nutrition globally contribute to the transgression of four out of nine planetary boundaries. Surplus nutrient flows (N, P) into aquatic and terrestrial ecosystems are of highest importance, followed by excessive land-system change and biodiversity loss. Whereas in the case of biodiversity loss, P cycle and land-system change, the transgression is in the zone of uncertainty—indicating an increasing risk (yellow circle in the figure), the N boundary related to agriculture is more than 200% transgressed—indicating a high risk (red marked circle in the figure). Here, nutrition includes food processing and trade as well as food consumption (preparation of food in households and gastronomy). Consumption-related environmental impacts are not quantified at the global level for the planetary boundaries of freshwater use, atmospheric aerosol loading (air pollution) and stratospheric ozone depletion.[86]

Individual and collective allowances edit

Approaches based on a general framework of ecological limits include (transferable) personal carbon allowances and "legislated" national greenhouse gas emissions limits.[87] Consumers would have freedom in their (informed) choice within (the collective) boundaries.[88]

Usage at international policy level edit

United Nations edit

The United Nations secretary general Ban Ki-moon endorsed the concept of planetary boundaries on 16 March 2012, when he presented the key points of the report of his High Level Panel on Global Sustainability to an informal plenary of the UN General Assembly.[89] Ban stated: "The Panel's vision is to eradicate poverty and reduce inequality, to make growth inclusive and production and consumption more sustainable, while combating climate change and respecting a range of other planetary boundaries."[90] The concept was incorporated into the so-called "zero draft" of the outcome of the United Nations Conference on Sustainable Development to be convened in Rio de Janeiro 20–22 June 2012.[91] However, the use of the concept was subsequently withdrawn from the text of the conference, "partly due to concerns from some poorer countries that its adoption could lead to the sidelining of poverty reduction and economic development. It is also, say observers, because the idea is simply too new to be officially adopted, and needed to be challenged, weathered and chewed over to test its robustness before standing a chance of being internationally accepted at UN negotiations."[92]

In 2011, at their second meeting, the High-level Panel on Global Sustainability of the United Nations had incorporated the concept of planetary boundaries into their framework, stating that their goal was: "To eradicate poverty and reduce inequality, make growth inclusive, and production and consumption more sustainable while combating climate change and respecting the range of other planetary boundaries."[93]

Elsewhere in their proceedings, panel members have expressed reservations about the political effectiveness of using the concept of "planetary boundaries": "Planetary boundaries are still an evolving concept that should be used with caution [...] The planetary boundaries question can be divisive as it can be perceived as a tool of the "North" to tell the "South" not to follow the resource intensive and environmentally destructive development pathway that rich countries took themselves... This language is unacceptable to most of the developing countries as they fear that an emphasis on boundaries would place unacceptable brakes on poor countries."[94]

However, the concept is routinely used in the proceedings of the United Nations,[95] and in the UN Daily News. For example, the United Nations Environment Programme (UNEP) Executive Director Achim Steiner states that the challenge of agriculture is to "feed a growing global population without pushing humanity's footprint beyond planetary boundaries."[96] The UNEP Yearbook 2010 also repeated Rockström's message, conceptually linking it with ecosystem management and environmental governance indicators.[97]

In their 2012 report entitled "Resilient People, Resilient Planet: A future worth choosing", The High-level Panel on Global Sustainability called for bold global efforts, "including launching a major global scientific initiative, to strengthen the interface between science and policy. We must define, through science, what scientists refer to as "planetary boundaries", "environmental thresholds" and "tipping points"".[98]

European Commission edit

The planetary boundaries concept is also used in proceedings by the European Commission,[99][100] and was referred to in the European Environment Agency synthesis report The European environment – state and outlook 2010.[101]

See also edit

References edit

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External links edit

 
Wikimedia Commons has media related to Planetary boundaries.
  • Figures and data for the updated Planetary Boundaries can be found at the Stockholm Resilience Centre website.
  • Planetary Boundaries: Specials Nature, 24 September 2009.
  • Johan Rockstrom: Let the environment guide our development TED video, July 2010. Transcript html
  • The Planetary Boundaries and what they mean for the Future of Humanity on YouTube

February 16, 2024
planetary, boundaries, confused, with, planetary, boundary, layer, framework, describe, limits, impacts, human, activities, earth, system, beyond, these, limits, environment, able, self, regulate, anymore, this, would, mean, earth, system, would, leave, period. Not to be confused with Planetary boundary layer Planetary boundaries are a framework to describe limits to the impacts of human activities on the Earth system Beyond these limits the environment may not be able to self regulate anymore This would mean the Earth system would leave the period of stability of the Holocene in which human society developed 2 3 4 The framework is based on scientific evidence that human actions especially those of industrialized societies since the Industrial Revolution have become the main driver of global environmental change According to the framework transgressing one or more planetary boundaries may be deleterious or even catastrophic due to the risk of crossing thresholds that will trigger non linear abrupt environmental change within continental scale to planetary scale systems 2 Planetary boundaries diagram orange sections indicate overshoot of boundaries green sections indicate a safe state within the boundaries data for September 2023 1 The normative component of the framework is that human societies have been able to thrive under the comparatively stable climatic and ecological conditions of the Holocene To the extent that these Earth system process boundaries have not been crossed they mark the safe zone for human societies on the planet 3 Proponents of the planetary boundary framework propose returning to this environmental and climatic system as opposed to human science and technology deliberately creating a more beneficial climate The concept doesn t address how humans have massively altered ecological conditions to better suit themselves The climatic and ecological Holocene this framework considers as a safe zone doesn t involve massive industrial farming So this framework begs a reassessment of how to feed modern populations The concept has since become influential in the international community e g United Nations Conference on Sustainable Development including governments at all levels international organizations civil society and the scientific community 5 The framework consists of nine global change processes In 2009 according to Rockstrom and others three boundaries were already crossed biodiversity loss climate change and nitrogen cycle while others were in imminent danger of being crossed 6 In 2015 several of the scientists in the original group published an update bringing in new co authors and new model based analysis According to this update four of the boundaries were crossed climate change loss of biosphere integrity land system change altered biogeochemical cycles phosphorus and nitrogen 7 The scientists also changed the name of the boundary Loss of biodiversity to Change in biosphere integrity to emphasize that not only the number of species but also the functioning of the biosphere as a whole is important for Earth system stability Similarly the Chemical pollution boundary was renamed to Introduction of novel entities widening the scope to consider different kinds of human generated materials that disrupt Earth system processes In 2022 based on the available literature the introduction of novel entities was concluded to be the 5th transgressed planetary boundary 8 Freshwater change was concluded to be the 6th transgressed planetary boundary in 2023 1 Contents 1 Framework overview and principles 1 1 Authors 2 Nine boundaries 2 1 Thresholds and tipping points 2 2 Safe operating spaces 2 3 Interaction among boundaries 2 4 Proposed new or expanded boundaries since 2012 2 5 Debate and further research per boundary 2 5 1 Climate change 2 5 2 Change in biosphere integrity 2 5 3 Nitrogen and phosphorus 2 5 4 Ocean acidification 2 5 5 Land system change 2 5 6 Freshwater 2 5 6 1 Green and blue water 2 5 7 Ozone depletion 2 5 8 Atmospheric aerosols 2 5 9 Novel entities chemical pollution 3 Related concepts 3 1 Planetary integrity 3 2 The Limits to Growth 1972 and Gaia theory 3 3 Anthropocene 4 Reception and debate 5 Subsequent developments 5 1 The safe and just space doughnut 5 2 National environmental footprints 5 3 Boundaries related to agriculture and food consumption 5 4 Individual and collective allowances 6 Usage at international policy level 6 1 United Nations 6 2 European Commission 7 See also 8 References 8 1 Sources 9 External linksFramework overview and principles editThe basic idea of the Planetary Boundaries framework is that maintaining the observed resilience of the Earth system in the Holocene is a precondition for humanity s pursuit of long term social and economic development 9 The Planetary Boundaries framework contributes to an understanding of global sustainability because it brings a planetary scale and a long timeframe into focus 7 The framework described nine planetary life support systems essential for maintaining a desired Holocene state and attempted to quantify how far seven of these systems had been pushed already 6 Boundaries were defined to help define a safe space for human development which was an improvement on approaches aiming at minimizing human impacts on the planet 9 The framework is based on scientific evidence that human actions especially those of industrialized societies since the Industrial Revolution have become the main driver of global environmental change According to the framework transgressing one or more planetary boundaries may be deleterious or even catastrophic due to the risk of crossing thresholds that will trigger non linear abrupt environmental change within continental scale to planetary scale systems 9 The framework consists of nine global change processes In 2009 two boundaries were already crossed while others were in imminent danger of being crossed 6 Later estimates indicated that three of these boundaries climate change biodiversity loss and the biogeochemical flow boundary appear to have been crossed The scientists outlined how breaching the boundaries increases the threat of functional disruption even collapse in Earth s biophysical systems in ways that could be catastrophic for human wellbeing While they highlighted scientific uncertainty they indicated that breaching boundaries could trigger feedbacks that may result in crossing thresholds that drastically reduce the ability to return within safe levels The boundaries were rough first estimates only surrounded by large uncertainties and knowledge gaps which interact in complex ways that are not yet well understood 9 The planetary boundaries framework lays the groundwork for a shifting approach to governance and management away from the essentially sectoral analyses of limits to growth aimed at minimizing negative externalities toward the estimation of the safe space for human development Planetary boundaries demarcate as it were the planetary playing field for humanity if major human induced environmental change on a global scale is to be avoided 7 Authors edit The authors of this framework was a group of Earth System and environmental scientists in 2009 led by Johan Rockstrom from the Stockholm Resilience Centre and Will Steffen from the Australian National University They collaborated with 26 leading academics including Nobel laureate Paul Crutzen Goddard Institute for Space Studies climate scientist James Hansen oceanographer Katherine Richardson geographer Diana Liverman and the German Chancellor s chief climate adviser Hans Joachim Schellnhuber Most of the contributing scientists were involved in strategy setting for the Earth System Science Partnership the precursor to the international global change research network Future Earth The group wanted to define a safe operating space for humanity for the wider scientific community as a precondition for sustainable development Nine boundaries editThresholds and tipping points edit The 2009 study identified nine planetary boundaries and drawing on current scientific understanding the researchers proposed quantifications for seven of them These are climate change CO2 concentration in the atmosphere lt 350 ppm and or a maximum change of 1 W m2 in radiative forcing ocean acidification mean surface seawater saturation state with respect to aragonite 80 of pre industrial levels stratospheric ozone depletion less than 5 reduction in total atmospheric O3 from a pre industrial level of 290 Dobson Units biogeochemical flows in the nitrogen N cycle limit industrial and agricultural fixation of N2 to 35 Tg N yr and phosphorus P cycle annual P inflow to oceans not to exceed 10 times the natural background weathering of P global freshwater use lt 4000 km3 yr of consumptive use of runoff resources land system change lt 15 of the ice free land surface under cropland the erosion of biosphere integrity an annual rate of loss of biological diversity of lt 10 extinctions per million species chemical pollution introduction of novel entities in the environment For one process in the planetary boundaries framework the scientists have not specified a global boundary quantification atmospheric aerosol loading The quantification of individual planetary boundaries is based on the observed dynamics of the interacting Earth system processes included in the framework The control variables were chosen because together they provide an effective way to track the human caused shift away from Holocene conditions For some of Earth s dynamic processes historic data display clear thresholds between comparatively stable conditions For example past ice ages show that during peak glacial conditions the atmospheric concentration of CO2 was 180 200 ppm In interglacial periods including the Holocene CO2 concentration has fluctuated around 280 ppm To know what past climate conditions were like with an atmosphere with over 350 ppm CO2 scientists need to look back about 3 million years The paleo record of climatic ecological and biogeochemical changes shows that the Earth system has experienced tipping points when a very small increment for a control variable like CO2 triggers a larger possibly catastrophic change in the response variable global warming through feedbacks in the natural Earth System itself For several of the processes in the planetary boundaries framework it is difficult to locate individual points that mark the threshold shift away from Holocene like conditions This is because the Earth system is complex and the scientific evidence base is still partial and fragmented Instead the planetary boundaries framework identifies many Earth system thresholds at multiple scales that will be influenced by increases in the control variables 6 Examples include shifts in monsoon behavior linked to the aerosol loading and freshwater use planetary boundaries Planetary Boundaries as defined in 2023 1 Earth systemprocess Control variable 1 Boundaryvalue in 2023 Current value i e for the year provided in the source Boundary nowexceeded beyond the 2023 values based on current value Preindustrial Holocene base value1 Climate change Atmospheric carbon dioxide concentration ppm by volume 10 See also Tipping point climatology 350 417 11 yes 280Total anthropogenic radiative forcing at top of atmosphere W m2 since the start of the industrial revolution 1750 1 0 2 91 11 yes 02 Change in biosphere integrity 1 Genetic diversity Extinction rate measured as E MSY extinctions per million species years lt 10 E MSY but with an aspirational goal of ca 1 E MSY assumed background rate of extinction loss gt 100 E MSY yes 1 E MSYFunctional diversity energy available to ecosystems NPP HANPP HANPP in billion tonnes of C year 1 lt 10 of preindustrial Holocene NPP i e gt 90 remaining for supporting biosphere function 30 HANPP yes 1 9 2s variability of preindustrial Holocene century mean NPP 3 Biogeochemical Phosphate global P flow from freshwater systems into the ocean regional P flow from fertilizers to erodible soils Tg of P year 1 Phosphate global 11 Tg of P year 1 regional 6 2 Tg of P year 1 mined and applied to erodible agricultural soils Global 22 Tg of P year 1 12 regional 17 5 Tg of P year 1 yes 0Nitrogen global industrial and intentional fixation of N Tg of N year 1 62 190 yes 04 Ocean acidification Global mean saturation state of calcium carbonate in surface seawater omega units 2 75 2 8 no 3 445 Land use Part of forests rested intact percent 7 75 from all forests including 85 from Boreal forest 50 from Temperate forests and 85 from Tropical forests 7 Global 60 7 yes 1006 Freshwater change Blue water human induced disturbance of blue water flow Upper limit 95th percentile of global land area with deviations greater than during preindustrial Blue water 10 2 18 2 yes 9 4 Green water human induced disturbance of water available to plants land area with deviations from preindustrial variability 11 1 15 8 yes 9 8 7 Ozone depletion Stratospheric ozone concentration Dobson units 276 284 6 no 2908 Atmospheric aerosols Interhemispheric difference in AOD 0 1 mean annual interhemispheric difference 0 076 no 0 039 Novel entities Percentage of synthetic chemicals released to the environment without adequate safety testing 0 Transgressed yes 0 Safe operating spaces edit The planetary boundaries framework proposes a range of values for its control variables This range is supposed to span the threshold between a safe operating space where Holocene like dynamics can be maintained and a highly uncertain poorly predictable world where Earth system changes likely increase risks to societies The boundary is defined as the lower end of that range If the boundaries are persistently crossed the world goes further into a danger zone 6 It is difficult to restore a safe operating space for humanity that is described by the planetary boundary concept Even if past biophysical changes could be mitigated the predominant paradigms of social and economic development appear largely indifferent to the looming possibilities of large scale environmental disasters triggered by human actions 9 13 Legal boundaries can help keep human activities in check but are only as effective as the political will to make and enforce them 14 Interaction among boundaries edit Understanding the Earth system is fundamentally about understanding interactions among environmental change processes The planetary boundaries are defined with reference to dynamic conditions of the Earth system but scientific discussions about how different planetary boundaries relate to each other are often philosophically and analytically muddled Clearer definitions of the basic concepts and terms might help give clarity There are many many interactions among the processes in the planetary boundaries framework 7 3 While these interactions can create both stabilizing and destabilizing feedbacks in the Earth system the authors suggested that a transgressed planetary boundary will reduce the safe operating space for other processes in the framework rather than expand it from the proposed boundary levels 3 They give the example that the land use boundary could shift downward if the freshwater boundary is breached causing lands to become arid and unavailable for agriculture At a regional level water resources may decline in Asia if deforestation continues in the Amazon That way of framing the interactions shifts from the framework s biophysical definition of boundaries based on Holocene like conditions to an anthropocentric definition demand for agricultural land Despite this conceptual slippage considerations of known Earth system interactions across scales suggest the need for extreme caution in approaching or transgressing any individual planetary boundaries 3 Another example has to do with coral reefs and marine ecosystems In 2009 researchers showed that since 1990 calcification in the reefs of the Great Barrier that they examined decreased at a rate unprecedented over the last 400 years 14 in less than 20 years 15 Their evidence suggests that the increasing temperature stress and the declining ocean saturation state of aragonite is making it difficult for reef corals to deposit calcium carbonate Multiple stressors such as increased nutrient loads and fishing pressure moves corals into less desirable ecosystem states 16 Ocean acidification will significantly change the distribution and abundance of a whole range of marine life particularly species that build skeletons shells and tests of biogenic calcium carbonate Increasing temperatures surface UV radiation levels and ocean acidity all stress marine biota and the combination of these stresses may well cause perturbations in the abundance and diversity of marine biological systems that go well beyond the effects of a single stressor acting alone 17 18 Proposed new or expanded boundaries since 2012 edit In 2012 Steven Running suggested a tenth boundary the annual net global primary production of all terrestrial plants as an easily determinable measure integrating many variables that will give a clear signal about the health of ecosystems 19 20 21 In 2015 a second paper was published in Science to update the Planetary Boundaries concept 7 The update concluded four boundaries had now been transgressed climate biodiversity land use and biogeochemical cycles The 2015 paper emphasized interactions of the nine boundaries and identified climate change and loss of biodiversity integrity as core boundaries of central importance to the framework because the interactions of climate and the biosphere are what scientifically defines Earth system conditions 22 In 2017 some authors argued that marine systems are underrepresented in the framework Their proposed remedy was to include the seabed as a component of the earth surface change boundary They also wrote that the framework should account for changes in vertical mixing and ocean circulation patterns 22 Subsequent work on planetary boundaries begins to relate these thresholds at the regional scale 23 Debate and further research per boundary edit See also List of environmental issues Climate change edit See also Effects of climate change A 2018 study calls into question the adequacy of efforts to limit warming to 2 C above pre industrial temperatures as set out in the Paris Agreement 23 The scientists raise the possibility that even if greenhouse gas emissions are substantially reduced to limit warming to 2 C that might exceed the threshold at which self reinforcing climate feedbacks add additional warming until the climate system stabilizes in a hothouse climate state This would make parts of the world uninhabitable for people raise sea levels by up to 60 metres 200 ft and raise temperatures by 4 5 C 7 2 9 0 F to levels that are higher than any interglacial period in the past 1 2 million years 24 Change in biosphere integrity edit See also Biodiversity loss Deforestation Decline in insect populations and Holocene extinction According to the biologist Cristian Samper a boundary that expresses the probability of families of species disappearing over time would better reflect our potential impacts on the future of life on Earth 25 The biodiversity boundary has also been criticized for framing biodiversity solely in terms of the extinction rate The global extinction rate has been highly variable over the Earth s history and thus using it as the only biodiversity variable can be of limited usefulness 22 Nitrogen and phosphorus edit The biogeochemist William Schlesinger thinks waiting until we near some suggested limit for nitrogen deposition and other pollutions will just permit us to continue to a point where it is too late He says the boundary suggested for phosphorus is not sustainable and would exhaust the known phosphorus reserves in less than 200 years 26 The ocean chemist Peter Brewer queries whether it is truly useful to create a list of environmental limits without serious plans for how they may be achieved they may become just another stick to beat citizens with Disruption of the global nitrogen cycle is one clear example it is likely that a large fraction of people on Earth would not be alive today without the artificial production of fertilizer How can such ethical and economic issues be matched with a simple call to set limits food is not optional 27 Peak phosphorus is a concept to describe the point in time at which the maximum global phosphorus production rate is reached Phosphorus is a scarce finite resource on earth and means of production other than mining are unavailable because of its non gaseous environmental cycle 28 According to some researchers Earth s phosphorus reserves are expected to be completely depleted in 50 100 years and peak phosphorus to be reached by approximately 2030 29 30 Ocean acidification edit Surface ocean acidity is clearly interconnected with the climate change boundaries since the concentration of carbon dioxide in the atmosphere is also the underlying control variable for the ocean acidification boundary 31 The ocean chemist Peter Brewer thinks ocean acidification has impacts other than simple changes in pH and these may need boundaries too 27 Land system change edit Across the planet forests wetlands and other vegetation types are being converted to agricultural and other land uses impacting freshwater carbon and other cycles and reducing biodiversity 31 In the year 2015 the boundary was defined as 75 of forests rested intact including 85 of boreal forests 50 of temperate forests and 85 of tropical forests The boundary is crossed because only 62 of forests rested intact as of the year 2015 7 The boundary for land use has been criticized as follows The boundary of 15 per cent land use change is in practice a premature policy guideline that dilutes the authors overall scientific proposition Instead the authors might want to consider a limit on soil degradation or soil loss This would be a more valid and useful indicator of the state of terrestrial health 32 Freshwater edit The freshwater cycle is another boundary significantly affected by climate change 31 Overexploitation of freshwater occurs if a water resource is mined or extracted at a rate that exceeds the recharge rate Water pollution and saltwater intrusion can also turn much of the world s underground water and lakes into finite resources with peak water usage debates similar to oil 33 34 The hydrologist David Molden stated in 2009 that planetary boundaries are a welcome new approach in the limits to growth debate but said a global limit on water consumption is necessary but the suggested planetary boundary of 4 000 cubic kilometres per year is too generous 35 Green and blue water edit A study concludes that the Freshwater use boundary should be renamed to the Freshwater change composed of green and blue water components 36 Green water refers to disturbances of terrestrial precipitation evaporation and soil moisture 36 Water scarcity can have substantial effects in agriculture 37 38 When measuring and projecting water scarcity in agriculture for climate change scenarios both green water and blue water are of relevance 37 38 In April 2022 scientists proposed and preliminarily evaluated green water in the water cycle as a likely transgressed planetary boundary as measured by root zone soil moisture deviation from Holocene variability 36 additional citation s needed Ozone depletion edit Main article Ozone depletion The stratospheric ozone layer protectively filters ultraviolet radiation UV from the Sun which would otherwise damage biological systems The actions taken after the Montreal Protocol appeared to be keeping the planet within a safe boundary 31 The Nobel laureate in chemistry Mario Molina says five per cent is a reasonable limit for acceptable ozone depletion but it doesn t represent a tipping point 39 Atmospheric aerosols edit Worldwide each year aerosol particles result in about 800 000 premature deaths from air pollution citation needed Aerosol loading is sufficiently important to be included among the planetary boundaries but it is not yet clear whether an appropriate safe threshold measure can be identified 31 Novel entities chemical pollution edit See also Chemical waste nbsp State parties to the Stockholm Convention on Persistent Organic PollutantsSome chemicals such as persistent organic pollutants heavy metals and radionuclides have potentially irreversible additive and synergic effects on biological organisms reducing fertility and resulting in permanent genetic damage Sublethal uptakes are drastically reducing marine bird and mammal populations This boundary seems important although it is hard to quantify 31 8 40 In 2019 it was suggested that novel entities could include genetically modified organisms pesticides and even artificial intelligence 5 A Bayesian emulator for persistent organic pollutants has been developed which can potentially be used to quantify the boundaries for chemical pollution 41 To date critical exposure levels of polychlorinated biphenyls PCBs above which mass mortality events of marine mammals are likely to occur have been proposed as a chemical pollution planetary boundary 42 There are at least 350 000 artificial chemicals in the world They are coming from plastics pesticides industrial chemicals chemicals in consumer products antibiotics and other pharmaceuticals They have mostly negative effects on planetary health Their production increased 50 times since 1950 and is expected to increase 3 times more by 2050 Plastic alone contain more than 10 000 chemicals and create large problems The researchers are calling for limit on chemical production and shift to circular economy meaning to products that can be reused and recycled 43 In January 2022 a group of scientists concluded that this planetary boundary is already exceeded which puts in risk the stability of the Earth system 44 They integrated the literature information on how production and release of a number of novel entities including plastics and hazardous chemicals have rapidly increased in the last decades with significant impact on the planetary processes 8 In August 2022 scientists concluded that the overall transgressed boundary is a placeholder for multiple different boundaries for NEs that may emerge reporting that PFAS pollution is one such new boundary They show that levels of these so called forever chemicals in rainwater are ubiquitously and often greatly above guideline safe levels worldwide 45 46 There are some moves to restrict and replace their use 45 Related concepts editPlanetary integrity edit See also Sustainable Development Goals Weak on environmental sustainability Planetary integrity is also called earth s life support systems or ecological integrity 47 140 Scholars have pointed out that planetary integrity needs to be maintained for long term sustainability 47 140 The current biodiversity loss is threatening ecological integrity on a global scale 47 140 The term integrity refers to ecological health in this context The concept of planetary integrity is interlinked within the concept of planetary boundaries 47 141 An expert Panel on Ecological Integrity in 1998 has defined ecological integrity as follows Ecosystems have integrity when they have their native components plants animals and other organisms and processes such as growth and reproduction intact 48 The Sustainable Development Goals might be able to act as a steering mechanism to address the current loss of planetary integrity 47 142 There are many negative human impacts on the environment that are causing a reduction in planetary integrity 47 142 The Limits to Growth 1972 and Gaia theory edit The idea that there are limits to the burden placed upon our planet by human activities has been around for a long time The Planetary Boundaries framework acknowledges the influence of the 1972 study The Limits to Growth that presented a model in which exponential growth in world population industrialization pollution food production and resources depletion outstrip the ability of technology to increase resources availability 49 Subsequently the report was widely dismissed particularly by economists and business people 50 and it has often been claimed that history has proved the projections to be incorrect 51 In 2008 Graham Turner from the Commonwealth Scientific and Industrial Research Organisation CSIRO published A comparison of The Limits to Growth with thirty years of reality 52 The Limits to Growth has been widely discussed both by critics of the modelling approach and its conclusions 53 54 and by analysts who argue that the insight that societies do not live in an unlimited world and that historical data since the 1970s support the report s findings 55 56 The Limits to Growth approach explores how the socio technical dynamics of the world economy may limit humanity s opportunities and introduce risks of collapse In contrast the Planetary Boundaries framework focuses on the biophysical dynamics of the Earth system 7 Our Common Future was published in 1987 by United Nations World Commission on Environment and Development 57 It tried to recapture the spirit of the Stockholm Conference Its aim was to interlock the concepts of development and environment for future political discussions It introduced the famous definition for sustainable development Development that meets the needs of the present without compromising the ability of future generations to meet their own needs 57 Another key idea influencing the Planetary Boundaries framework is the Gaia theory or hypothesis In the 1970s James Lovelock and microbiologist Lynn Margulis presented the idea that all organisms and their inorganic surroundings on Earth are integrated into a single self regulating system 58 The system has the ability to react to perturbations or deviations much like a living organism adjusts its regulation mechanisms to accommodate environmental changes such as temperature homeostasis Nevertheless this capacity has limits For instance when a living organism is subjected to a temperature that is lower or higher than its living range it can perish because its regulating mechanism cannot make the necessary adjustments Similarly the Earth may not be able to react to large deviations in critical parameters 7 In Lovelock s book The Revenge of Gaia he suggests that the destruction of rainforests and biodiversity compounded with global warming resulting from the increase of greenhouse gases made by humans could shift feedbacks in the Earth system away from a self regulating balance to a positive intensifying feedback loop Anthropocene edit Main article AnthropoceneFrom the Stockholm MemorandumScience indicates that we are transgressing planetary boundaries that have kept civilization safe for the past 10 000 years Evidence is growing that human pressures are starting to overwhelm the Earth s buffering capacity Humans are now the most significant driver of global change propelling the planet into a new geological epoch the Anthropocene We can no longer exclude the possibility that our collective actions will trigger tipping points risking abrupt and irreversible consequences for human communities and ecological systems Stockholm Memorandum 2011 Scientists have affirmed that the planet has entered a new epoch the Anthropocene 59 In the Anthropocene humans have become the main agents of not only change to the Earth System 60 but also the driver of Earth System rupture 61 disruption of the Earth System s ability to be resilient and recover from that change potentially ultimately threatening planetary habitability The previous geological epoch the Holocene began about 10 000 years ago It is the current interglacial period and was a relatively stable environment of the Earth There have been natural environmental fluctuations during the Holocene but the key atmospheric and biogeochemical parameters have remained within relatively narrow bounds 62 This stability has allowed societies to thrive worldwide developing agriculture large scale settlements and complex networks of trade 63 According to Rockstrom et al we have now become so dependent on those investments for our way of life and how we have organized society technologies and economies around them that we must take the range within which Earth System processes varied in the Holocene as a scientific reference point for a desirable planetary state 9 Various biophysical processes that are important in maintaining the resilience of the Earth system are also undergoing large and rapid change because of human actions 64 For example since the advent of the Anthropocene the rate at which species are going extinct has increased over 100 times 65 and humans are now the driving force altering global river flows 66 as well as water vapor flows from the land surface 67 Continuing perturbation of Earth system processes by human activities raises the possibility that further pressure could be destabilizing leading to non linear abrupt large scale or irreversible environmental change responses by the Earth system within continental to planetary scale systems 7 Reception and debate editSee also Debate and further research per boundary In summary the planetary boundary concept is a very important one and its proposal should now be followed by discussions of the connections between the various boundaries and of their association with other concepts such as the limits to growth Importantly this novel concept highlights the risk of reaching thresholds or tipping points for non linear or abrupt changes in Earth system processes As such it can help society to reach the agreements required for dealing effectively with existing global environmental threats such as climate change Nobel laureate Mario J Molina 39 The 2009 report 3 was presented to the General Assembly of the Club of Rome in Amsterdam 68 An edited summary of the report was published as the featured article in a special 2009 edition of Nature 2 alongside invited critical commentary from leading academics like Nobel laureate Mario J Molina and biologist Cristian Samper 39 Development studies scholars have been critical of aspects of the framework and constraints that its adoption could place on the Global South Proposals to conserve a certain proportion of Earth s remaining forests can be seen as rewarding the countries such as those in Europe that have already economically benefitted from exhausting their forests and converting land for agriculture In contrast countries that have yet to industrialize are asked to make sacrifices for global environmental damage they may have had little role in creating 22 The biogeochemist William Schlesinger queries whether thresholds are a good idea for pollutions at all He thinks waiting until we near some suggested limit will just permit us to continue to a point where it is too late Management based on thresholds although attractive in its simplicity allows pernicious slow and diffuse degradation to persist nearly indefinitely 26 In a global empirical study researchers investigated how students of environmental and sustainability studies in 35 countries assessed the planetary boundaries It was found that there are substantial global differences in the perception of planetary boundaries 69 Subsequent developments editThe safe and just space doughnut edit nbsp Doughnut economic model This section is an excerpt from Doughnut economic model edit The Doughnut or Doughnut economics is a visual framework for sustainable development shaped like a doughnut or lifebelt combining the concept of planetary boundaries with the complementary concept of social boundaries 70 The name derives from the shape of the diagram i e a disc with a hole in the middle The centre hole of the model depicts the proportion of people that lack access to life s essentials healthcare education equity and so on while the crust represents the ecological ceilings planetary boundaries that life depends on and must not be overshot 71 The diagram was developed by University of Oxford economist Kate Raworth in her 2012 Oxfam paper A Safe and Just Space for Humanity and elaborated upon in her 2017 book Doughnut Economics Seven Ways to Think Like a 21st Century Economist and paper 72 The framework was proposed to regard the performance of an economy by the extent to which the needs of people are met without overshooting Earth s ecological ceiling 73 The main goal of the new model is to re frame economic problems and set new goals In this context the model is also referred to as a wake up call to transform our capitalist worldview 74 In this model an economy is considered prosperous when all twelve social foundations are met without overshooting any of the nine ecological ceilings This situation is represented by the area between the two rings considered by its creator as a safe and just space for humanity 75 National environmental footprints edit Several studies have assessed environmental footprints of nations based on planetary boundaries for Portugal 76 Sweden 77 Switzerland 78 the Netherlands 79 the European Union 80 India 81 82 many of Belt and Road Initiative countries 83 as well as for the world s most important economies 84 85 While the metrics and allocation approaches applied varied there is a converging outcome that resource use of wealthier nations if extrapolated to world population is not compatible with planetary boundaries Boundaries related to agriculture and food consumption edit nbsp Visualization of the planetary boundaries related to agriculture and nutrition 86 Human activities related to agriculture and nutrition globally contribute to the transgression of four out of nine planetary boundaries Surplus nutrient flows N P into aquatic and terrestrial ecosystems are of highest importance followed by excessive land system change and biodiversity loss Whereas in the case of biodiversity loss P cycle and land system change the transgression is in the zone of uncertainty indicating an increasing risk yellow circle in the figure the N boundary related to agriculture is more than 200 transgressed indicating a high risk red marked circle in the figure Here nutrition includes food processing and trade as well as food consumption preparation of food in households and gastronomy Consumption related environmental impacts are not quantified at the global level for the planetary boundaries of freshwater use atmospheric aerosol loading air pollution and stratospheric ozone depletion 86 Individual and collective allowances edit Approaches based on a general framework of ecological limits include transferable personal carbon allowances and legislated national greenhouse gas emissions limits 87 Consumers would have freedom in their informed choice within the collective boundaries 88 Usage at international policy level editUnited Nations edit The United Nations secretary general Ban Ki moon endorsed the concept of planetary boundaries on 16 March 2012 when he presented the key points of the report of his High Level Panel on Global Sustainability to an informal plenary of the UN General Assembly 89 Ban stated The Panel s vision is to eradicate poverty and reduce inequality to make growth inclusive and production and consumption more sustainable while combating climate change and respecting a range of other planetary boundaries 90 The concept was incorporated into the so called zero draft of the outcome of the United Nations Conference on Sustainable Development to be convened in Rio de Janeiro 20 22 June 2012 91 However the use of the concept was subsequently withdrawn from the text of the conference partly due to concerns from some poorer countries that its adoption could lead to the sidelining of poverty reduction and economic development It is also say observers because the idea is simply too new to be officially adopted and needed to be challenged weathered and chewed over to test its robustness before standing a chance of being internationally accepted at UN negotiations 92 In 2011 at their second meeting the High level Panel on Global Sustainability of the United Nations had incorporated the concept of planetary boundaries into their framework stating that their goal was To eradicate poverty and reduce inequality make growth inclusive and production and consumption more sustainable while combating climate change and respecting the range of other planetary boundaries 93 Elsewhere in their proceedings panel members have expressed reservations about the political effectiveness of using the concept of planetary boundaries Planetary boundaries are still an evolving concept that should be used with caution The planetary boundaries question can be divisive as it can be perceived as a tool of the North to tell the South not to follow the resource intensive and environmentally destructive development pathway that rich countries took themselves This language is unacceptable to most of the developing countries as they fear that an emphasis on boundaries would place unacceptable brakes on poor countries 94 However the concept is routinely used in the proceedings of the United Nations 95 and in the UN Daily News For example the United Nations Environment Programme UNEP Executive Director Achim Steiner states that the challenge of agriculture is to feed a growing global population without pushing humanity s footprint beyond planetary boundaries 96 The UNEP Yearbook 2010 also repeated Rockstrom s message conceptually linking it with ecosystem management and environmental governance indicators 97 In their 2012 report entitled Resilient People Resilient Planet A future worth choosing The High level Panel on Global Sustainability called for bold global efforts including launching a major global scientific initiative to strengthen the interface between science and policy We must define through science what scientists refer to as planetary boundaries environmental thresholds and tipping points 98 European Commission edit The planetary boundaries concept is also used in proceedings by the European Commission 99 100 and was referred to 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2016 retrieved 29 June 2017 United Nations High level Panel on Global Sustainability April 2011 Meeting Report PDF Report of the meeting of the GSP Sherpas held in Madrid Spain 13 14 April 2011 archived PDF from the original on 4 March 2016 retrieved 29 June 2017 United Nations High level Panel on Global Sustainability 2012 Resilient People Resilient Planet A future worth choosing PDF Report New York United Nations Archived PDF from the original on 8 February 2012 Retrieved 30 January 2012 van Vuuren D P Faber A 2009 Growing within Limits A Report to the Global Assembly 2009 of the Club of Rome PDF Netherlands Environmental Assessment Agency ISBN 978 90 6960 234 9 Zalasiewicz J Williams M Steffen W Crutzen P 2010 The New World of the Anthropocene PDF Environmental Science amp Technology 44 7 2228 2231 Bibcode 2010EnST 44 2228Z doi 10 1021 es903118j hdl 1885 36498 PMID 20184359 archived PDF from the original on 2 October 2011 retrieved 11 July 2011External links edit nbsp Wikimedia Commons has media related to Planetary boundaries Figures and data for the updated Planetary Boundaries can be found at the Stockholm Resilience Centre website Planetary Boundaries Specials Nature 24 September 2009 Johan Rockstrom Let the environment guide our development TED video July 2010 Transcript html The Planetary Boundaries and what they mean for the Future of Humanity on YouTube Portals nbsp Environment nbsp Ecology nbsp Earth sciences nbsp Biology Retrieved from https en wikipedia org w index php title Planetary boundaries amp oldid 1193546895, wikipedia, wiki, book, books, library,

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