#climate system

Have you ever thought about how dinosaurs lived on a warm, swampy Earth and how we live on one that’s cold enough to keep pretty much the entirety of Greenland and Antarctica buried under kilometers-thick sheets of solid ice and wondered, hmm, how did we get from there to here? The short answer is that it took 50 million years of declining atmospheric carbon dioxide concentrations and dropping temperatures, not to mention building an ice sheet or two. For the longer story of the last 50 million years of climate change, including some of the reasons why, catch this episode of our podcast with Dr De La Rocha! You’ll hear about plate tectonics and continental drift, silicate weathering, carbonate sedimentation, and the spectacular effects the growth of Earth’s ice sheets have had on Earth’s climate. There are also lessons here for where anthropogenic global warming is going and whether or not its effects have permanently disrupted the climate system. Fun fact: the total amount of climate change between 50 million years ago and now dwarfs what we’re driving by burning fossil fuels, and yet, what we’re doing is more terrifying, in that it’s unfolding millions of times faster.

Bonus content: If you want to see sketches and plots of the data discussed in this episode, you can do so here!

!!Nerd alert!! 

If you're interested in the primary scientific literature on the subject, these four papers are a great place to start.

Dutkiewicz et al (2019) Sequestration and subduction of deep-sea carbonate in the global ocean since the Early Cretaceous. Geology 47:91-94.

Müller et al (2022) Evolution of Earth’s plate tectonic conveyor belt. Nature 605:629–639.

Rae et al (2021) Atmospheric CO2 over the last 66 million years from marine archives. Annual Review of Earth and Planetary Sciences 49:609-641.

Westerfeld et al (2020) An astronomically dated record of Earth’s climate and its predictability over the last 66 million years. Science 369: 1383–1387.

Connect with Christina at her blog, on Twitter, and on Mastodon

“New research from West Virginia University biologists shows that trees around the world are consuming more carbon dioxide than previously reported, making forests even more important in regulating the Earth's atmosphere and forever shift how we think about climate change.

They found that increases in carbon dioxide in the atmosphere over the past century have caused an uptick in trees' water-use efficiency, the ratio of carbon dioxide taken up by photosynthesis to the water lost by transpiration—the act of trees "breathing out" water vapor.

Tipping points in the climate system refer to critical thresholds at which a small change in external conditions can lead to a significant and often irreversible change in the state of the system. These are moments when the climate can shift from one stable state to another, often with profound and potentially catastrophic consequences for ecosystems, biodiversity, and human societies. Understanding these tipping points is crucial for predicting and mitigating the impacts of climate change. Here are several key aspects and examples:

1. Definition and Importance

A tipping point in the climate system is a point at which a relatively small change can lead to a significant shift in the behavior or condition of the system. This concept is critical because it implies that gradual changes in variables such as temperature or carbon dioxide levels can suddenly trigger rapid and possibly irreversible shifts in the Earth's climate.

2. Examples of Tipping Points

Melting of the Greenland and West Antarctic Ice Sheets: Significant melting of these ice sheets could lead to several meters of sea-level rise, affecting millions of people living in coastal areas.

Dieback of the Amazon Rainforest: Changes in rainfall patterns, combined with deforestation, could transform the rainforest into a savannah, releasing vast amounts of stored carbon dioxide.

Disruption of the Atlantic Meridional Overturning Circulation (AMOC): This ocean current plays a crucial role in regulating the climate by distributing heat globally. A slowdown or halt could lead to cooler temperatures in Europe, more extreme weather, and rising sea levels on the East Coast of the U.S.

Permafrost Thaw: Warming temperatures can cause permafrost to thaw, releasing methane, a potent greenhouse gas, and further accelerating global warming.

3. Mechanisms and Feedback Loops

Tipping points often involve feedback loops that can either amplify or dampen the effects of climate change. Positive feedback loops, such as the release of methane from thawing permafrost, can accelerate warming and push the system closer to a tipping point. Negative feedback loops, on the other hand, can stabilize the system and prevent it from reaching a tipping point.

4. Uncertainty and Research

Predicting when tipping points will occur is challenging due to the complexity of climate systems and the interplay of various factors. Researchers use climate models, historical data, and observations to estimate thresholds and potential impacts, but there remains significant uncertainty.

5. Implications for Policy and Action

Understanding and identifying tipping points is crucial for climate policy and action. It underscores the urgency of reducing greenhouse gas emissions to avoid reaching these critical thresholds. International efforts, like the Paris Agreement, aim to limit global warming to well below 2°C above pre-industrial levels to reduce the risk of crossing tipping points.

6. Adaptation and Resilience

In addition to mitigation efforts, building resilience and adapting to changes are essential strategies, especially for communities most at risk. This includes investing in sustainable infrastructure, protecting natural carbon sinks, and developing early warning systems for extreme weather events.

In conclusion, tipping points in the climate system represent a significant area of concern within the broader context of global climate change. They highlight the non-linear and interconnected nature of climate impacts, emphasizing the need for prompt and decisive action to safeguard the planet for future generations.

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i wonder Mechanisms and Feedback Loops ChatGPT

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The mechanisms and feedback loops in the climate system play crucial roles in determining the Earth's climate and its responses to external forces, such as greenhouse gas emissions. These feedback loops can either amplify (positive feedback) or dampen (negative feedback) the effects of climate changes, and understanding them is essential for accurately predicting climate dynamics. Here's a deeper look into how these mechanisms and feedback loops work:

Positive Feedback Loops

Positive feedback loops accelerate a process or change. In the context of climate change, they can lead to a self-reinforcing cycle of warming.

Ice-Albedo Feedback: This is a classic example where melting ice reduces the Earth's albedo (reflectivity). Ice and snow reflect more sunlight than open water or bare ground. As ice melts, less sunlight is reflected back into space, increasing the absorption of heat and causing further warming and melting. This feedback loop can lead to faster and more extensive melting of ice in polar regions.

Water Vapor Feedback: Water vapor is a potent greenhouse gas. As the atmosphere warms, it can hold more water vapor, which in turn traps more heat and leads to further warming. This is the most significant feedback mechanism in the climate system and amplifies the warming effect of CO2 and other greenhouse gases.

Permafrost Thawing: Warming temperatures can thaw frozen permafrost, releasing stored methane (CH4) and carbon dioxide (CO2) into the atmosphere. Since methane is a much more potent greenhouse gas than CO2, this can significantly amplify global warming, leading to more permafrost thawing and greenhouse gas release.

Negative Feedback Loops

Negative feedback loops work to stabilize the climate system by counteracting changes, either cooling the planet in response to warming or vice versa.

Increased Plant Growth: Higher concentrations of CO2 in the atmosphere can enhance plant growth in some regions, a process known as CO2 fertilization. More plant growth can increase the amount of CO2 absorbed from the atmosphere, potentially mitigating some effects of climate change. However, this process is limited by other factors like nutrient availability and water supply.

Weathering of Rocks: This long-term process involves the chemical breakdown of rocks on the Earth's surface, a reaction that consumes CO2 from the atmosphere. Increased CO2 levels can accelerate weathering, thus removing CO2 from the atmosphere and acting as a slow, stabilizing feedback over thousands to millions of years.

Interactions and Implications

The climate system's feedback loops are interconnected, and their impacts can vary geographically and temporally. Positive feedback loops are particularly concerning in the context of climate change because they can lead to tipping points, where the climate system shifts to a new state after crossing certain thresholds.

Understanding these feedback mechanisms is critical for developing accurate climate models, which are used to predict future climate conditions and inform policy decisions. It also highlights the importance of rapid action to reduce greenhouse gas emissions, as delaying action could activate positive feedbacks that make it much harder to control warming.

Tipping points in the climate system refer to critical thresholds at which a small change in external conditions can lead to a significant and often irreversible change in the state of the system. These are moments when the climate can shift from one stable state to another, often with profound and potentially catastrophic consequences for ecosystems, biodiversity, and human societies. Understanding these tipping points is crucial for predicting and mitigating the impacts of climate change. Here are several key aspects and examples:

1. Definition and Importance

A tipping point in the climate system is a point at which a relatively small change can lead to a significant shift in the behavior or condition of the system. This concept is critical because it implies that gradual changes in variables such as temperature or carbon dioxide levels can suddenly trigger rapid and possibly irreversible shifts in the Earth's climate.

2. Examples of Tipping Points

Melting of the Greenland and West Antarctic Ice Sheets: Significant melting of these ice sheets could lead to several meters of sea-level rise, affecting millions of people living in coastal areas.

Dieback of the Amazon Rainforest: Changes in rainfall patterns, combined with deforestation, could transform the rainforest into a savannah, releasing vast amounts of stored carbon dioxide.

Disruption of the Atlantic Meridional Overturning Circulation (AMOC): This ocean current plays a crucial role in regulating the climate by distributing heat globally. A slowdown or halt could lead to cooler temperatures in Europe, more extreme weather, and rising sea levels on the East Coast of the U.S.

Permafrost Thaw: Warming temperatures can cause permafrost to thaw, releasing methane, a potent greenhouse gas, and further accelerating global warming.

3. Mechanisms and Feedback Loops

Tipping points often involve feedback loops that can either amplify or dampen the effects of climate change. Positive feedback loops, such as the release of methane from thawing permafrost, can accelerate warming and push the system closer to a tipping point. Negative feedback loops, on the other hand, can stabilize the system and prevent it from reaching a tipping point.

4. Uncertainty and Research

Predicting when tipping points will occur is challenging due to the complexity of climate systems and the interplay of various factors. Researchers use climate models, historical data, and observations to estimate thresholds and potential impacts, but there remains significant uncertainty.

5. Implications for Policy and Action

Understanding and identifying tipping points is crucial for climate policy and action. It underscores the urgency of reducing greenhouse gas emissions to avoid reaching these critical thresholds. International efforts, like the Paris Agreement, aim to limit global warming to well below 2°C above pre-industrial levels to reduce the risk of crossing tipping points.

6. Adaptation and Resilience

In addition to mitigation efforts, building resilience and adapting to changes are essential strategies, especially for communities most at risk. This includes investing in sustainable infrastructure, protecting natural carbon sinks, and developing early warning systems for extreme weather events.

Remarkable new observation and modelling technologies continue to develop, helping advance understanding of the Earth’s complex global weather and climate system. As a result, today’s five-day forecasts are as reliable as the two-day forecast of 25 years ago. These advances translate into literally billions of dollars in economic gains. 

“If we want to forecast weather we have to understand clouds. If we want to model the climate system we have to understand clouds. And if we want to predict the availability of water resources, we have to understand clouds,”

World Meteorological Organization (WMO) Secretary-General Petteri Taalas.