Expanded Explanatin of the Key Climate Feedback Loops Fueling the Amazon Collapse

The Interactions Among the Albedo Feedback Loop, Brown Carbon Feedback Loop, Freshwater-AMOC Disruption Loop, Permafrost-Methane Feedback Loop, Amazon Rainforest Dieback Feedback Loop, Sudden Sea Level Rise Pulses ("Cork Release" Events), Hydroclimate Whiplash, and Arctic Sea Ice Feedback

by Daniel Brouse and Sidd Mukherjee
July 16, 2025

Introduction

The Interaction of: Albedo Feedback Loop, Brown Carbon Feedback Loop, Freshwater-AMOC Disruption Loop, Permafrost-Methane Feedback Loop, Amazon Rainforest Dieback Feedback Loop, Sudden Sea Level Rise Pulses ("Cork Release" Events), Hydroclimate Whiplash, and Arctic Sea Ice Feedback

Combined Consequences

These interlinked, reinforcing feedbacks can:
* Drive non-linear, abrupt climate shifts.
* Cause sudden sea level pulses (feet/year for consecutive years).
* Collapse AMOC and disrupt weather, food systems, and rainfall patterns.
* Trigger Amazon dieback, increasing global CO2.
* Result in mass displacement, famine, and water crises.

Research and Development Incorporating Complex Social-Ecological Feedback Loops Within a Dynamic, Non-Linear System is an extremely complex subject. A small example of this complexity can be seen in the interaction of the Albedo Feedback Loop, Brown Carbon Feedback Loop, Freshwater-AMOC Disruption Loop, Permafrost-Methane Feedback Loop, Amazon Rainforest Dieback Feedback Loop, Sudden Sea Level Rise Pulses ("Cork Release" Events), Hydroclimate Whiplash, and Arctic Sea Ice Feedback.

Lately, my deep reflection has centered on how tipping points have triggered self-sustaining feedback loops within the climate system. We knew this was coming--and now it is here. I was prepared for that part.

What I could not fully envision was how quickly the interplay of these tipping points would ignite a domino effect--so, so fast.

Now, I can see it clearly: the nonlinear, dynamic dance of economic, physical, and ecological systems in real time. This is pure math and science visibly unfolding, transforming abstract models into undeniable, measurable reality.

I've been reflecting further on the collapse of Atlantic currents and want to share another angle. The breakdown of these subsystems will not follow a smooth, linear decline. As one subsystem fails, it accelerates the failure of others, creating cascading, compounding effects within the climate system. There are too many interconnected subsystems to count, but let's consider one example involving AMOC collapse and sea level rise.

We can start with the "albedo" feedback loop: as ice melts, it exposes darker surfaces, which absorb more heat, warming the surface further, and causing even more ice to melt. When this happens with sea ice, it increases ocean temperatures, which can affect the AMOC, but it doesn't directly raise sea levels.

Land ice, however, is far more concerning. The albedo feedback loop accelerates glacier melt in Greenland and Antarctica, which not only raises sea levels but also changes the temperature and salinity of the ocean, having a much more direct and significant impact on the AMOC's stability.

Many people don't realize that Greenland and Antarctica contain giant "corks" holding back enormous quantities of fresh water in the form of ice and meltwater lakes. These corks, created by the underlying topography and ice dams, are precarious. For example, Greenland is shaped like a bowl, with meltwater pooling inside it. Once these corks break, we could see sudden pulses of sea level rise--potentially 1-3 feet per year for several consecutive years.

At that point, we truly do not know what will happen to the AMOC and other climate systems, as nothing like this has occurred within human history. What is clear is that as these cascading, nonlinear feedback loops accelerate, the climate system will become increasingly unstable, with each tipping point amplifying the next. We could likely see this within the next 50 years.

East Antarctic Ice Sheet Collapse: The Largest Unknown

An even larger, deeply unsettling unknown is the potential collapse of the East Antarctic Ice Sheet (EAIS)--a colossal risk with consequences we can barely begin to model. The EAIS holds the largest single store of ice on the planet, containing enough to raise global sea levels by over 170 feet if fully destabilized.

But what happens when it begins to go? Will it gradually slide off over centuries, or could destabilization occur much faster, driven by warming oceans, ice cliff instabilities, and subglacial melt? Could sections of the ice sheet collapse abruptly, displacing massive volumes of water and triggering tsunamis? How quickly would sea levels rise simply from displacement alone, before the ice even begins to melt in the ocean?

We do not yet know exactly how this will unfold, but it is likely we will witness the early stages within the next 100 years, if not sooner. Could this result in the fastest sea level rise in human history? It is not out of the question.

Sidd Mukherjee's Perspective: Context and Probabilities

Sidd Mukherjee replied with his characteristically precise perspective:

"Mmmm… how long is ‘ever'? I don't think there is enough ice globally to do more than ~200 feet of sea level rise total."

He estimates:

• Greenland: Effectively lost, will melt in place over 100-300 years, raising sea levels by ~20 feet.

• West Antarctica: Also lost, could collapse rapidly--within decades to a century--adding ~10 feet.

• Combined, this suggests ~20-30 feet of sea level rise over the next century, translating to an average of ~2 inches per year (10x the current rate).

However, Sidd highlights the pulse nature of collapse:

"We could dawdle along at half an inch a year, then see a few years at a foot per year."

The wildcard is the East Antarctic Ice Sheet. If we manage to hold atmospheric CO2 equivalents to ~500 ppm, it may remain largely stable. But if destabilized, it could eventually contribute another 170-200 feet of sea level rise, with catastrophic consequences for coastal cities, food systems, and global infrastructure.

What is the AMOC?

The Atlantic Meridional Overturning Circulation (AMOC) is a system of ocean currents, including the Gulf Stream, that transports warm, salty surface water northward and cold, dense water southward at depth. It is critical for:

• Regulating regional climates (e.g., warming Europe)

• Distributing heat across the planet

• Driving the global nutrient cycle.

How melting Greenland land ice affects the AMOC

Freshwater Injection Reduces Salinity

• Greenland's glaciers and ice sheet are land ice, so when they melt, they add freshwater directly into the North Atlantic.

• This reduces the salinity and density of surface waters, making them less likely to sink in the North Atlantic (the "engine" of the AMOC).

Sea Level Rise and Pressure Changes

• Melting ice increases local sea level in the North Atlantic, which can reduce vertical mixing and stratify the water column, further weakening the sinking mechanism.

• It also changes pressure gradients across the Atlantic, potentially altering current speeds.

Cooling of Surface Waters

• Melting ice cools local sea surface temperatures near Greenland, which can at first counteract warming, but if the surface water is too fresh, it still won't sink even if cooled.

Gravitational Redistribution ("Water Pull")

• Greenland's ice mass exerts gravitational pull on surrounding water. As Greenland loses mass, water is pulled away toward the equator, which raises sea levels in the Southern Hemisphere and equatorial regions while initially lowering local sea level near Greenland. This redistribution can alter ocean current patterns and the AMOC's stability.

How Antarctica's melt impacts the AMOC indirectly

Southern Freshwater Input

• Antarctic land ice melt primarily affects the Southern Ocean, reducing salinity and potentially impacting the formation of Antarctic Bottom Water, which feeds into global deep ocean currents.

Global Sea Level Rise

• As Antarctic land ice melts, global sea levels rise, subtly changing pressure balances and stratification patterns across ocean basins, including the Atlantic.

Equatorial Water Pull

• Like Greenland, Antarctica's mass loss reduces its gravitational pull on water, causing water to redistribute away from Antarctica toward the equator, raising sea levels in equatorial regions.

Combined Impact on the AMOC

• Stratification & Reduced Sinking: Freshwater from Greenland (and eventually Antarctica's indirect influence) leads to less dense surface waters in the North Atlantic, preventing sinking and weakening the AMOC.

• Altered Heat Distribution: A weakened AMOC means less warm water is transported north, leading to regional cooling in Europe but potential warming of tropical Atlantic waters.

• Feedback Loops: Weakened AMOC can affect precipitation patterns, Arctic sea ice melt, and storm tracks, which can further influence ice melt, creating feedback loops.

Why it matters

If the AMOC weakens significantly or collapses:

• Europe may face extreme cold spells despite global warming.

• Tropical regions may see intensified storms and heatwaves.

• Global weather patterns could shift abruptly.

• Marine ecosystems would be disrupted by changes in nutrient and heat distribution.

The melting of Greenland and Antarctica's land ice is thus not only a driver of sea level rise but a key destabilizer of Earth's climate regulation systems like the AMOC, with cascading impacts on global habitability.

How Arctic and Antarctic Melting Accelerate Amazon Rainforest Dieback

The Feedback Loops In Motion

Albedo Effect & Ice Melt

• As Arctic and Antarctic ice melts, darker ocean/land surfaces are exposed, absorbing more solar energy.

• This accelerates local and global warming, leading to faster ice melt in Greenland and Antarctica.

• Ice melt increases sea level rise and changes ocean salinity, contributing to AMOC weakening.

AMOC Slowing

• The AMOC distributes heat globally; when it slows due to freshwater from melting ice, it disrupts weather patterns:

  • Alters rainfall distribution in the tropics.

  • Contributes to regional drying in the Amazon basin.

  • Shifts the Intertropical Convergence Zone (ITCZ), which impacts the Amazon's rainfall cycles.

Impacts on the Amazon Rainforest

Reduced Rainfall & Longer Droughts

• The Amazon depends on consistent rainfall, much of which it recycles itself.

• AMOC weakening and altered tropical rainfall patterns reduce moisture transport into the basin, increasing the frequency and severity of droughts.

Higher Temperatures

• Global and regional warming driven by greenhouse gases and the albedo feedback increase surface temperatures in the Amazon.

• Higher temperatures increase evaporation and plant stress, compounding drought impacts.

Storm Pattern Changes

• Shifting storm tracks can:

  • Decrease rainfall in the Amazon.

  • Increase extreme weather events, leading to tree damage and forest vulnerability.

Hydroclimate Whiplash

Hydroclimate whiplash--the rapid swings between extreme drought and intense rainfall--creates a destructive feedback loop accelerating Amazon dieback. Droughts stress trees, leading to increased mortality, while intense rains after droughts can erode nutrient-poor soils and wash away organic matter before it can contribute to healthy regrowth. In the Amazon, these rapid shifts weaken the forest's resilience, leading to more vegetation death, less transpiration, and therefore less rainfall, perpetuating the cycle. As trees die and decompose during prolonged droughts, they release more carbon into the atmosphere, intensifying global warming and further drying conditions that continue to reduce rainfall across the basin. This dynamic is critical in the context of the Rio Negro, whose black waters are rich in dissolved organic carbon (DOC) sourced from forest soils and decaying vegetation. Under normal rainfall conditions, much of this DOC is flushed toward the ocean, aiding in long-term carbon sequestration as the carbon sinks to the seafloor. However, record-low river levels in 2023 due to drought reduced this export, while exposing more DOC to photo-oxidation under intense sunlight, leading to additional CO2 emissions. As the Rio Negro and Amazon Rivers continue to experience these unprecedented drought conditions, they serve as a case study for how hydroclimate whiplash, Amazon dieback, and disruptions in the carbon cycle may interact with broader climate systems, including the slowing or collapse of the AMOC, underscoring the interconnected risks we now face.

Positive Feedback: Drought → Fire → Dieback

Drought & Heat Stress:

• Stressed trees close stomata, reducing CO2 uptake and weakening forest resilience.

• Warmer, drier conditions make forests more flammable.

Fire & Mortality:

• Drought conditions lead to more frequent and intense forest fires.

• Fires release stored carbon, turning the Amazon from a carbon sink to a carbon source.

Ozone Poisoning:

• Ozone pollution, driven by fossil fuel combustion, further reduces plant CO2 uptake, compounding forest decline.

Brown Carbon from Wildfires

• As climate change and droughts increase wildfires globally (including in the Amazon, boreal forests, and other regions), they produce "brown carbon" (light-absorbing organic particles) that travel via wind currents.

• When this brown carbon settles on snow and ice in Greenland, Antarctica, and mountain glaciers, it darkens the ice surface, reducing reflectivity (albedo), causing faster melting

Carbon Feedback Loop:

• Dying and burning forests release CO2, further warming the planet, which accelerates polar ice melt and deepens the AMOC slowdown, feeding back into the cycle.

Why It Matters

The Amazon dieback is not an isolated crisis:

• It is tied to polar processes through atmospheric and oceanic feedback loops.

• It represents a tipping point where global systems interact, pushing each other toward collapse.

Without rapid fossil fuel reduction, the interconnected:

• Albedo feedback,

• Ice melt and sea level rise,

• AMOC slowdown,

• and Amazon drought-fire-carbon feedback

will accelerate the collapse of one of Earth's most critical climate regulators, impacting global food systems, weather stability, and habitability.