What real-world constraints increase the risk of SAI compared with model assumptions?

Real-world constraints include materials, manufacturing, transport, and governance limits that aren’t captured in idealized models. SAI requires sub‑micron particles with precise optical properties; many candidate minerals clump, forming aggregates that scatter light unpredictably. Some alternatives (titanium dioxide, diamond dust) are scarce or costly at needed scales. Injection logistics—where, when, altitude, and rate—also change particle lifetime and atmospheric transport, altering outcomes.

How could deployment of SAI affect climate and politics?

Deployment could disrupt regional rainfall, monsoon patterns, and ozone chemistry, even with careful targeting, as altitude and latitude changes alter transport and residence time. Politically, benefits and harms may be uneven, sparking disputes over responsibility and compensation, while strategic competition raises risks of unilateral or dual-use actions, making governance of a truly global weather intervention highly fragile.

What is termination shock and why is it worrisome?

Termination shock refers to a rapid warming spike that would occur if a long‑running SAI program were suddenly stopped. While greenhouse gases remain in the atmosphere, removing the cooling effect could unleash abrupt climate rebound, potentially causing rapid warming that would be harder to adapt to than the gradual changes that preceded the intervention.

What should policymakers take away regarding SAI and climate strategy?

The Columbia study argues that published modelling often understates real‑world constraints, and that SAI is not a substitute for emissions reductions or carbon removal. Policy should emphasize reducing greenhouse gases, investing in removal technologies, and building multilateral institutions to manage global commons, while recognizing that safe, reliable deployment would require extraordinary coordination and acceptance of significant risks.

Dimming the Sun Could Spark Global Chaos: Practical Limits Make Solar Geoengineering Far More Risky Than Models Suggest

Environment By Mattias Risberg Nov 16, 2025 18:03

A Columbia University team finds that real-world engineering, supply-chain and governance limits make stratospheric aerosol injection far less predictable — and far more dangerous — than models imply. Their analysis suggests regional climate disruption, material shortages and political fragmentation could turn a quick climate fix into a global crisis.

Why the idea of "dimming the sun" has moved from fringe to front-page debate

Spraying particles high into the stratosphere to reflect sunlight — a family of techniques known as solar geoengineering or solar radiation management — has long been discussed as a theoretical stopgap to cool the planet quickly. The idea borrows from nature: large volcanic eruptions inject sulfate aerosols into the stratosphere and have temporarily lowered global temperatures for a few years. That apparent simplicity has made stratospheric aerosol injection (SAI) an alluring option for policy makers and scientists worried about rapid warming.

But models often assume a perfect world

Most climate-model studies of SAI assume an idealized operation: perfectly sized particles, injected in precisely the right place, at the right altitude, and maintained year after year. New research from a Columbia University team, published in Scientific Reports in October 2025, argues those assumptions leave out a long list of messy, real‑world constraints. When the nitty-gritty of materials, manufacturing, transport, dispersal and politics are folded into the picture, the range of plausible outcomes broadens — in ways that could be destabilizing for societies and ecosystems.

From nanometres to nations: the practical barriers researchers flagged

Particle physics matters. To scatter sunlight efficiently without causing unwanted heating or chemical side‑effects, SAI particles generally need to be extremely small (sub‑micron) and have specific optical properties. Many candidate minerals tend to clump together during storage and dispersal, forming larger aggregates that scatter light poorly and behave unpredictably.
Material limits and economics. Some proposed alternatives to sulfates — from titanium dioxide to cubic zirconia and even diamond dust in theoretical scenarios — look attractive on paper but are scarce or costly at the scale required. The team finds only a handful of materials (for example, calcium carbonate and alpha‑alumina) are abundant enough in principle, and both come with their own dispersion challenges and environmental unknowns.
Injection logistics change the physics. Altitude, latitude, longitude, season and injection rate all affect particle lifetime and transport through the Brewer‑Dobson circulation. Small changes in where and when aerosols are released can alter regional rainfall, monsoon behaviour and ozone chemistry — outcomes that are difficult to control if deployment is not tightly coordinated.

Why "chaos" is not just rhetorical

The paper’s stark language — warning that dimming the sun could "spark global chaos" — reflects how engineering uncertainties and geopolitical fragmentation could couple to produce cascading impacts. Mis-sized or aggregated particles could weaken intended cooling or produce unexpected heating in parts of the atmosphere. Latitude‑biased deployments could disrupt monsoon rains that hundreds of millions of people depend on for food and water. Ozone chemistry is sensitive to stratospheric changes, and some strategies that avoid one risk may amplify another.

On the political side, uneven benefits and harms raise the spectre of diplomatic friction. If one set of countries chooses a deployment that cools their region but stresses agriculture in another, disputes over responsibility and compensation are likely. The risk of accidental, unilateral or dual‑use deployment — especially in a world with strategic competition — compounds the uncertainty.

And then there's the termination problem

Experts have long warned of the so‑called "termination shock": if a long‑term SAI program were suddenly stopped, the masking effect would vanish while greenhouse gases would remain, producing a rapid and potentially catastrophic warming spike. That prospect turns SAI from a temporary patch into a potential commitment: once started, it may be safer — though politically and technically fraught — to continue indefinitely.

What this means for policy and research

The Columbia study does not argue that every form of SAI is impossible. Rather, it highlights that much of the published modelling literature understates real‑world constraints. That has two practical implications:

Alternatives — and a clear warning

Crucially, solar geoengineering does not remove greenhouse gases or stop ocean acidification. Many climate experts and organisations argue it should never be a substitute for rapid emissions reductions and carbon removal. The Columbia team’s contribution strengthens that warning by showing how engineering limits and political fragmentation could turn a polished climate model into a real‑world headache with unpredictable social and ecological fallout.

For policymakers, the takeaway is blunt: SAI may look inexpensive and fast in simulations, but making it work safely in the real world is a far more complicated — and dangerous — engineering and diplomatic problem than many papers have assumed. The temptation of a technical quick fix should not obscure the basic fact that the safest path out of climate risk still runs through deep emissions cuts, careful investment in removal technologies, and multilateral institutions that can manage global commons.

Mattias Risberg

Cologne-based science & technology reporter tracking semiconductors, space policy and data-driven investigations.

University of Cologne (Universität zu Köln) • Cologne, Germany