Global Effects of Nuclear War: Resource Guide

An Introductory Resource Guide for Researchers, Teachers, and Students

Two ways to engage with this literature:

• New to the field? Start with our Background Paper for a guided, chronological overview of how scientific understanding of nuclear-war effects has developed.

• Looking to contribute? Explore the sections below to see where your expertise fits into current research questions.

 

 

Atmospheric Injection and Plume Dynamics

How material from nuclear detonations enters the upper atmosphere through city firestorms is a foundational question in nuclear-war effects research. This line of work examines the physical mechanisms by which fires ignited in urban and industrial areas generate smoke plumes, how those plumes rise, and under what conditions soot and other aerosols reach the upper troposphere or stratosphere—where their climatic influence becomes long-lived and global. Assumptions about fuel availability, fire behavior, and plume lofting are among the most consequential drivers of divergence across models and remain an active area for interdisciplinary research.

Who might contribute here?

Atmospheric physicists, fire and plume-dynamics specialists, combustion scientists, urban systems researchers, high resolution urban climate modelers, and others working on aerosol injection, convective transport, or extreme fire behavior in complex built environments.

Resources:

• Paul J. Crutzen and John W. Birks, “The Atmosphere after a Nuclear War: Twilight at Noon,” Ambio 11, no. 2–3 (1982): 114–125.

A foundational paper that first articulated how smoke from large-scale urban fires could be lofted into the upper atmosphere, framing plume rise and atmospheric persistence as central drivers of global nuclear-war effects.

• Nathaniel Tarshish and David M. Romps, “Latent Heating Is Required for Firestorm Plumes to Reach the Stratosphere,” Journal of Geophysical Research: Atmospheres 127 (2022): e2022JD036667.  

This study examines the physics of plume rise, showing that latent heat release is a necessary condition for firestorm smoke to reach the stratosphere, directly constraining assumptions used in nuclear-war climate models.

Further exploration:

• National Security Archive. “Investigating the Climate Impacts of Nuclear War.” Washington, DC: George Washington University, 2024
• Coupe, Joshua, Charles G. Bardeen, Alan Robock, and Owen B. Toon. “Nuclear Niño Response Observed in Simulations of Nuclear War Scenarios.” Communications Earth & Environment 2, no. 1 (2021): 1–11.

 

 

Climate System Response and Modeling Architecture

Once smoke and aerosols enter the upper atmosphere, their interaction with the climate system determines the scale, duration, and geographic distribution of cooling and precipitation changes. This body of research focuses on how radiative forcing from soot alters surface temperatures, atmospheric circulation, and hydrological cycles, and on how different modeling choices—such as dimensionality, coupling, and representation of feedbacks—shape outcomes. Advances in Earth system models have strengthened confidence in the direction of effects while also sharpening debates over magnitude and persistence.

Who might contribute here?

Climate modelers, Earth system scientists, atmospheric dynamicists, radiation and cloud-physics specialists, and researchers working on model intercomparison, uncertainty quantification, or coupled climate–aerosol feedbacks.

Resources:

• R. P. Turco, O. B. Toon, T. P. Ackerman, J. B. Pollack, and C. Sagan, “Nuclear Winter: Global Consequences of Multiple Nuclear Explosions,” Science 222, no. 4630 (1983): 1283–1292. 

This paper represents the first end-to-end climate response modeling framework, translating assumed smoke injection into global temperature, circulation, and radiation effects using simplified climate modeling architecture.

• Curt Covey, Stephen H. Schneider, and Thomas L. Thompson, “Global Atmospheric Effects of Massive Smoke Injections from a Nuclear War: Results of General Circulation Model Simulations,” Nature 308, no. 5956 (1984): 21–25. 

This paper advanced the field by using general circulation models (GCMs) to explore how different climate-model structures alter predicted temperature and circulation responses.

Further Exploration:

• National Academies of Sciences, Engineering, and Medicine. Potential Environmental Effects of Nuclear War. Washington, DC: National Academies Press, 2025.
• Jägermeyr, Jonas, et al. “A New Ocean State after Nuclear War.” AGU Advances 3, no. 2 (2022): e2021AV000610.
• Joshua Coupe, Charles G. Bardeen, Alan Robock, and Owen B. Toon, “Nuclear Winter Responses to Nuclear War Between the United States and Russia in the Whole Atmosphere Community Climate Model Version 4 and the Goddard Institute for Space Studies ModelE,” Journal of Geophysical Research: Atmospheres 124, no. 15 (2019): 8522–8543.

 

 

Atmospheric Chemistry, Ozone Depletion, and Radiative Effects

Research in this category examines how nuclear detonations and the resulting atmospheric perturbations affect chemical processes in the stratosphere and upper troposphere, particularly ozone depletion and changes in ultraviolet (UV) radiation reaching Earth’s surface. This work played a critical role in broadening early understandings of nuclear-war effects beyond fallout and blast damage, highlighting global-scale biological and ecological consequences even in the absence of severe surface cooling. While later climate-focused studies became more prominent, atmospheric chemistry remains an important yet underexplored pathway of harm and an area where modern chemical-transport modeling could yield further insight.

Who might contribute here?

Atmospheric chemists, photochemists, radiation and UV specialists, chemical-transport modelers, and researchers working on stratospheric processes, ozone recovery dynamics, or biospheric UV sensitivity.

Resources:

• National Academy of Sciences, Long-Term Worldwide Effects of Multiple Nuclear-Weapons Detonations (Washington, DC: National Academy of Sciences, 1975).

This report foregrounds atmospheric chemistry and radiological pathways, especially ozone depletion and long-term radiation effects, before climate cooling became the dominant framing.

• United Nations Scientific Committee on the Effects of Atomic Radiation (UNSCEAR), Sources, Effects, and Risks of Ionizing Radiation (New York: United Nations, 1988), selected sections on atmospheric and radiological impacts.

Provides a synthesis of atmospheric, radiological, and chemical impacts, including stratospheric processes and biological exposure pathways rather than climate dynamics per se.

Further Exploration:

• Paul J. Crutzen, “The Possible Importance of CS₂ for the Sulfate Layer of the Stratosphere,” Geophysical Research Letters 3, no. 2 (1976): 73–76.
• Institute of Medicine (US) Steering Committee for the Symposium on the Medical Implications of Nuclear War. The Medical Implications of Nuclear War. Edited by Fred Solomon and Robert Q. Marston. Washington, DC: National Academy Press, 1986.
• Bardeen, Charles G., Douglas E. Kinnison, Owen B. Toon, Michael J. Mills, Francis Vitt, Lili Xia, Jonas Jägermeyr, Nicole S. Lovenduski, Kim J. N. Scherrer, Margot Clyne, and Alan Robock, 2021: Extreme ozone loss following nuclear war resulting in enhanced surface ultraviolet radiation. J. Geophys. Res. Atmos., 126, e2021JD035079, doi:10.1029/2021JD035079. 
• Yook, S., Solomon, S., Bardeen, C. G., &Stone, K. (2025). Arctic ozone hole and enhanced mid‐latitude ozone losses due to heterogeneous halogen chemistry following a regional nuclear conflict. Earth's Future, 13, e2025EF006866.

 

 

Food Systems, Ecology, and Human Consequences

This body of research examines how climate and atmospheric disruptions caused by nuclear war propagate through ecosystems, agriculture, and global food systems, shaping risks of famine and mass human suffering. Rather than focusing solely on physical or atmospheric effects, these studies integrate crop models, fisheries, trade, and nutritional requirements to assess societal vulnerability under different conflict scenarios. This work has helped translate abstract climatic changes into human-relevant outcomes, while also revealing how inequality, geography, and global interdependence mediate impacts.

Who might contribute here?

Agricultural scientists, food-system modelers, ecologists, fisheries scientists, nutrition experts, economists, and researchers working on global trade, food security, or humanitarian risk modeling.

Resources:

• Xia, Lili, Alan Robock, Kim Scherrer, Cheryl S. Harrison, Benjamin Leon Bodirsky, Isabelle Weindl, Jonas Jägermeyr, Charles G. Bardeen, Owen B. Toon, and Ryan Heneghan. “Global Food Insecurity and Famine from Reduced Crop, Marine Fishery and Livestock Production due to Climate Disruption from Nuclear War Soot Injection.” Nature Food 3, no. 8 (2022): 586–596.

This article translates climate disruption into crop yields, caloric availability, and famine risk, integrating agricultural, trade, and nutritional modeling.

• Robock, Alan, Luke Oman, Georgiy L. Stenchikov, Owen Toon, Charles Bardeen, and Richard P. Turco. “Climatic Consequences of Regional Nuclear Conflicts.” Atmospheric Chemistry and Physics 7, no. 8 (2007): 2003–2012.

An influential early analysis showing that even regional nuclear conflicts could produce significant climate perturbations, helping motivate later work on ecological and food-system impacts.
 

Further Exploration:

• Helfand, Ira. Nuclear Famine: Two Billion People at Risk? Global Impacts of Limited Nuclear War on Agriculture, Food Supplies, and Human Nutrition (Updated Report). Boston: International Physicians for the Prevention of Nuclear War, 2022.
• Shi, Yuning, Felipe Montes, Francesco Di Gioia, Lili Xia, Charles G. Bardeen, Charles T. Anderson, Yolanda Gil, Deborah Khider, Varun Ratnakar, and Armen R. Kemanian. “Adapting Agriculture to Climate Catastrophes: The Nuclear Winter Case.” Environmental Research Letters 20, no. 6 (2025): 064006.

 

 

Early Global Effects and Fallout-Centered Assessments (1940s–1960s)

The earliest studies of nuclear war’s global consequences focused primarily on radioactive fallout and long-term biological harm, rather than climate or atmospheric disruption. These efforts established the first systemic thinking about worldwide nuclear damage and shaped decades of subsequent inquiry, even as later research would shift attention toward atmospheric, climatic, and ecological mechanisms.

Who might engage here?

Historians of science, radiobiologists, health physicists, environmental historians, and researchers interested in how early assumptions shaped later scientific trajectories.

Resources:

• Project Gabriel. A Study of the Large-Scale Effects of Nuclear War. Report to the U.S. Atomic Energy Commission by Nicholas M. Smith. Washington, DC, 1949.

One of the earliest global assessments of nuclear war effects, this study focused on radioactive fallout, long-term biological harm, and worldwide exposure pathways.

• Project Sunshine. A Report on Worldwide Fallout of Strontium-90. Washington, DC: U.S. Atomic Energy Commission and U.S. Air Force, 1953.

This report quantified the global distribution and biological uptake of radioactive fallout, shaping early understanding of the long-term health consequences of nuclear detonations.

Further Exploration:

• Philippe, Sébastien, Susan Alzner, Gilbert P. Compo, Mason Grimshaw, and Megan Smith. “Fallout from U.S. Atmospheric Nuclear Tests in New Mexico and Nevada (1945–1962).” arXiv preprint arXiv:2307.11040. July 20, 2023.
• United Kingdom, Cabinet Office. Report of the Strath Committee on the Effects of Nuclear Weapons. London: Her Majesty’s Stationery Office, 1955. (Overview available at https://en.wikipedia.org/wiki/Strath_Committee)

 

Regional Nuclear War Climate Effects: Model Assumptions and Scientific Debate

This category brings together a set of closely related studies examining the potential climatic consequences of a regional nuclear conflict, most often modeled as a limited nuclear exchange between India and Pakistan. These works are best read together, as they engage in an active and consequential scientific debate over whether such a conflict could plausibly generate enough soot injection into the upper troposphere or stratosphere to produce long-lasting, global climatic disruption.

At the center of this debate are modeling assumptions made early in the causal chain, particularly those related to urban fuel loads, fire behavior, firestorm formation, plume rise, rainout, and pyro-convection. Once soot is assumed to reach and persist in the stratosphere, there is relatively strong agreement on the direction and severity of climate responses. Disagreement instead arises over whether—and under what conditions—those upstream processes would occur in a regional nuclear war scenario.

These papers collectively illustrate how different assumptions about real-world fire dynamics and material properties can lead to sharply divergent conclusions about the magnitude, duration, and global reach of climatic effects. As such, they provide an important case study in how scientific uncertainty, modeling choices, and empirical gaps shape high-stakes risk assessments.

Resources:

• Mills, Michael J., Owen B. Toon, Richard P. Turco, Douglas E. Kinnison, and Rolando R. Garcia. “Multidecadal Global Cooling and Unprecedented Ozone Loss Following a Regional Nuclear Conflict.” Earth’s Future 2, no. 4 (2014): 161–176.

This paper presents one of the strongest modeled outcomes of a regional nuclear conflict, concluding that large soot injections from urban fires could drive decades-long global cooling and severe ozone depletion.

• Reisner, Jon M., Gennaro D’Angelo, Eunmo Koo, Wesley P. Even, Matthew W. Hecht, Elizabeth C. Hunke, Darin S. Comeau, Randall J. Bos, and James H. Cooley. “Climate Impact of a Regional Nuclear Weapons Exchange: An Improved Assessment Based on Detailed Source Calculations.” Journal of Geophysical Research: Atmospheres 123, no. 5 (2018): 2752–2772.

This study directly challenges the plausibility of the outcomes claimed by Mills et al. by questioning key upstream assumptions about urban fuel loads, firestorm formation, and the efficiency of soot lofting into the stratosphere.

• Robock, Alan, Owen B. Toon, and Charles G. Bardeen. “Comment on ‘Climate Impact of a Regional Nuclear Weapons Exchange: An Improved Assessment Based on Detailed Source Calculations’ by Reisner et al.” Journal of Geophysical Research: Atmospheres 124, no. 24 (2019): 12,953–12,958.

In response to Reisner et al., the authors defend the realism of firestorm behavior and stratospheric soot injection in regional conflict scenarios, arguing that the challenged assumptions are consistent with historical and observational evidence.

• Hess, Gregory D. “The Impact of a Regional Nuclear Conflict between India and Pakistan: Two Views.” Journal for Peace and Nuclear Disarmament 4, suppl. 1 (2021): 163–175.

This article synthesizes the competing models and arguments, framing the disagreement as a question of unresolved empirical uncertainty rather than a dispute over basic climate physics.

Who might contribute here?

Researchers who can help constrain, test, or empirically ground the assumptions underlying regional nuclear war climate models are particularly well positioned to contribute in this area. This includes:

• Fire science and combustion researchers studying large urban fires, firestorms, and mass-conflagration dynamics
• Atmospheric scientists working on plume rise, pyro-convection, and aerosol transport in the upper troposphere and lower stratosphere
• Remote sensing and satellite imagery analysts capable of characterizing urban fuel loads, building materials, and post-destruction fire behavior
• Urban systems, civil engineering, and materials researchers with expertise in modern construction practices and combustible contents
• Experimentalists and field researchers studying soot emission factors, black carbon aging, and rainout under realistic fire conditions
• Model intercomparison and uncertainty specialists interested in systematically testing sensitivity to assumptions across fire and climate models

Progress in this area depends less on further refinement of global climate models alone and more on improving how real-world fire behavior and material properties are represented within them, making this a particularly fertile area for interdisciplinary collaboration.

 

 

Integrated Assessments and International Scientific Syntheses

At several key moments, international and national scientific bodies have sought to integrate disparate lines of research on nuclear-war effects into authoritative assessments. These efforts synthesize evidence across atmospheric physics, climate modeling, biological impacts, and human consequences, while also explicitly grappling with uncertainty, disagreement, and policy relevance. For new researchers, these assessments provide both a snapshot of where scientific consensus existed at particular historical moments and a reminder of how institutional context shapes the framing and communication of risk.

Who might contribute here?

Interdisciplinary groups of scientists, assessment authors, science-policy experts, systems analysts, and researchers interested in synthesis methods, uncertainty communication, or the interface between scientific knowledge and international governance.

Resources:

• United States Congress, House of Representatives, Committee on Science and Technology. The Climatic, Biological, and Strategic Effects of Nuclear War: Hearings before the Committee on Science and Technology, Ninety-Eighth Congress, Second Session, April 1984. Washington, D.C.: U.S. Government Printing Office, 1984.

These congressional hearings brought together scientific testimony on nuclear-war effects, integrating climate, biological, and strategic perspectives for policymakers.

• National Academy of Sciences, The Effects on the Atmosphere of a Major Nuclear Exchange (Washington, DC: National Academy Press, 1985).

This assessment synthesized contemporary atmospheric science on nuclear war, evaluating climate and chemical effects while explicitly addressing scientific uncertainty.

• Scientific Committee on Problems of the Environment (SCOPE), Environmental Consequences of Nuclear War, Volume I: Physical and Atmospheric Effects (Chichester, UK: John Wiley & Sons, 1986).

An interdisciplinary synthesis integrating physical and atmospheric research on nuclear-war effects, produced through an international scientific collaboration.

• United Nations. Study on the Climatic and Other Global Effects of Nuclear War: Report of the Secretary-General. New York: United Nations, 1988.

This UN report provided a global synthesis of scientific understanding of nuclear-war impacts, situating climate and environmental risks within an international governance context.

Further Exploration:

• U.S. Government Accountability Office. Uncertainties Surround the Long-Term Effects of Nuclear War. GAO/NSIAD-86-62. Washington, DC: GAO, 1986.
• Robock, Alan, Lili Xia, Cheryl S. Harrison, Joshua Coupe, Owen B. Toon, and Charles G. Bardeen. “Opinion: How Fear of Nuclear Winter Has Helped Save the World, So Far.” Atmospheric Chemistry and Physics 23, no. 12 (2023): 6691–6701.
• Schell, Jonathan. The Fate of the Earth. New York: Alfred A. Knopf, 1982.

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Development of this resource page is supported by Lex International through the Swiss Philanthropy Foundation.