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Public Health Preparedness in the Era of Weather Modification and Climate Engineering

Published online by Cambridge University Press:  15 February 2023

Christos Tsagkaris Open the ORCID record for Christos Tsagkaris [Opens in a new window] ,
Andreas S. Papazoglou Open the ORCID record for Andreas S. Papazoglou [Opens in a new window] ,
Dimitrios V. Moysidis  and
Anna Loudovikou
Christos Tsagkaris
Affiliation:
European Student Think Tank, Public Health and Policy Working Group, Amsterdam, Netherlands
Andreas S. Papazoglou*
Affiliation:
Athens Naval Hospital, Athens, Greece
Dimitrios V. Moysidis
Affiliation:
Hippokration University Hospital, Aristotle University of Thessaloniki, Thessaloniki, Greece
Anna Loudovikou
Affiliation:
Aristotle University of Thessaloniki, Faculty of Philosophy, Thessaloniki, Greece
*
Corresponding author: Andreas S. Papazoglou, Email: andreaspap797@gmail.com.
Rights & Permissions [Opens in a new window]

Abstract

The use of technological and chemical means aiming to achieve favorable weather conditions or reduce the risk of weather extremes is known as Weather Modification (WM). The United States of America, the People’s Republic of China, Thailand, the United Arab Emirates, and Europe have employed WM in an effort to prevent hurricanes and storms, control precipitations, mitigate deforestation and drought, and enhance agriculture. Recently, the use of WM has been expanded toward decreasing air pollution and creating favorable weather conditions for major political and athletic events. The increasing significance and use of WM call for consideration upon its positive and negative effects on human health, close collaboration among health experts and WM decision makers, and relevant public health emergency contingency planning.

Keywords

climate engineeringpublic health preparednessweather modification
Type
Brief Report
Information
Disaster Medicine and Public Health Preparedness , Volume 17 , 2023 , e308
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of Society for Disaster Medicine and Public Health, Inc.

Weather modification (WM) pertains to the use of technological and chemical means, aiming to achieve or prolong favorable weather conditions and reduce the risk of weather extremes. The first scientific weather modification attempts were recorded in the 19th century. WM was widely used between 1950 and 1970 in both the military sector and agriculture. While its use in warfare was prohibited, WM was further researched and used in the United States of America, the People’s Republic of China, Thailand, and the United Arab Emirates (UAE) in an effort to prevent hurricanes and storms, mitigate deforestation and drought, and enhance crop production. Reference Chalmin1 Recent reports suggest that WM was deployed to decrease air pollution in large urban centers and create favorable weather conditions for major political and athletic events, Reference Davidson2 inaugurating what is considered as the era of climate engineering. The increasing significance and use of WM call for consideration upon its positive and negative effects on human health.

Evidence Regarding Weather Modification

A rapid search in major biomedical research databases reveals limited knowledge on the matter. The majority of studies document environmental impacts of cloud seeding but provide limited information regarding its actual effect on human health. In this sense, it has become obvious that WM can lead to increased air stagnation over residential areas, particularly during winter, Reference Liao, Gui and Jiang3,Reference Garrido-Perez, Ordóñez, García-Herrera and Barriopedro4 as well as to a decrease in the photosynthetic ability of terrestrial plants and phytoplankton. Reference Rodríguez-Sánchez, Rosas, Calva-Vásquez and Sandoval-Zapotitla5,Reference Fajardo, Costa and Ortiz6 The available studies have also examined the distribution of particles used for the purpose of WM in atmospheric air Reference Lou, Zhao and Yang7 or in the water Reference Deng, Shi and Wu8 and novel cloud seeding techniques capable of decreasing the amount of greenhouse gases trapped by the clouds. Reference Storelvmo, Boos and Herger9 Such studies provide a standpoint for hypotheses and predictions and show a considerable knowledge gap with regard to WM safety and potential health benefits.

To date, not only studies on toxicity of compounds used in cloud seeding are limited, but also some of them have gained expressions of concern or been retracted on the grounds of scientific integrity. 10,Reference Herndon11 It appears that WM-associated air stagnation can trigger asthma exaggeration, Reference Norris, Larson and Koenig12 while manual treatment of cloud seeding compounds increases the risk for occupational contact dermatitis. Reference Ng and Koh13 Until a large-scale investigation of the real-world health implications of WM means and techniques is performed, relevant public health preparedness needs to be based on the existing knowledge about the interconnection of climate, climate change, and climate adaptation on human health.

Health Considerations on Weather Modification

Climate conditions can have direct and indirect effects on health. Direct health implications include respiratory disease exacerbation, skin and eye inflammation due to low air humidity, Reference Sato, Fukayo and Yano14 blood pressure and heart rhythm irregularities due to low or high temperatures, Reference Liu, Yavar and Sun15 and altered transmission dynamics in cases of weather conditions favoring indoor gatherings or proliferation of zoonotic disease vectors and radiation-associated skin cancer. Reference Joszt16 Indirect health implications stem from climate change intercepting the social determinants of health. Increased temperatures, reduced rainfall, droughts, and the opposites of them can equivocally harm agricultural economy, travel and tourism, undermine food security, professional and financial stability, and pave the way toward irregular migration. Reference Semenza and Ebi17 Simultaneously, the provision of health care services is also subject to adverse weather conditions that hinder the commute of health care professionals, patients, and supplies, or destroy sensitive equipment. Reference Paavola18

While WM is regarded as reparative action toward the aforementioned climate conditions, it is still likely that efforts to decrease the temperature or induce rainfall can backfire in the form of freeze damage and floods, and vice versa. For instance, cloud seeding over remote agricultural communities with a high prevalence of respiratory and cardiovascular diseases and limited access to emergency health care may undermine the benefits from increased crop production. Similarly, unexpected rainfall or snowfall can pose a threat to remote communities, who will be deprived of supplies or access to emergency care. Reference Friedrich, Ikeda and Tessendorf19 Providing remote communities with adequate supplies, instructing people with respiratory conditions to wear a mask or stay indoors, enhancing epidemiological surveillance for zoonotic disease outbreaks, or even postponing skiing, hiking, and rafting activities in potentially affected areas are some representative examples. WM planning can become safer as long as the frequency of likely-to-be-exacerbated diseases or the presence of zoonotic disease vectors in the local biota is taken into account. Therefore, WM attempts should be promptly communicated with public health authorities to create contingency plans for WM-associated “adverse events.”

WM has also the potential to benefit health. So far, rain enhancement in the UAE has improved the population’s access to water. Thriving agriculture has also leveraged the living standards of communities that would otherwise face poverty. Reference Munoz20 Similarly, decreasing greenhouse gases can also decrease the burden of asthma, rhinosinusitis, and chronic obstructive pulmonary disease in the course of time. Reference Storelvmo, Boos and Herger9 At a larger scale improving agricultural production, maritime, trade, travel, and transportations by means of WM can contribute to financial growth, part of which can be channeled toward biomedical advances and equitable health care. In the foreseeable future, this can contribute to addressing the global financial effects of coronavirus disease (COVID-19).

Conclusions and Recommendations

Certainly, this cannot be achieved unless regulators, international organizations, and health bodies work together to monitor and mitigate the potential adverse health implications of WM. The Convention on the prohibition of military or any other hostile use of environmental modification techniques sets a worthy precedent. 21 In response to the wider use of WM, a new pact safeguarding health and well-being should be put in place. Researchers, health care professionals, and health advocates must stress that WM without public health preparedness and contingency plans can backfire into a considerable disease burden and financial disruption. The current COVID-19 pandemic has set a clear example of the potential of health crises to impact the global economy, and this notion should be respected by those who make decisions on WM.

In the future, it is possible that WM will be used widely. Reference Zielinski22 Denouncing the use of technological and chemical means for this purpose would be unrealistic. On the contrary, putting together public health preparedness and contingency plans, and urging decision-makers to adhere to them, is a worthy endeavor.

Funding statement

None.

Conflict(s) of interest

None.

References

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