by  James R. Fleming
from the Wilson Quarterly [HERE]

Beyond the security checkpoint at the  National  Aeronautics and Space Administration’s Ames Research Center at the  southern end of San Francisco Bay, a small group gathered in November for a  conference on the innocuous topic of “managing solar  radiation.” The real subject was much bigger: how to save the planet  from the effects of global warming. There was little talk among the two  dozen scientists and other specialists about carbon taxes, alternative  energy sources, or the other usual remedies. Many of the scientists were  impatient with such schemes. Some were simply contemptuous of calls for  international cooperation and the policies and lifestyle changes needed to  curb greenhouse-gas emissions; others had concluded that the world’s  politicians and bureaucrats are not up to the job of agreeing on such  reforms or that global warming will come more rapidly, and with more  catastrophic consequences, than many models predict. Now, they believe, it  is time to consider radical measures: a technological quick fix for global  ­warming.

“Mitigation is not happening and is not going to  happen,” physicist Lowell Wood declared at the NASA conference. Wood,  the star of the gathering, spent four dec ades at the University of California’s Law rence Livermore National Laboratory, where he  served as one of the Pentagon’s chief weapon designers and threat  analysts. ( He reportedly enjoys the  “Dr. Evil” nickname bestowed by his critics.) The time has come, he said, for “an intelligent  elimination of undesired heat from the biosphere by technical ways and  means,” which, he asserted, could be achieved for a tiny fraction of  the cost of “the  bureaucratic suppression of CO2.” His engineering approach, he boasted, would provide  “instant climatic gratification.”


Wood advanced several ideas to “fix” the  earth’s climate, including building up Arctic sea ice to make it  function like a planetary air conditioner to “suck heat in from the  ­mid latitude heat bath.” A “surprisingly  practical” way of achieving this, he said, would be to use large  artillery pieces to shoot as much as a million tons of highly reflective  sulfate aerosols or ­specially ­engineered nanoparticles into the  Arctic stratosphere to deflect the sun’s rays. Delivering up to a  million tons of material via artillery would require a constant  ­bombardment— basically declaring war on the  strato sphere. Alternatively, a fleet of B-747 “crop dusters” could  deliver the particles by flying continuously around the Arctic Circle. Or a  25-kilometer- long sky hose could be tethered to a military superblimp  high above the planet’s surface to pump reflective particles into the  ­atmosphere.

Far-fetched as Wood’s ideas may sound, his  weren’t the only Rube Goldberg proposals aired at the meeting. Even  as they joked about a NASA staffer’s apology for her inability to  control the temperature in the meeting room, others detailed their own  schemes for manipulating earth’s climate. Astronomer J. Roger Angel  suggested placing a huge fleet of mirrors in orbit to divert incoming solar  radiation, at a cost of “only” several trillion dollars. Atmospheric scientist  John Latham and engineer Stephen Salter hawked their idea of making marine  clouds thicker and more reflective by whipping ocean water into a froth  with giant pumps and eggbeaters. Most frightening was the science-fiction  writer and astrophysicist Gregory Benford’s announcement that he  wanted to “cut through red tape and demonstrate what could be  done” by finding private sponsors for his plan to inject diatomaceous  ­earth— the ­chalk like substance used in filtration  systems and cat ­litter— into the Arctic stratosphere. He,  like his fellow geoengineers, was largely silent on the possible unintended  consequences of his plan.

The inherent unknowability  of what would happen if we tried to tinker with the immensely complex planetary climate system is one reason why climate engineering has until  recently been spoken of only sotto voce in the scientific community. Many  researchers recognize that even the most brilliant scientists have a  history of blindness  to the wider ramifications of their work. Imagine, for example, that  Wood’s scheme to thicken the Arctic icecap did somehow become  possible. While most of the world may want to maintain or increase polar  sea ice, Russia and some other nations have historically desired an  ­ice- free Arctic ocean, which would liberate shipping and open  potentially vast oil and mineral deposits for exploitation. And an  engineered Arctic ice sheet would likely produce shorter growing seasons  and harsher winters in Alaska, Siberia, Greenland, and elsewhere, and could  generate super winter storms in the midlatitudes. Yet Wood calls his brainstorm a plan for “global climate stabilization,” and hopes  to create a sort of “planetary thermostat” to regulate the global  ­climate.

Who would control such a “thermostat,”  making ­life- altering decisions for the planet’s billions? What is to prevent other nations from undertaking unilateral climate  modification? The United States has no monopoly on such dreams. In November  2005, for example, Yuri Izrael, head of the ­Moscow- based  Institute of Global Climate and Ecology Studies, wrote to Russian president Vladimir Putin to make the case for immediately burning massive amounts of  sulfur in the stratosphere to lower the earth’s temperature “a  degree or two”—a correction greater than the total warming  since ­pre- industrial ­times.

There is, moreover, a troubling motif of  militarization in the history of weather and climate control. Military  leaders in the United States and other countries have pondered the  possibilities of weaponized weather manipulation for decades. Lowell Wood  himself embodies the overlap of civilian and military interests. Now  affiliated with the Hoover Institution, a think tank at Stanford  ­University, Wood was a protégé of the late Edward  Teller, the weapons scientist who was credited with developing the hydrogen  bomb and was the architect of the ­Reagan- era Star Wars  ­missile ­defense system (which Wood worked on, too). Like Wood,  Teller was known for his advocacy of controversial military and  technological solutions to complex problems, including the chimerical “peaceful uses of nuclear weapons.” Teller’s plan to  excavate an artificial harbor in Alaska using thermo nuclear explosives  actually came close to receiving government approval. Before his death in  2003, Teller was advocating a climate control scheme similar to what Wood  proposed.

Despite the large, unanswered questions about the  implications of playing God with the elements, climate engineering is now  being widely discussed in the scientific community and is taken seriously  within the U.S. government. The Bush administration has recommended the  addition of this “important strategy” to an upcoming report of  the Intergovernmental Panel on Climate Change, the ­UN- sponsored  organization whose February study seemed to persuade even the Bush White House to take global warming more seriously. And climate  engineering’s advocates are not confined to the small group that met  in California. Last year, for example, Paul J. Crutzen, an atmospheric  chemist and Nobel laureate, proposed a scheme similar to Wood’s, and  there is a long paper trail of climate and weather modification studies by  the Pentagon and other government agencies.

As the sole historian at the NASA conference, I may  have been alone in my appreciation of the irony that we were meeting on the  site of an old U.S. Navy airfield literally in the shadow of the huge  hangar that once housed the ­ill-starred Navy dirigible U.S.S. Macon. The  785- foot- long Macon, a technological wonder of its time, capable of cruising at 87  miles per hour and launching five Navy biplanes, lies at the bottom of the  Pacific Ocean, brought down in 1935 by strong winds. The Navy’s  entire rigid-airship program went down with it. Coming on the heels of the  crash of its sister ship, the Akron, the Macon’s destruction showed that the design of these technological marvels was fundamentally flawed. The hangar, built by the Navy in 1932, is  now both a historic site and a Superfund site, since it has been discovered  that its “galbestos” siding is leaching PCBs into the drains.  As I reflected on the fate of the Navy dirigible program, the geoengineers  around the table were confidently and enthusiastically promoting techniques  of climate intervention that were more than several steps beyond what might  be called state of the art, with implications not simply for a handful of  airship crewmen but for every one of the 6.5 billion inhabitants of the  ­planet.

Ultimate control of the weather and climate excites  some of our wildest fantasies and our greatest fears. It is the stuff of  age-old myths. Throughout history, we mortals have tried to protect  ourselves against harsh weather. But weather control was reserved for the ancient sky gods. Now the power has seemingly devolved to modern Titans. We are undoubtedly facing an  uncertain future. With rising temperatures, increasing emissions of  greenhouse gases, and a growing world population, we may be on the verge of  a worldwide climate crisis. What shall we do? Doing nothing or too little is clearly wrong, but so is doing too ­much.

Largely unaware of the long and checkered history of  weather and climate control and the political and ethical challenges it  poses, or somehow considering themselves exempt, the new Titans see themselves as heroic pioneers, the first generation capable of alleviating  or averting natural disasters. They are largely oblivious to the history of  the charlatans and sincere but deluded scientists and engineers who  preceded them. If we fail to heed the lessons of that history, and fail to  bring its perspectives to bear in thinking about public policy, we risk  repeating the mistakes of the past, in a game with much higher ­stakes.

Three stories (there are  many more) capture the recurring pathologies of weather and climate control  schemes. The first involves ­19th- century proposals by the U.S.  government’s first meteorologist and other  “pluviculturalists” to make artificial rain and relieve drought  conditions in the American West. The second begins in 1946 with promising  discoveries in cloud seeding that rapidly devolved into exaggerated claims  and attempts by cold warriors to wea ponize the technique in the  jungles of Vietnam.  And then there is the tale of how computer modeling raised hopes for  perfect forecasting and ultimate control of weather and  ­climate— hopes that continue to inform and encourage  ­present- day planetary ­engineers.

James Pollard Espy (1785–1860), the first  meteorologist employed by the U.S. government, was a frontier schoolmaster  and lawyer until he moved to Philadelphia in 1817. There he supported himself by teaching mathematics and classics ­part ­time while  devoting himself to meteorological research. Working through the American  Philosophical Society and the Franklin Institute, Espy gained the support  of Pennsylvania’s  legislature to equip weather observers in each county in the state with  barometers, thermometers, and other standard instruments to provide a  larger, synoptic picture of the weather, especially the passage of  ­storms.

Espy viewed the atmosphere as a giant heat engine.  According to his thermal theory of storms, all atmospheric disturbances,  including thunderstorms, hurricanes, and winter storms, are driven by “steam power.” Heated by the sun, a column of air rises,  allowing the surrounding air to rush in. As the heated air ascends, it  cools and its moisture condenses, releasing its latent heat (this is the “steam”) and producing rain, hail, or snow. The thermal theory  is now an accepted part of meteorology, and for this discovery Espy is well  regarded in the history of ­science.

His stature has been diminished, however, by his  unbridled enthusiasm for rainmaking. Espy suggested cutting and burning  vast tracts of forest to create huge columns of heated air, believing this  would generate clouds and trigger precipitation. “Magnificent  Humbug” was one contemporary assessment of this scheme. Espy came to  be known derisively as the “Storm King,” but he was not ­deterred.

Seeking a larger stage for his storm studies and  rainmaking proposals, Espy moved in 1842 to Washington, D.C., where he was  funded by the Navy and employed as the “national meteorologist”  by the Army Medical Department. This position afforded him access to the meteorological reports of surgeons at Army posts around the country. He  also collaborated with Joseph Henry at the Smithsonian Institution to  establish and maintain a national network of volunteer weather  ­observers.

The year Espy moved to Washington, the popular  magazine writer Eliza Leslie published a short story in Godey’s Lady’s Book called “The Rain King, or, A  Glance at the Next Century,” a fanciful account of rainmaking set in  1942 in Philadelphia, in which Espy’s  great-great- grand- nephew offers weather for the Delaware Valley  on demand. Various factions vie for the weather they desire. Three hundred  washerwomen petition the Rain King for fine weather forever, while cabmen  and umbrella makers want perpetual rain. An equal number of applications  come from both the fair- and ­foul- weather camps, until the  balance is tipped by a late request from a winsome ­high- society  matron desperately seeking a hard rain to prevent a visit by her  ­country-­bumpkin cousins that would spoil the lavish party she is  ­planning.

Of course, when the artificial rains come, they  satisfy no one and raise widespread suspicions. The Rain King, suddenly  unpopular because he lacks the miraculous power to please everybody, takes  a steamboat to China, where he studies magic in anticipation of returning  someday. “Natural rains had never occasioned anything worse than  submissive regret to those who suffered inconvenience from them, and were  always received more in sorrow than in anger,” Leslie wrote. “But these artificial rains were taken more in anger than in sorrow,  by all who did not want them.”


Leslie had identified the fundamental political  pitfalls of manufactured weather that dog it to this day. But the  enthusiasm for pluviculture was just beginning. During the Civil War, some  began to suspect that the smoke and concussion of artillery fire generated  rain. After all, didn’t it tend to rain a day, or two, or three  following most battles? Skeptics wondered whether generals simply preferred  to fight under fair skies, with rainy days therefore tending naturally to  follow, and some pointed out that Plutarch had noticed the correlation  between battles and rainfall long before the invention of gunpowder.  Nevertheless, in 1871 retired Civil War general Edward Powers argued in favor of cannonading in his book War and the  Weather, or, The Artificial Production of Rain.


Two decades later, the publication of the second  edition of Powers’s book coincided with a severe and prolonged  western drought, prompting a congressional appropriation of $10,000 for a  series of field experiments. Secretary of Agriculture Jeremiah Rusk,  nominally in charge of both this project and the newly formed U.S. Weather Bureau, chose  as the lead investigator Robert St. George Dyrenforth, a flamboyant patent  lawyer from Washington, D.C., who possessed no scientific or military  experience. Dyrenforth arrived in Texas in August during a severe drought,  but also conveniently at the traditional (and commonly noted) onset of the  Texas rainy season. He brought an arsenal of explosives, including bombs,  cannon, and hydrogen balloons, to be detonated at various altitudes, and  engaged in what one observer called “a beautiful imitation of a battle.”


After several months of assaults on the heavens, it  did indeed rain. Dyrenforth claimed victory, concluding that his practical  skills, combined with his use of special explosives “to keep the weather in an unsettled condition,” could cause or at least enhance  ­pre cipitation— when conditions were favorable! He   warned that bombarding the sky in dry weather, however, would be fruitless, since his technique could stimulate clouds and precipitation but  not create ­them.

The Nation, which criticized the government for  wasting tax dollars, observed that the effect of the explosion of a 10-foot  hydrogen balloon on aerial currents would be less than “the effect of  the jump of one vigorous flea upon a ­thousand- ton steamship  running at a speed of twenty knots.” But if there is one lesson from  the long history of efforts to modify the weather and climate, it is that neither ­common sense criticism nor flops deter ­geoengineers.

Just over 100 years after  Espy arrived in Washington, another seminal episode in the history of weather and climate control commenced at the General Electric Research  Laboratory in Schenectady, New York. On a warm, humid day in 1946, a  laboratory technician named Vincent Schaefer dropped some dry ice into a  home freezer unit he was using as a cloud chamber. To his surprise, he saw  the moisture in his breath instantly transform into millions of tiny ice  crystals. He had generated the ice cloud from “supercooled”  water droplets. As Schaefer recalled, “It was a serendipitous event,  and I was smart enough to figure out just what happened. . . . I knew I had something pretty important.” Soon after, another member of the GE  team, Bernard Vonnegut of MIT, discovered that silver iodide smoke also  “caused explosive ice growth” in supercooled ­clouds.

On November 14, 1946, Schaefer rented an airplane and  dropped six pounds of dry ice pellets into a cold cloud over Mount Greylock  in the nearby Berkshires, creating ice crystals and streaks of snow along a  ­three- mile path. According to Schaefer’s laboratory  notebook, “It seemed as though [the cloud] almost exploded, the  effect was so widespread and rapid.” Schaefer’s boss was Nobel laureate Irving Langmuir, a chemist who had worked on generating military  smoke screens and de-icing aircraft in World War II—and who did not  lack for media savvy. Langmuir watched the experiment from the control  tower of the airport, and he was on the phone to the press before Schaefer  landed. According to an article in The New York  Times the next day, “A single pellet of dry ice, about the size of a pea . . . might produce enough ice nuclei to  develop several tons of snow,” or perhaps eliminate clouds at  airports that might cause dangerous icing conditions, thus, in the words of  the story’s headline, “Opening Vista of Moisture Control by  Man.” The Boston Globe headline read “Snowstorm Manufactured.”


From this moment on, in the press and before the  meteorological community, Langmuir expounded his sensational vision of ­large- scale weather  control, including redirecting hurricanes and changing the arid Southwest  into fertile farmland. His first paper on the subject used familiar military terminology to explain how a small amount of “nucleating” agent such  as dry ice, silver iodide, or even water could cause a “chain  reaction” in cumulus clouds that potentially could release as much  energy as an atomic bomb, but without radioactive fallout. The Department  of Defense took due note. It would take an intense interest in the military  possibilities of weather modification in the years ­ahead.

Ironically, in 1953, at the very same time Langmuir  was involved in making exaggerated and highly dubious claims for the  efficacy of weather and climate modification, he presented a seminar at GE  titled “Pathological Science,” or “the science of things  that aren’t so.” Yet there is hardly any scientific foundation  for most claims about weather modification. Cloud seeding apparently can augment “orographic” precipitation (which falls on the windward  side of mountains) by up to 10 percent. It is also possible to clear cold  fogs and suppress frost with heaters in very small areas. That is the  extent of what has been proved. Nevertheless, millions are still spent on  cloud seeding today, largely by local water and power companies.

About the time Langmuir was giving his seminar, the  great futurist and science-
fiction writer H. G. Wells toured the GE  labs, and the young publicist who escorted him tried to interest the writer  in its weather control re search. Wells gave a ­luke warm  response. The young man was Bernard Vonnegut’s brother, Kurt, and he  took up the subject himself in the novel Cat’s Cradle (1963), in which a quirky and  amoral scientist named Felix  loosely modeled on both Irving Langmuir and Edward Teller, invents a substance called  ­“ice- nine” that in stantly freezes water and  remains solid at room temperature. Hoenikker’s intent is to create a  material that would be useful to armies bogged down in muddy battlefields,  but the result is an unprecedented ecological disaster. Vonnegut got the  idea of ­ice- nine from Langmuir, who suggested it to Wells as a  story line.

Weather modification technology seemed of such great  potential, especially to military aviation, that Vannevar Bush, a friend of  Langmuir’s who had served as head of the Office of Scientific Research and Development during World War II, brought the issue to the  attention of Secretary of Defense George C. Marshall and General Omar  Bradley, chairman of the Joint Chiefs of Staff. The Pentagon immediately  convened a committee to study the development of a Cold War weather weapon.  It was hoped that cloud seeding could be used surreptitiously to release  the violence of the atmosphere against an enemy, tame the winds in the  service of an ­all- weather air force, or, on a larger scale,  perhaps disrupt (or improve) the agricultural economy of nations and alter  the global climate for strategic purposes. Military planners generated  strategic scenarios such as hindering the enemy’s military campaigns  by causing heavy rains or snows to fall along lines of troop movement and  on vital airfields, or using controlled precipitation as a delivery system  for biological and radiological agents. Tactical possibilities included  dissipating cloud decks to enable visual bombing attacks on targets,  opening airfields closed by low clouds or fog, and relieving aircraft  ­icing.

Some in the military had already recognized the  potential uses of weather modification, and the subject has remained on  military minds ever since. In the 1940s, General George C. Kenney, commander of the Strategic Air Command, declared, “The nation which  first learns to plot the paths of air masses accurately and learns to  control the time and place of precipitation will dominate the globe.”  His opinion was echoed in 1961 by the distinguished  ­aviator- engineer Rear Admiral Luis de Florez: “With control  of the weather the operations and economy of an enemy could be disrupted. .  . . [Such control] in a cold war would provide a powerful and subtle weapon  to injure agricultural production, hinder commerce, and slow down  industry.” He urged the government to “start now to make  control of weather equal in scope to the Manhattan . . . Proj ect which  produced the first ­A- bomb.”


Howard T. Orville, President Dwight D.  Eisenhower’s weather adviser, published an influential 1954 article  in Collier’s  that included a variety of scenarios for using weather as a weapon of warfare. Planes would drop hundreds of balloons containing seeding crystals  into the jet stream. Downstream, when the fuses on the balloons exploded,  the crystals would fall into the clouds, initiating rain and miring enemy  operations. The Army Ordnance Corps was investigating another technique:  loading silver iodide and carbon dioxide into 50-caliber tracer bullets  that pilots could fire into clouds. A more insidious technique would strike  at an adversary’s food supply by seeding clouds to rob them of  moisture before they reached enemy agricultural areas. Speculative and wildly optimistic ideas such as these from official sources, together with  threats that the Soviets were aggressively pursuing weather control,  triggered what Newsweek called “a weather race with the Russians,” and  helped fuel the rapid expansion of meteorological research in all areas, including the creation of the National Center for Atmospheric Research,  which was established in ­1960.

Weather warfare took a  ­macro- pathological turn between 1967 and ’72 in the jungles  over North and South Vietnam, Laos, and Cambodia. Using technology  developed at the naval weapons testing center at China Lake, California, to  seed clouds by means of silver iodide flares, the military conducted secret  operations intended, among other goals, to “reduce  trafficability” along portions of the Ho Chi Minh Trail, which Hanoi  used to move men and materiel to South Vietnam. Operating out of Udorn Air  Base, Thailand, without the knowledge of the Thai government or almost  anyone else, but with the full and enthusiastic support of presidents  Lyndon B. Johnson and Richard M. Nixon, the Air Weather Service flew more  than 2,600 cloud seeding sorties and expended 47,000 silver iodide flares  over a period of approximately five years at an annual cost of some $3.6 million. The covert operation had several names, including  “POPEYE” and “Intermediary-Compatriot.”


In March 1971, nationally syndicated columnist Jack  Anderson broke the story about Air Force rainmakers in Southeast Asia in The Washington  Post, a story confirmed several months later  with the leaking of the Pentagon Papers and splashed on the front page of The New York Times in 1972 by  Seymour Hersh. By 1973, despite stonewalling by Nixon administration  officials, the U.S. Senate had adopted a resolution calling for an  international treaty “prohibiting the use of any environmental or  geophysical modification activity as a weapon of war.” The following  year, Senator Claiborne Pell (D.-R.I.), referring to the field as a  “Pandora’s box,” published the transcript of a formerly  ­top- secret briefing by the Defense Department on the topic of  weather warfare. Eventually, it was revealed that the CIA had tried  rainmaking in South Vietnam as early as 1963 in an attempt to break up the  protests of Buddhist monks, and that cloud seeding was probably used in  Cuba to disrupt the sugarcane harvest. Similar technology had been  employed, yet proved ineffective, in drought relief efforts in India and  Pakistan, the Philippines, Panama, Portugal, and Okinawa. All of the  programs were conducted under military sponsorship and had the direct involvement of the White ­House.

Operation POPEYE, made public as it was at the end of  the Nixon era, was dubbed the “Watergate of weather warfare.”  Some defended the use of environmental weapons, arguing that they were more  “humane” than nuclear weapons. Others suggested that inducing  rainfall to reduce trafficability was preferable to dropping napalm. As one  wag put it, “Make mud, not war.” At a congressional briefing in  1974, military officials downplayed the impact of Operation POPEYE, since  the most that could be claimed were 10 percent increases in local rainfall,  and even that result was “unverifiable.” Philip Handler,  president of the National Academy of Sciences, represented the mainstream  of scientific opinion when he observed, “It is grotesquely immoral  that scientific understanding and technological capabilities developed for  human welfare to protect the public health, enhance agricultural  productivity, and minimize the natural violence of large storms should be  so distorted as to become weapons of war.”


At a time when the United States was already weakened  by the Watergate crisis, the Soviet Union caused considerable embarrassment  to the Ford administration by bringing the issue of weather modification as  a weapon of war to the attention of the United Nations. The UN Convention  on the Prohibition of Military or Any Other Hostile Use of Environmental Modification  Techniques (ENMOD) was eventually ratified by nearly 70 nations, including  the United States. Ironically, it entered into force in 1978, when the Lao  People’s Democratic Republic, where the American military had used  weather modification technology in war only six years earlier, became the  20th signatory.

The language of the ENMOD Convention may become  relevant to future weather and climate engineering, especially if such  efforts are conducted unilaterally or if harm befalls a nation or region.  The convention targets those techniques having “widespread,  longlasting or severe effects as the means of destruction, damage, or  injury to any other State Party.” It uses the term “environmental modification” to mean “any technique for  ­changing— through the deliberate manipulation of natural  ­processes— the dynamics, composition, or structure of the  Earth, including its biota, lithosphere, hydrosphere, and atmosphere, or of  outer space.”


A vision of perfect  forecasting ultimately leading to weather and climate control was present  at the birth of modern computing, well before the GE cloud seeding  experiments. In 1945 Vladimir Zworykin, an RCA engineer noted for his early  work in television technology, promoted the idea that electronic computers  could be used to process and analyze vast amounts of meteorological data,  issue timely and highly accurate forecasts, study the sensitivity of  weather systems to alterations of surface conditions and energy inputs, and  eventually intervene in and control the weather and climate. He ­wrote:



The eventual goal to be attained is the international  organization of means to study weather phenomena as global phenomena and to  channel the world’s weather, as far as possible, in such a way as to  minimize the damage from catastrophic  disturbances, and otherwise to benefit the world to the greatest extent by  improved climatic conditions where ­possible.

Zworykin imagined that a perfectly accurate machine  forecast combined with a ­para military rapid deployment force able  literally to pour oil on troubled ocean waters or even set fires or  detonate bombs might someday provide the capacity to disrupt storms before  they formed, deflect them from populated areas, and otherwise control the  ­weather.

John von Neumann, the multi-talented mathematician  extraordinaire at the Institute for Advanced Study in Princeton, New  Jersey, endorsed Zworykin’s view, writing to him, “I agree with  you completely. . . . This would provide a basis for scientific  approach[es] to influencing the weather.” Using  ­computer- generated predictions, von Neumann wrote, weather and  climate systems “could be controlled, or at least directed, by the  release of perfectly practical amounts of energy” or by “altering the absorption and reflection properties of the ground or  the sea or the atmosphere.” It was a project that neatly fit von  Neumann’s overall philosophy: “All stable processes we shall predict. All unstable processes we shall control.”  Zwory kin’s proposal was also endorsed by the noted oceanographer  Athelstan Spilhaus, then a U.S. Army major, who ended his In weather control meteorology  has a new goal worthy of its greatest efforts.”


In a 1962 speech to meteorologists, “On the  Possibilities of Weather Control,” Harry Wexler, the  ­MIT- trained head of meteorological research at the U.S. Weather  Bureau, reported on his analysis of early computer climate models and  additional possibilities opened up by the space age. Reminding his audience  that humankind was modifying the weather and climate “whether we know  it or not” by changing the composition of the earth’s  atmosphere, Wexler demonstrated how the United States or the Soviet Union,  perhaps with hostile intent, could alter the earth’s climate in a  number of ways. Either nation could cool it by several degrees using a dust  ring launched into orbit, for example, or warm it using ice crystals lofted  into the polar atmosphere by the explosion of hydrogen bombs. And while  most practicing atmospheric chemists today believe that the discovery of  ozone-destroying reactions dates to the early 1970s, Wexler sketched out a  scenario for destroying the ozone layer using chlorine or bromine in his  1962 ­speech.

“The subject of weather and climate control is  now becoming respectable to talk about,” Wexler claimed, apparently  hoping to reduce the prospects of a geophysical arms race. He cited Soviet premier Nikita Khrushchev’s mention of weather control in an address  to the Supreme Soviet and a 1961 speech to the United Nations by John F.  Kennedy in which the president proposed “cooperative efforts between  all nations in weather prediction and eventually in weather control.” Wexler was actually the source of Kennedy’s suggestions, and had  worked on them behind the scenes with the President’s Science  Advisory Committee and the State Department. But if weather control’s  “respectability” was not in question, its  ­attainability— even using computers, satellites, and  100-megaton ­bombs— certainly ­was.

In 1965, the  President’s Science Advisory Committee warned in a report called Restoring the Quality of Our Environment that increases in atmospheric carbon dioxide due to the burning  of fossil fuels would modify the earth’s heat balance to such an  extent that harmful changes in climate could occur. This report is now  widely cited as the first official statement on “global warming.” But the committee also recommended geoengineering options.  “The possibilities of deliberately bringing about countervailing  climatic changes . . . need to be thoroughly explored,” it said. As  an illustration, it pointed out that, in a warming world, the earth’s  solar reflectivity could be increased by dispersing buoyant reflective  particles over large areas of the tropical sea at an annual cost, not  considered excessive, of about $500 million. This technology might also  inhibit hurricane formation. No one thought to consider the side effects of  particles washing up on tropical beaches or choking marine life, or the  negative consequences of redirecting hurricanes, much less other effects  beyond our imagination. And no one thought to ask if the local inhabitants  would be in favor of such schemes. The committee also speculated about  modifying high-altitude cirrus clouds to counteract the effects of  increasing atmospheric carbon dioxide. It failed to mention the most  obvious option: reducing fossil fuel ­use.

After the embarrassment of the 1978 ENMOD Convention,  federal funding for weather modification research and development dried up,  although freelance rainmakers continued to ply their trade in the American  West with state and local funding. Until recently, a 1991 National Academy  of Sciences report, Policy Implications of  Greenhouse Warming, was the only serious  document in decades to advocate climate control. But the level of urgency  and the number of proposals have increased dramatically since the turn of  the new ­century.

In September 2001, the U.S. Climate Change Technology  Program quietly held an invitational conference, “Response Options to  Rapid or Severe Climate Change.” Sponsored by a White House that was  officially skeptical about global warming, the meeting gave new status to  the control fantasies of the climate engineers. According to one  participant, “If they had broadcast that meeting live to people in  Europe, there would have been riots.”


Two years later, the Pentagon released a controversial  report titled An Abrupt Climate Change Scenario  and Its Implications for United States National Security. The report explained how global warming might lead to rapid and  catastrophic global cooling through mechanisms such as the slowing of North  Atlantic deep-water ­circulation— and recommended that the  government “explore ­geo engineering options that control the  climate.” Noting that it is easier to warm than to cool the climate,  the report suggested that it might be possible to add various gases, such  as  to the atmosphere to offset the  effects of cooling. Such actions would be studied carefully, of course,  given their potential to exacerbate conflict among ­nations.

With greater gravitas, but no less speculation, the  National Research Council issued a study, Critical  Issues in Weather Modification Research, in  2003. It cited  looming social and environmental challenges such as water shortages and  drought, property damage and loss of life from severe storms, and the  threat of “inadvertent” climate change as justifications for  investing in major new national and international programs in weather  modification research. Although the NRC study included an acknowledgment  that there is “no convincing scientific proof of the efficacy of  intentional weather modification efforts,” its authors nonetheless  argued that there should be “a renewed commitment” to research  in the field of intentional and unintentional weather ­modification.

The absence of such proof  after decades of efforts has not deterred governments here and abroad from  a variety of ­ill- advised or simply fanciful undertakings. The  NASA Institute for Advanced Concepts, for example, has provided $475,000  for atmospheric scientist Ross Hoffman’s research on beaming  ­satellite- based microwaves at hurricanes as a means of  redirecting ­them— as if it were possible to know where a  storm was originally headed or that its new path would not lead straight to  calamity. In 2005, Senator Kay Bailey Hutchison (R.-Texas) introduced  legislation “to develop and implement a comprehensive and coordinated  national weather modification research policy and a national cooperative  Federal and State program of weather modification and development.”  (Significantly, the Texas Department of Agriculture already supports  weather modification programs covering one-fifth of the state.) And China  has announced that its Study Institute for Artificial Influence on the  Weather will attempt to manipulate Beijing’s weather by cloud seeding  in order to ensure optimum conditions for the 2008 Olympics.

With great fanfare, atmospheric chemist Paul J.  Crutzen, winner of a 1995 Nobel Prize for his work on the chemistry of  ozone depletion, recently proposed to cool the earth by injecting  reflective aerosols or other substances into the tropical stratosphere  using balloons or artillery. He estimated that more than five million  metric tons of sulfur per year would be needed to do the job, at an annual  cost of more than $125 billion. The effect would emulate the 1991 eruption  of Mount Pinatubo in the Philippines, which covered the earth with a cloud  of sulfuric acid and other sulfates and caused a drop in the planet’s  average temperature of about 0.5°C for roughly two years. Unfortunately, Mount Pinatubo may also have contributed to the largest  ozone hole ever measured. The volcanic eruption was also blamed for causing  cool, wet summers, shortening the growing season, and exacerbating  Mississippi River flooding and the ongoing drought in the Sahel region of  ­Africa.

Overall, the cooling caused by Mount Pinatubo’s  eruption temporarily suppressed the greenhouse warming effect and was  stronger than the influence of the El Niño event that occurred at  the same time. Crutzen merely noted that if a Mount  ­Pinatubo– scale eruption were emulated every year or two,  undesired side effects and ozone losses should not be “as  large,” but some whitening of the sky and colorful sunsets and  sunrises would occur. His “interesting alternative” method  would be to release soot particles to create minor “nuclear  winter” ­conditions.

Crutzen later said that he had only reluctantly  proposed his planetary “shade,” mostly to “startle” political leaders enough to spur them to more serious efforts to curb  greenhouse-gas emissions. But he may well have produced the opposite  effect. The appeal of a quick and seemingly painless technological  “fix” for the global climate dilemma should not be  underestimated. The more practical such dreams appear, the less likely the  world’s citizens and political leaders are to take on the difficult  and painful task of changing the destiny that global climate models  ­foretell.

These issues are not new.  In 1956, F. W. Reichel derfer, then chief of the U.S. Weather Bureau, delivered an address to the National Academy of Sciences, “Importance  of New Concepts in Meteorology.” Reacting to the widespread  theorizing and speculation on the possibilities of weather and climate  control at the time, he pointed out that the crucial issue was  “practicability” rather than “possibility.” In 1956  it was possible to modify a cloud with dry ice or silver iodide, yet it was  impossible to predict what the cloud might do after seeding and  impracticable to claim any sense of control over the weather. This is still  true today. Yet thanks to remarkable advances in science and technology,  from satellite sensors to enormously sophisticated global climate models, the fantasies of the weather and climate engineers have only grown. Now it  is possible to tinker with scenarios in computer climate  models— manipulating the solar inputs, for example, to demonstrate that artificially increased solar reflectivity will generate a  cooling trend in the ­model.

But this is a far cry from conducting a practical  global field experiment or operational program with proper data collection  and analysis; full accounting for possible liabilities, unintended consequences, and litigation; and the necessary international support and  approval. Lowell Wood blithely declares that if his proposal to turn the  polar icecap into a planetary air conditioner were implemented and  didn’t work, the process could be halted after a few years. He  doesn’t mention what harm such a failure could cause in the  ­meantime.

There are signs among the geoengineers of an  overconfidence in technology as a solution of first resort. Many appear to  possess a too-literal belief in progress that produces an  ­anything- is-­possible mentality, abetted by a basic  misunderstanding of the nature of today’s climate models. The global  climate system is a “massive, staggering beast,” as  oceanographer Wallace Broecker describes it, with no simple set of  controlling parameters. We are more than a long way from understanding how  it works, much less the precise prediction and practical  “control” of global ­climate.

Assume, for just a moment, that climate control were  technically possible. Who would be given the authority to manage it? Who  would have the wisdom to dispense drought, severe winters, or the effects  of storms to some so that the rest of the planet could prosper? At what  cost, economically, aesthetically, and in our moral relationship to nature,  would we manipulate the ­climate?

These questions are never seriously contemplated by  the climate wizards who dream of mastery over nature. If, as history shows,  fantasies of weather and climate control have chiefly served commercial and  military interests, why should we expect the future to be different? Have  you noticed all the cannons? From Dyrenforth’s cannonading in Texas  to Crutzen’s artillery barrage of the stratosphere, military means  and ends have been closely intertwined with thinking about control of the  weather and climate. In 1996 the U.S. Air Force resurrected the old Cold  War speculation about using weather modification for military purposes,  claiming that “in 2025, U.S. aerospace forces can ‘own the  weather’ by capitalizing on emerging technologies and focusing development of those technologies to ­war- fighting  applications.” In addition to conventional cloud seeding methods, the  Air Force visionaries proposed computer hacking to disrupt an enemy’s weather monitors and models and the use of emerging technologies to create  clouds of particles that could block an enemy’s optical sensors.  Hurricanes were also fair game for weaponization. The Air Force pointed out  that weather modification, unlike other approaches, “makes what are otherwise the results of deliberate actions appear to be the consequences  of natural weather phenomena.”


Given such mindsets, it is virtually impossible to  imagine governments resisting the temptation to explore military uses of  any potentially ­climate- altering ­technology.

When Roger Angel was asked  at the NASA meeting last November how he intended to get the massive amount  of material required for his space mirrors into orbit, he dryly suggested a  modern cannon of the kind originally proposed for the Strategic Defense  Initiative: a giant electric rail gun firing a ton or so of material into  space roughly every five minutes. Asked where such a device might be  located, he suggested a high mountaintop on the Equator.

I was immediately re minded of Jules Verne’s  1889 novel The Purchase of the North Pole. For two cents per acre, a group of American investors gains  rights to the vast and incredibly lucrative coal and mineral deposits  un der the North Pole. To mine the region, they propose to melt the  polar ice. Initially the project captures the public imagination, as the  backers promise that their scheme will improve the climate everywhere by  reducing extremes of cold and heat, making the earth a terrestrial heaven.  But when it is revealed that the investors are retired Civil War  artillerymen who intend to change the inclination of the earth’s axis  by building and firing the world’s largest cannon, public enthusiasm  gives way to fears that tidal waves generated by the explosion will kill millions. In secrecy and haste, the protagonists proceed with their plan,  building the cannon on Mount Kilimanjaro. The plot fails only when an error  in calculation renders the massive shot ineffective. Verne concludes,  “The world’s inhabitants could thus sleep in peace.”  Perhaps he spoke too soon.