Abstract: The Islamic State is actively seeking weapons of mass destruction and, to a limited extent, it has used such weapons in Syria and Iraq. It is also actively seeking personnel with technical experience capable of expanding its program. The Islamic State’s program faces many challenges and logistical issues, however, that have tempered their ambitions. This means the group is not yet capable of striking Western nations with WMD, though it cannot be ruled out that the Islamic State could deploy rudimentary chemical devices against the West in the next several years.
“If Muslims cannot defeat the kafir (unbelievers) in a different way, it is permissible to use weapons of mass destruction, even if it kills all of them and wipes them and their descendants off the face of the Earth.”
—Saudi jihadi cleric Nasir al-Fahd.[1]
On November 19, 2015, a day after French police thwarted a second-wave attack by Islamic State terrorists in Paris, France’s Prime Minister Manuel Valls raised the specter of the Islamic State deploying weapons of mass destruction (WMD) against the West. “I say it with all the precautions needed. But we know and bear in mind that there is also a risk of chemical or bacteriological weapons,” he told the French parliament.[2] Australia’s Foreign Minister Julie Bishop had earlier sounded the alarm on chemical weapons in June 2015:
“The counter-terrorism landscape is changing so rapidly that long accepted paradigms can quickly become obsolete. Apart from some crude and small-scale endeavors, the conventional wisdom has been that the terrorist intention to acquire and weaponize chemical agents has been largely aspirational. The use of chlorine by Daesh and its recruitment of highly technically trained professionals, including from the West, have revealed far more serious efforts in chemical weapons development. Daesh is likely to have amongst its tens of thousands of recruits the technical expertise necessary to further refine precursor materials and build chemical weapons.”[3]
In light of these warnings and the Islamic State’s documented use of crude WMD devices in Syria and Iraq, this article explores what is known about the group’s WMD capabilities and the current logistical challenges that are containing its ambitions in this area. The article outlines how despite current intentions and active recruitment of technically trained personnel, the Islamic State is not yet capable of striking Western nations with WMD, though it cannot be ruled out that the Islamic State could deploy rudimentary chemical devices against the West in the next several years.
Nuclear
Among WMD, nuclear weapons cause the largest amount of destruction, yet they are the most difficult to develop or obtain. To develop a nuclear weapon, the Islamic State would first require enough fissile material[a] to support a sustained chain reaction. The specific quantity required is determined by the weapon design, but generally involves several kilograms of highly enriched uranium. The other significant limiting factor is the scores of physicists, engineers, and metallurgists required to construct the device. Fighting over the past five years throughout Iraq and Syria has created an intellectual drain in the region. In the distant chance that the Islamic State could assemble nuclear scientists to develop the weapon, it would have to conduct tests on weapon designs and construction methods in order to confirm that a nuclear detonation would actually occur in the final device.[b] These tests would easily be detected by intelligence, surveillance, and reconnaissance assets (ISR), which would presumably trigger a kinetic response from other parties.
Since the Islamic State lacks the personnel and material to build a nuclear weapon, purchase on the black market becomes the most likely path to acquisition. The Islamic State raised this possibility with its May 2015 claim that “it could buy a nuclear weapon through Pakistan within the coming year.”[5] Although the assertion sounds far-fetched, the group has significant liquid assets from oil sales and other sources of revenue.[6] These assets imply that funding is likely not the greatest barrier to purchase of a weapon. The key barrier is availability of material and identification of a willing seller.
The extent of the global nuclear smuggling network was recently highlighted in media coverage of the five-year, joint Moldovan government and FBI probe into the “thriving nuclear black market that has emerged in an impoverished corner of Eastern Europe.”[7] In one instance a sample of uranium that could be used in an atomic bomb was seized.[8] Regrettably, as the coverage noted, most arrests occurred after only a small sample of nuclear material was exchanged; the larger stockpiles from which the samples were taken may remain for sale. The confluence of existing nuclear smuggling networks, the willingness of actors to sell material, even to extremists, and the Islamic State’s financial capabilities increase the likelihood that the group could acquire a nuclear device. However, notwithstanding its desire to possess nuclear weapons, the probability of the Islamic State obtaining and deploying a device remains low.
Radiological
Radiological dispersion devices (RDDs) are likely the only radioactive weapons that the Islamic State could employ. Far more simplistic in design than nuclear weapons, these devices feature radioactive material intermixed with conventional explosives. Though they do not produce the mass-destruction characteristics of nuclear weapons such as shock waves, fires, and electro-magnetic pulses, RDDs create psychological impact on affected populations. They are most effective when detonated in densely populated areas; otherwise, the dispersion of radioactive material would do little more than prevent access to the area for a period of time. To attack the West the Islamic State would be required to export an RDD, drastically increasing the risk of detection through ISR and human intelligence.
The black market is one avenue for the Islamic State to obtain materials that could be used in a radiological device. In the cases investigated in Moldova, nuclear smugglers were purportedly ready to sell Cesium 137 to what they believed was a representative of the Islamic State.[9]
Within the area controlled by the Islamic State, there are two potential sources of radiological material: research facilities at universities and medical devices. Most of the material used in scientific research and medical diagnostics contain limited quantities of radioactive material. A material of concern is cobalt-60, which is used in medical devices and emits gamma radiation. In December 2013, a cargo truck carrying hospital equipment containing cobalt-60 was stolen from a gas station in Mexico.[10] The theft prompted concern among U.S. intelligence agencies that the material could be converted into a dirty bomb. Prolonged exposure to cobalt-60 can be deadly; the timeframe of lethality ranges from minutes to hours depending on the level of shielding.
Since RDDs are no more complicated than an improvised explosive device, the Islamic State certainly has the capability to develop them. There are two significant obstacles preventing the employment of such a device in the West. One, there is no evidence the Islamic State has gathered the necessary radiological material, and two, it lacks access to the target. To transport and move an RDD to a target increases the risk of detection similar to the limits of transporting a nuclear weapon. The detonation of an RDD would have a greater psychological impact on the affected population compared to the physical damage caused by the device. Subsequently, the risk of the Islamic State building an RDD is greater than that of a nuclear weapon, however the risk of actual deployment remains low.
Biological
There is little doubt that the Islamic State would like to possess and use biological weapons. A laptop recovered by moderate Syrian rebels during a 2014 raid on the Islamic State stronghold of Idlib allegedly contained files instructing Islamic State on the preparation and use of biological weapons. The laptop also contained safety instructions for the development of microbes in order to protect Islamic State technicians from exposure.[11]
Despite the consistent reiteration of its desire to possess biological weapons, the Islamic State faces significant practical challenges. Like nuclear weapons, the development of biological weapons requires sophisticated personnel and technology that are not readily available in Iraq and Syria. The group could conceivably purchase and smuggle the materials needed to set up a biological weapons lab, however scale would become a significant obstacle given that effective production levels require a facility about the size of a large research lab with the corresponding infrastructure. The Islamic State would also have to contend with quality control issues as well. The power grid and generators in Iraq and Syria are not sufficiently reliable for the refrigerators and incubators needed to weaponize biological agents.[c]
In regard to the difficulties of biological weaponization, the 2014 Ebola crisis in Western Africa proves instructive. The spread of Ebola gave rise to concerns that the Islamic State would attempt to use Ebola-infected individuals as delivery systems for the virus. This non-traditional transfer mechanism could, in theory, infect people around the world. The reality is far different, however. When first infected with a virus, individuals have a low titer count (the concentration of virus in the blood). Once inside the host individual, the virus invades cells and replicates. This progressively leads to higher levels of virus in the body and a corresponding escalation of symptoms. At low levels, the individual is relatively non-contagious and appears normal. It is at the later stages of the infection that the individual is most contagious, but also the most sick and debilitated. Such highly infected host individuals are easily identifiable and often barely able to function, let alone able to execute a clandestine infection strategy. Diseases are not limited by national or regional borders. The introduction of a pathogen in a developed nation would be rapidly detected through bio-surveillance networks.
Biological weapons are very unlikely to be developed by the Islamic State as a mass casualty tool. Western medical countermeasures and response capabilities were able to handle the 2001 anthrax attack and quickly contain Ebola in the United States in 2014. All this suggests the impact of a deliberate biological attack by the Islamic State in the West would be extremely limited.
Chemical
In 2013, the Syrian government deployed chemical munitions against rebels multiple times. International pressure following these attacks forced the Assad regime to join the Organization for the Prohibition of Chemical Weapons (OPCW) and turn over all chemical weapon stockpiles. According to the OPCW, the Syrian government declared 1,308,021 kilograms[11] of both category 1 and 2 chemicals,[d] and the OPCW oversaw the destruction of 98.8% of those declared category 1 and 2 chemical weapons.
Various media reports indicate that the Islamic State is currently employing chemical weapons, specifically mustard agent.[12] These reports also reveal, however, that the agent is crude and has not produced the mass effects typical of a state-run program. There are also signs that the Islamic State “has developed at least a small-scale chemical weapons program, and may have manufactured low-quality blister agent or obtained chemical arms from undeclared or abandoned government [Syrian] stocks.”[13] The possibility that the chemical weapons used may have come from material at undeclared Syrian stockpiles has been documented in various media sources.[14] Examining samples of both the Syrian stockpile and the Islamic State’s chemical weapons would reveal not only whether this was true, but also information about potency and persistence, which is the ability of the agent to linger in the environment before environmental factors cause its breakdown.[e]
One concern is that the Islamic State may take advantage of recruits with knowledge of previous state-run chemical weapons programs in Iraq and Syria. In January 2015, a coalition air strike killed Abu Malik, an Islamic State chemical weapons engineer who had worked at Saddam Hussein’s Muthana chemical weapon program before joining the predecessor group to the Islamic State in 2005. According to U.S. Central Command, “his past training and experience provided the terrorist group with expertise to pursue a chemical weapons capability,” and his death was “expected to temporarily degrade and disrupt the terrorist network and diminish ISIL’s ability to potentially produce and use chemical weapons.”[15]
With the Islamic State’s willingness to use chemical weapons, western nations should be concerned that the group or individuals acting on behalf of the group would attempt to deploy a poison gas device. If it did, the Islamic State would not be the first to attack on a western nation with chemical weapons. The Aum Shinrikyo released sarin in the Tokyo subway on March 20, 1995.
Before 9/11, al-Qa`ida began developing a device called mubtakkar, meaning “invention” in Arabic, to disseminate hydrogen cyanide and other toxic gases. According to journalist Ron Suskind, in 2003 al-Qa`ida operatives in Saudi Arabia plotted to use a poison gas device in the New York City subway system but aborted the plot after the group’s then-deputy, Ayman al-Zawahiri, decided not to “green light” it. The cell had planned to disperse quantities of hydrogen cyanide gas or another poisonous gas.[16] [f] The simplicity of the design and the relative ease of obtaining some of the chemicals makes it a plot the Islamic State could mimic.
There are several constraints associated with developing chemical weapons. Chemicals such as hydrogen cyanide, sarin, and their precursors are highly corrosive and require storage in highly controlled environments. For example, high temperatures and humidity will affect both the chemical reactions used to make the warfare agents and their effectiveness. The corrosive nature of these agents also makes long-term storage and transportation over long distances very difficult without the appropriate containers and proper environment. When placed in a container, the agents will immediately begin to eat away at rubber seals and the container itself, making leaks inevitable. Such constraints make it likely that any agents developed by the Islamic State would most likely be deployed immediately after manufacture and within close proximity to the territory it holds.
While it cannot be ruled out that the Islamic State could deploy a rudimentary poison gas device against the West in the next several years, the group would likely need to build the device near the location of the planned attack, requiring it to recruit or plant its own chemists in the West, not an easy feat.
Moving forward, the Islamic State will most likely continue to employ its limited chemical weapon munitions in both Syria and Iraq while seeking the capacity to expand its program to strike at major targets in the West.
Conclusion
The Islamic State’s potential use of WMD poses a greater psychological threat than physical threat to its enemies. While the Islamic State continues to seek and develop WMD, its progress will be constrained by reality. Despite seeking technical expertise and having large sums of liquid assets at its disposal, the Islamic State’s logistical capabilities and support structure in Western nations is limited. Containing the Islamic State needs to remain a priority, however, as further territorial expansion provides an opportunity to acquire new materials.
The Islamic State will continue to employ the simplest and most readily available WMD at their disposal—chemical weapons. The proliferation of this program remains a concern especially with the availability of toxic industrial chemicals that could be modified and dispersed in a chemical attack. While the effects of such devices would be limited to a small geographic area, the psychological impact to a Western nation, for example, would be significant. Current conditions in Syria and Iraq in conjunction with international ISR assets constantly monitoring the area reduce the possibility that the Islamic State will be able to develop any other WMD beyond chemical weapons.
Captain Stephen Hummel is a FA52 officer and currently serving as an instructor in the Chemistry and Life Science Department at the U.S. Military Academy, West Point. Captain Hummel previously served in both Iraq and Afghanistan and as the USAREUR CBRN plans officer. He is also the author of the 2015 book STRIKE: A Firsthand Account of the Largest Operation of the Afghan War.
Substantive Notes
[a] Fissile material refers to “a nuclide that is capable of undergoing fission after capturing low-energy thermal (slow) neutrons.”3 Capturing a neutron displaces other neutrons from the capturing material, which leads to interaction with adjacent atoms, which in turn displaces other neutrons. This creates a sustained chain reaction that releases large amounts of energy. The three primary fissile materials are uranium-233, uranium-235, and plutonium-239. “Fissile Material.” United States Nuclear Regulatory Commission, updated November 30, 2015.
[b] Tests are required to ensure fidelity of the design and build. Such tests do not entail detonation of a full-scale nuclear weapon but rather components of the weapon such as the trigger.
[c] Considering the Islamic State’s tremendous liquid assets, it could be possible for them to purchase the required generators and refrigerators. The process to grow and culture biological agents is neither short nor easy. The equipment required to culture large amounts of biological agents to be used in an attack would need to run for months and the culture areas must be completely sterile and within strict temperature ranges. Logistically, this is extremely difficult. Major research institutions in the West regularly struggle with maintaining sterile environments and contend with failing equipment that runs constantly. Without a reliable power grid, the Islamic State must then provide fuel to the generators, and although the group possesses vast amounts of oil, this does not mean it has the refinery capability to convert crude oil into gas. Furthermore, the equipment would need regular maintenance in a dry, dusty environment. Consequently, it would be an extreme logistical challenge for the Islamic State to maintain the proper environment to culture biological materials.
[d] The Organization for the Prohibition of Chemical Weapons defines category 1 chemicals as munitions filled with schedule 1 chemical agents while category 2 chemicals are munitions filled with other toxic chemicals.
[e] If the mustard agent used in the recent attacks came from Syrian stockpiles, it could be confirmed by comparing the composition of components and impurities. A difference between the agents would indicate the inception and implementation of the Islamic State’s chemical weapon program. These impurities provide additional information about the potency, persistence, and absorption capabilities of the agents.
[f] Exposure to hydrogen cyanide gas at sufficiently high quantities is lethal within minutes. The LD50, or lethal dose to 50% of a population, is 2,000 parts per million, which corresponds to approximately 0.2% of the air as hydrogen cyanide. “Environmental & Health Effects: Cyanide Facts,” International Cyanide Management Code for the Fold Mining Industry.
Citations
[1] Harold Doornbos and Jenan Moosa, “Found: The Islamic State’s Terror Laptop of Doom,” Foreign Policy, August 28, 2014.
[2] Adam Withnall, “Paris attacks: Isis ‘chemical weapons’ warning issued by French PM Manuel Valls,” Independent, November 19, 2015.
[3] Speech by Australia Foreign Minister Julie Bishop to Australia Group Plenary, Perth, Australia, June 5, 2015.
[4] Lora Moftah, “ISIS Nuclear Weapon? Islamic State Claims It Can Buy Nukes From Pakistan Within A Year In Dabiq Propaganda Magazine.” International Business Times, May 23, 2015.
[5] Harriet Alexander and Alastair Beach, “How Isil is funded, trained, and operating in Iraq and Syria.” Telegraph, August 23, 2014.
[6] Desmond Butler and Vadim Ghirda, “Nuclear smugglers sought extremist buyers, investigation uncovers.” Associated Press, October 7, 2015.
[7] Ibid.
[8] Desmond Butler and Vadim Ghirda, “Nuclear smugglers sought extremist buyers, investigation uncovers.” Associated Press, October 7, 2015.
[9] Gabriela Martinez and Joshua Partlow, “Stolen cobalt-60 found in Mexico, thieves may be doomed.” Washington Post, December 5, 2013.
[10] Harold Doornbos and Jenan Moosa, “Found: The Islamic State’s Terror Laptop of Doom,” Foreign Policy, August 28, 2014.
[11] OPCW, Chemical Destruction Data as of July 25, 2015.
[12] Christopher John Chivers, “What an ISIS Chemical Strike Did to One Syrian Family,” New York Times, October 7, 2015.
[13] Ibid.
[14] Paul Blake, “US Official: ‘IS making and using chemical weapons in Iraq and Syria,’” BBC, September 11, 2015.
[15] “ISIL Chemical Weapons Expert Killed in Coalition Airstrike,” U.S. Central Command news release, January 30, 2015.
[16] Ron Suskind, The One Percent Doctrine: Deep Inside America’s Pursuit of Its Enemies Since 9/11, Simon and Schuster, New York, 2006; David Burnett, “Exclusive Book Excerpt: How an Al-Qaeda Cell Planned a Poison-Gas Attack on the N.Y. Subway,” Time, June 17, 2006. It should be noted that some analysts and former officials have questioned the reliability of some of the information on the plot in the book. But the details included here were confirmed to Paul Cruickshank by a former British intelligence source with knowledge of the plot. Author communications with Paul Cruickshank, January 2016.
