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20 March 2005
Source:
http://132.160.230.113:8080/revize/repository/CSSPrototype/simplelist/Planning_Scenarios__Exec_Summary_.pdf
Related: http://cryptome.info/hi-docs.htm
The complete text of the Planning Scenarios, referred to below, does not appear to have been made public. If it has, a pointer (or hardcopy) is invited. Send to jya@pipeline.com or if hardcopy to the send-to address here.
[55 pages.]
Version 2.0
PLANNING SCENARIOS
Executive Summaries
Created for Use in National, Federal, State,
and Local Homeland Security Preparedness Activities
The Homeland Security Council
David Howe, Senior Director for Response and Planning
July 2004
Contents
Scenario 1: Nuclear Detonation – 10-Kiloton Improvised Nuclear Device
Scenario 2: Biological Attack – Aerosol Anthrax
Scenario 3: Biological Disease Outbreak – Pandemic Influenza
Scenario 4: Biological Attack – Plague
Scenario 5: Chemical Attack – Blister Agent
Scenario 6: Chemical Attack – Toxic Industrial Chemicals
Scenario 7: Chemical Attack – Nerve Agent
Scenario 8: Chemical Attack – Chlorine Tank Explosion
Scenario 9: Natural Disaster – Major Earthquake
Scenario 10: Natural Disaster – Major Hurricane
Scenario 11: Radiological Attack – Radiological Dispersal Devices
Scenario 12: Explosives Attack – Bombing Using Improvised Explosive Device
Scenario 13: Biological Attack – Food Contamination
Scenario 14: Biological Attack – Foreign Animal Disease (Foot and Mouth Disease)
Appendix: Scenario Working Group Members
Introduction
The Homeland Security Council (HSC) – in partnership with the Department of Homeland Security (DHS), the federal interagency, and state and local homeland security agencies – has developed fifteen all-hazards planning scenarios for use in national, federal, state, and local homeland security preparedness activities. These scenarios are designed to be the foundational structure for the development of national preparedness standards from which homeland security capabilities can be measured. While these scenarios reflect a rigorous analytical effort by federal, state, and local homeland security experts, it is recognized that refinement and revision over time may be necessary to ensure the scenarios remain accurate, represent the evolving all-hazards threat picture, and embody the capabilities necessary to respond to domestic incidents.
This document includes executive summaries for the fifteen scenarios, and a separate document contains the complete scenario text.
General Considerations for the Scenarios:
The scenarios have been developed in a way that allows them to be adapted to local conditions throughout the country. Although certain areas have special concerns – continuity of government in Washington, D.C.; viability of financial markets in New York; and trade and commerce in other major cities – every part of the country is vulnerable to one or more major hazards.
Because the attacks could be caused by foreign terrorists; domestic radical groups; state-sponsored adversaries; or in some cases, disgruntled employees, the perpetrator has been named, the Universal Adversary (UA). The focus of the scenarios is on response capabilities and needs, not threat-based prevention activities.
Since these scenarios were compiled to be the minimum number necessary to test the range of response capabilities and resources, other hazards were inevitably omitted. Examples of other potentially high-impact scenarios include nuclear power plant incidents1, industrial and transportation accidents, and frequently occurring natural disasters. These either have well-developed and tested response plans, and/or the response would be a subset of the requirements for scenarios contained in this set.
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1 A severe incident at a nuclear power plant, whether or not it is terrorist-initiated, could result in a release of radioactive materials to the environment with adverse consequences to public health. Scenarios for such severe incidents have not been included in this scenario set because: (a) current federal regulations from the Nuclear Regulatory Commission and the DHS Federal Emergency Management Agency (FEMA) mandate robust emergency planning and preparedness for each nuclear plant to include the full range of response organizations; and (b) scenarios for nuclear plants cannot be generically extrapolated to other types of facilities (e.g., chemical plants).
Detailed assumptions for each scenario are provided in the full-text of this document but are not provided in this executive summary.
Intelligence Disclaimer –
While the intelligence picture developed as part of each scenario generally reflects suspected terrorist capabilities and known tradecraft, the Federal Bureau of Investigation (FBI) is unaware of any credible intelligence that indicates that such an attack is being planned, or that the agents or devices in question are in possession of any known terrorist group.
Ranking of Scenarios –
Various schemes have been used in the past to rank scenarios based on probability, number of casualties, extent of property damage, economic impact, and social disruption. Because the scenarios in this set were developed to test the full range of response capabilities and resources – and to assist federal, state, and local governments as well as the private sector in preparedness – they have not been ranked. Each jurisdiction or organization should apply its own priorities, based on its responsibilities within the domestic incident management structure.
Multiple Events –
There is a high probability that multiple incidents will occur simultaneously. When scoping resource requirements, organizations should always consider the need to respond to multiple incidents of the same type and multiple incidents of different types, at either the same or other geographic locations. These incidents will invariably require the coordination and cooperation of homeland security response organizations across multiple regional, state, and local jurisdictions.
The Homeland Security Advisory System –
The scenarios do not specify changes in the levels of the Homeland Security Advisory System (HSAS). However, in all scenarios other than natural disasters, it is anticipated that the alert level would increase. This increases the nation’s ability to respond to the current attack, reduces the vulnerability to future attacks, and helps citizens prepare to protect themselves. At higher alert levels, the HSAS has increased resource demands and can also have national economic impacts.
The “Worried Well” –
In most incidents, citizens will seek medical treatment even though they may not be injured by the incident. For example, in the World Trade Center incident on 9/11/01, the uninjured who sought medical treatment was approximately fifteen times the number of people who presented for medical treatment due to smoke inhalation; and in the Tokyo subway attack it was five times the number of victims experiencing chemical poisoning. For planning purposes, most experts calculate a ratio of ten-to-one.
Infrastructure Impact –
The effect of disasters on national, state, and local transportation, communication, medical, and utility infrastructure will have a considerable effect on response strategies. As on 9/11, when the entire civilian air transportation system and much of the national telecommunications system were shut down or disabled, a terrorist incident may have repercussions that affect critical infrastructures necessary for coherent emergency response. These critical networks must be layered and properly coordinated across both civilian and military sectors to ensure the continuity of critical infrastructure support for responding jurisdictions.
Economic Impact –
Catastrophic disasters, depending upon the type, scope, and magnitude of the disaster incident, could threaten the economic sustainability of the communities affected and may cause severe disruption and long-term economic damage. Extreme disaster incidents can generate cascading economic situations extending outside the immediate community. Even in moderate disasters, of all businesses that close following a disaster, more than 43% never reopen, and an additional 29% close permanently within 2 years2. The American Planning Association notes, “Economic recovery is quite likely the most serious issue facing most communities in the post-disaster period, and almost certainly the central issue in every major disaster.”3
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2 Institute for Business and Home Safety, at www.ibhs.org/business_protection.3 Planning for Post-Disaster Recovery and Reconstruction (1998), American Planning Association–Federal Emergency Management Agency, Planning Advisory Service Report No. 483/484, p. 53.
Environmental Impact –
Catastrophic natural and manmade disasters and terrorist attacks can result in extreme environmental impacts that challenge government and community recovery time. Long after the emergency phase subsides, contamination from disasters may remain, consisting of chemical, biological, or radiological materials. While decontamination technologies may be well established for some types of contamination, others are only moderately effective – some contaminants, especially radionuclides, are very difficult and costly to remediate. While some decontamination techniques may be effective in small sites, these techniques may not be suited for decontaminating expansive areas of varying physical characteristics. Evacuation and relocation during cleanup and restoration activities can result in significant business loss and failure, leading to local and regional economic downturn. In addition, agricultural and industrial products from an area contaminated, or thought to be contaminated, can generate impacts that extend within a region and beyond.
International Dimensions –
It is important to underline the significant international dimensions that arise in connection with some of the more damaging and devastating scenarios in which significant loss of life and property, together with the possibility of foreign-directed terrorism, are involved. First, there is the hemispheric dimension of effects on U.S. relations with Canada and Mexico in terms of cross-border trade, transit, law enforcement coordination, and other key issues. Second, there is the immediate treaty connection the United States has with other North Atlantic Treaty Organization (NATO) allies if the United States comes under attack. Third, there is the significant lobbying the United States will undertake at the United Nations (UN) to articulate American needs and interests. In addition to humanitarian and law enforcement assistance from NATO allies, other nations may contribute special equipment in order to meet other necessities. Instances where a disaster or terrorist attack has disrupted major urban centers and international transit/trade routes through U.S. cities will typically require significant coordination with the State Department to ensure all economic, trade, commercial, consular, military cooperative, and humanitarian assistance is rendered as needed.
The State Department plays several key roles in post-disaster situations. It assists foreign citizens affected by the incident. It identifies the specific needs of affected U.S. areas where foreign offers of assistance can be mediated and arranged. Moreover, in cases where explicit terrorist activities may have occurred, the State Department is a leader in facilitating the investigations abroad needed to determine the origins of the attack, in pursuing diplomatic and follow-up policies related to finding the guilty parties abroad, and in rendering coordinated international assistance to U.S. recovery efforts.
Common Response Threads:
Media Access and Support –
The support and cooperation of media in informing and protecting citizens is a critical aspect of emergency response. In many cases, media sources represent the best or only source of information available during the early stages of an incident. Cultivating good working relationships with the media provides opportunities to advise the public of important safety and health guidance and information and corrected misinformation, as well as to obtain critical information from news sources at the scene. Likewise, consistent public service guidance and information from emergency management officials to media sources are vital to reducing the probability of injury or illness and for alleviating citizen anxiety during the emergency.
The Importance of Planning for Continuity of Operations –
The scenarios reinforce the need for governments and the private sector to make preparations to continue their essential operations in an environment in which primary staff and facilities are unavailable. This includes the need to backup key records and systems.
The Need for Capability-Based Planning –
The scenarios emphasize the need for domestic incident preparedness to proceed through a capabilities-based approach. Although it is impossible to determine which major incident will occur next, examination of the scenarios leads to certain common functions that must be accomplished: the need for response organizations to move quickly and in a coordinated manner, the requirement to quickly treat mass casualties, and the need to temporarily house large numbers of people. Other considerations, such as treating infected animals or reconfiguring computer systems, are more incident-dependent.
Mission Areas:
The following Mission Areas were used to assist in scoping the response requirements generated by the scenarios.4 The full-text document contains detailed information for each Mission Area, and this executive summaries document highlights actions to be taken under each Mission Area.
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4 Department of Homeland Security, Office for Domestic Preparedness: Homeland Security Exercise and Evaluation Program, October 2003.
Prevention/Deterrence/Protection – The ability to prevent, deter, or protect against terrorist actions Emergency Assessment/Diagnosis – The ability to detect an incident, determine its impact, classify the incident, conduct environmental monitoring, and make government-to-government notifications
Emergency Management/Response – The ability to direct, control, and coordinate a response; provide emergency public information to the population at risk and the population at large; and manage resources – this outcome includes direction and control through the Incident Command System (ICS), Emergency Operations Center (EOC), and Joint Information Center (JIC)
Incident/Hazard Mitigation – The ability to control, collect, and contain an incident at its source and to mitigate the magnitude of its impact; this outcome also includes all response tasks conducted at the incident scene except those specifically associated with victim care
Public Protection – The ability to provide initial warnings to the population at large and the population at risk, notifying people to shelter-inplace or evacuate; provide evacuee support (e.g., transportation for evacuees, reception center, sand shelters); protect schools and special populations; and manage traffic flow and access to the affected area
Victim Care – The ability to treat victims at the scene, transport patients, treat patients at a medical treatment facility, track patients, handle and track human remains, and provide tracking and security of patients’ possessions and evidence
Investigation/Apprehension – The ability to investigate the cause and source of the attack; prevent secondary attacks; and identify, apprehend, and prosecute those responsible
Recovery/Remediation – The ability to restore essential services, restore businesses and commerce, cleanup the environment and render the affected area safe, compensate victims, provide long-term mental health and other services to victims and the public, and restore a sense of well-being in the community
Scenario 1: Nuclear Detonation –
10-Kiloton Improvised Nuclear Device
Executive Summary
| Casualties | Can vary widely |
| Infrastructure Damage | Total within radius of 0.5 to 1.0 mile |
| Evacuations/Displaced Persons | 450,000 or more |
| Contamination | Approximately 3,000 square miles |
| Economic Impact | Hundreds of billions of dollars |
| Potential for Multiple Events | No |
| Recovery Timeline | Years |
Scenario Overview:
General Description –
In this scenario, terrorist members of the Universal Adversary (UA) group assemble a gun-type nuclear device using highly enriched uranium (HEU) – used here to mean weapons-grade uranium – stolen from a nuclear facility located in the former Soviet Union. The nuclear device components are smuggled into the United States. The 10-kiloton nuclear device is assembled near a major metropolitan center. Using a delivery van, terrorists transport the device to the central business district of a large city and detonate it. Most buildings within 1,000 meters (~ 3,200 feet) of the detonation are severely damaged. Injuries from flying debris (missiles) may occur out to 6 kilometers (~ 3.7 miles). An Electromagnetic Pulse (EMP) damages many electronic devices within about 5 kilometers (~ 3 miles). A mushroom cloud rises above the city and begins to drift east-northeast.
Geographical Considerations/Description –
This scenario postulates a 10-kiloton nuclear detonation in a large metropolitan area. The effects of the damage from the blast, thermal radiation, prompt radiation, and the subsequent radioactive fallout have been calculated, based on a detonation in Washington, D.C. (details are not provided in this executive summary but are presented in the full-text version in Appendix 1-A). However, the calculation is general enough that most major cities in the United States can be substituted in a relatively straightforward manner. If the incident happened near the U.S. border, there would be a need for cooperation between the two border governments. Additionally, the IND attack may warrant the closure of U.S. borders for some period of time. If the detonation occurs in a coastal city, the fallout plume may be carried out over the water, causing a subsequent reduction in casualties. On the other hand, the surrounding water will likely restrict the zones that are suitable for evacuation. Bridges and tunnels that generally accompany coastal cities will restrict the evacuation, causing delay and an increase in the radioactive dose that evacuees receive. This delay may be substantial and the resulting dose increase may drive a decision to shelter-in-place or evacuate-in-stages.
Timeline/Event Dynamics –
The response timeline will begin the instant the detonation occurs. Initially, only survivors in the immediate area will conduct rescue and lifesaving activities. Later (minutes to hours), rescue teams will begin to arrive and provide assistance. With the current state of education, training, and equipment, it is likely that many of these responders will subject themselves to very large (perhaps incapacitating or fatal) doses of radiation. As various command posts are setup (which may take hours to days), the response will become more coordinated.
For a nuclear detonation, the actual occurrence of injuries does not stop when the immediate blast effects have subsided. The most critical components of the post-detonation response may not be the lifesaving efforts that assist the victims directly injured by the detonation. Instead, it is likely that the most effective lifesaving activities will be those that address the evacuation or sheltering-in-place decisions for the potential victims in the immediate fallout path, the effective communication of instructions to the affected population, and the efficient decontamination of the evacuated population.
Secondary Hazards/Events –
The detonation will cause many secondary hazards. The intense heat of the nuclear explosion and other subsequent causes will produce numerous fires located throughout the immediate blast zone. Damaged buildings, downed power and phone lines, leaking gas lines, broken water mains, and weakened bridges and tunnels are just some of the hazardous conditions that will need to be assessed. Depending on the type of industries present (such as chemical or petroleum production, industrial storage facilities, and manufacturing operations), there could be significant releases of hazardous materials.
Another secondary effect of a nuclear explosion is the EMP that will be produced by the ionization and subsequent acceleration of electrons from the air and other materials by the intense radiation of the detonation. This EMP is a sharp, high-voltage spike that radiates out from the detonation site. It has the potential to disrupt the communication network, other electronic equipment, and associated systems within approximately a 5-kilometer (~ 3-mile) range from the 10-kiloton ground blast.
There likely will be significant damage to the general public support infrastructure with potentially cascading effects. These systems include transportation lines and nodes (e.g., air, water, rail, highway); power generation and distribution systems; communications systems; food distribution; and fuel storage and distribution. There will be concerns about the safety and reliability of many structures (e.g., dams, levees, nuclear power plants, hazardous material storage facilities). Structures may be damaged that are used to provide essential services (e.g., hospitals, schools).
Key Implications:
A full description of the fatalities and injuries for a nuclear detonation is difficult and complicated. There will be casualties directly associated with the blast, which will cause “translation/tumbling” (the human body being thrown) and subsequent impacts of people and other objects. A nuclear detonation will also produce a great deal of thermal (heat) energy that will cause burns to exposed skin (and eyes). There are two general “categories” of nuclear radiation produced in a detonation. First is the so-called “prompt” nuclear radiation, arbitrarily defined as being emitted within the first minute – it is actually produced as the device detonates or shortly thereafter. For a 10-kiloton blast, this radiation may expose unprotected people within a distance of a few kilometers (a couple of miles) to extremely large gamma ray and/or neutron doses. In addition, a detonation of a nuclear device near the surface of the ground will result in a great deal of fallout (in the form of dirt particles) that is radioactively contaminated. This fallout will settle out of the radioactive cloud over a period of minutes to weeks. By far, the most dangerously radioactive fallout will be deposited near the detonation site and will happen within the first couple of hours after detonation. Radioactive fallout will exponentially decay with time, but may expose many people to large doses and will certainly contaminate large areas of land for years. Many fatalities and injuries will result from a combination of these various effects.
The largest radiation concerns following an IND incident will be the “prompt” radiation (gamma ray and neutron) and the gamma dose received from the “ground shine” (radioactive particles deposited on the ground) as people are evacuated from the fallout areas. These effects are likely to have significantly larger impacts on the population than internal doses. Internal doses tend to expose the body to relatively small radiation doses over a long period of time, which produces different effects than large radiation doses received during a short period of time.
As the distance from ground zero increases past 20 kilometers (~ 12 miles), the injuries due to acute radiation exposure (from prompt radiation and the subsequent fallout) will decrease, and lower level contamination, evacuation, and sheltering issues will become the major concern. In general, at distances greater than 250 kilometers (~ 150 miles) from ground zero of a 10 kiloton nuclear detonation, acute health concerns will not be a significant issue. However, contamination of people and the environment will still be a concern.
Years later, there will still be health consequences in the form of increased probabilities of cancers in the exposed population. The number of these cancers will likely run into the thousands and will extract a large human, social, and financial cost.
It is likely that the blast and subsequent fires will destroy all buildings in the immediate area of the detonation. Historically, decontamination of sites involves the removal of all affected material, so most buildings in the immediate downwind fallout path will likely have to be destroyed in the decontamination effort. As the distance from the detonation site increases, the contamination level will decrease. At some distance, the buildings will not have to be destroyed and removed but will still require decontamination of all affected surfaces. This decontamination process will take years and will be extremely expensive. The decontamination will produce a far greater challenge and cost much more than the actual rebuilding of the destroyed structures. Approximately 8,000 square kilometers (~ 3,000 square miles) of land will have to undergo varying degrees of decontamination. This effort will last for many years and will cost many billions of dollars to complete.
Service disruption will be extensive in the area near ground zero and in the fallout path for several miles downwind. Services in these areas will not be restored for years because the land affected will not be returned to use until the decontamination is complete and the structures rebuilt. Service disruption will be much less dramatic in areas that are less severely contaminated or not contaminated at all.
The electrical power grid is likely to be damaged by transients produced by the destruction of substations, as well as other power production and distribution installations, and perhaps by the EMP of the detonation. It is likely that the grid damage may cause power outages over wide areas, perhaps over several states, but these outages should be repaired within several days to a couple of weeks. The communication systems in the area will suffer similar damage and will likely be repaired within similar timeframes.
City water mains will likely survive without major damage. The city water supply is unlikely to become substantially contaminated with radiation via water main breaks, but it is possible that some small amount of radioactive and non-radioactive contamination may enter the lines.
To varying degrees, all government services will be impacted over some geographical area. The national economy will be significantly impacted. Decontamination, disposal, and replacement of lost infrastructure will cost many billions of dollars. Replacement of lost private property and goods could add billions more to the cost. Additionally, an overall national economic downturn, if not recession, is probable in the wake of the attack.
Mission Areas Activated:
Prevention/Deterrence/Protection – Law enforcement attempts will be made to prevent development and detonation of the device. Site boundaries must be protected and surveyed after the detonation. Officers must respond to any additional threats or looting/theft issues.
Emergency Assessment/Diagnosis – The detonation will be easily recognized as nuclear. Actions required include dispatching response units; making incident scene reports; detecting and identifying the source; establishing a perimeter; collecting information; making hazard assessments and predictions; coordinating hospital and urgent care facilities; coordinating county and state response requests; and coordinating monitoring, surveying, and sampling operations.
Emergency Management/Response – Evacuation/shelter-in-place decisions must be made immediately. Required actions include alerting the public, providing traffic and access control, protecting at-risk and special populations, supporting requests for assistance, directing and controlling critical infrastructure assets, and directing pubic information activities. Location and removal of injured and disabled people will be a significant undertaking that will be greatly complicated by the need to keep the radiation dose of the individual workers as low as reasonably achievable (ALARA). Initial emergency workers will likely receive high doses of radiation and must be trained on how to avoid as much as possible.
Incident/Hazard Mitigation – Self-evacuation should occur in the short-term, and the greatest factor impacting the reduction of the effects of the detonation on the general population will remain the speed and appropriateness of the decisions that are made and the effectiveness of the dissemination of this information (e.g., evacuation/shelter-in-place instructions). Evacuees must be promptly decontaminated.
Public Protection – Actions should include making and communicating protective action decisions, monitoring and decontaminating evacuees, implementing decisions to administer prophylaxis to the affected populations, protecting special populations, protecting schools and day care facilities, and providing shelter/reception facilities.
Victim Care – Tens of thousands will require decontamination and both short-term and long-term treatment. Due to a high number of casualties, the level of care may be significantly lower than normally expected. When overwhelmed with victims who need care, decisions must be made based on the fact that the sooner the onset of the symptoms, the higher the dose received and the less likely the victim is to survive (even with medical intervention).
Investigation/Apprehension – Attribution activities at the detonation site will rely largely on scientific forensic techniques and will be provided by specialized national teams. Actions of incident-site personnel will include site control and criminal investigation. Federal authorities or the military will probably conduct “apprehension” activities.
Recovery/Remediation – Expected radiation levels will limit the total time workers can spend in the affected area, quickly leading to a shortage of willing, qualified, and trained workers. The volume of contaminated material that will be removed will overwhelm the national hazardous waste disposal facilities and will severely challenge the nation’s ability to transport the material. This effort will be the most expensive and time-consuming part of recovery and will likely cost many billions of dollars and take many years.
Note: For more information, there are two sections available only in the full-text version of this document that provide more detailed information regarding results. There is an Estimated “Realistic” Results section that reflects a set of possible results from the 10-kiloton detonation described in this scenario. The second section, Appendix 1-A, contains a consequence report for a 10-kiloton nuclear detonation in Washington, DC, that describes a set of possible consequences calculated for a 10-kiloton nuclear blast including its prompt effects (occurring within the first minute) and fallout. The results provided in Appendix 1-A are very conservative, and the results provided in the section, Estimated “Realistic” Results are less conservative and are intended to be more realistic.
Scenario 2: Biological Attack – Aerosol Anthrax
Executive Summary
| Casualties | 13,000 fatalities and injuries |
| Infrastructure Damage | Minimal, other than contamination |
| Evacuations/Displaced Persons | Possibly |
| Contamination | Extensive |
| Economic Impact | Billions of dollars |
| Potential for Multiple Events | Yes |
| Recovery Timeline | Months |
Scenario Overview:
General Description –
Anthrax spores delivered by aerosol delivery results in inhalation anthrax, which develops when the bacterial organism, Bacillus anthracis, is inhaled into the lungs. A progressive infection follows. This scenario describes a single aerosol anthrax attack in one city delivered by a truck using a concealed improvised spraying device in a densely populated urban city with a significant commuter workforce. It does not, however, exclude the possibility of multiple attacks in disparate cities or time-phased attacks (i.e., “reload”). For federal planning purposes, it will be assumed that the Universal Adversary (UA) will attack five separate metropolitan areas in a sequential manner. Three cities will be attacked initially, followed by two additional cities 2 weeks later.
Timeline/Event Dynamics –
It is possible that a Bio-Watch signal would be received and processed, but this is not likely to occur until the day after the release. The first cases of anthrax would begin to present to Emergency Rooms (ERs) approximately 36 hours post-release, with rapid progression of symptoms and fatalities in untreated (or inappropriately treated) patients.
The situation in the hospitals will be complicated by the following facts: The release has occurred at the beginning of an unusually early influenza season and the prodromal symptoms of inhalation anthrax are relatively non-specific. Physician uncertainty will result in low thresholds for admission and administration of available countermeasures (e.g., antibiotics), producing severe strains on commercially available supplies of such medications as ciprofloxacin and doxycycline, and exacerbating the surge capacity problem.
Secondary Hazards/Events –
Social order questions will arise. The public will want to know very quickly if it is safe to remain in the affected city and surrounding regions. Many persons will flee regardless of the public health guidance that is provided. Pressure may be placed directly on pharmacies to dispense medical countermeasures directly, and it will be necessary to provide public health guidance in more than a dozen languages.
Key Implications:
This attack results in 328,484 exposures; 13,208 untreated fatalities; and 13,342 total casualties. Although property damage will be minimal, city services will be hampered by safety concerns.
There is the potential for a huge sell-off in the economic markets; moreover, the stock exchange and large businesses may be directly affected by the attack. There may also be a decline in consumer spending and a loss of revenue for the metropolitan area. An overall national economic downturn is possible in the wake of the attack due to loss of consumer confidence. The costs of the closure of a large section of the city and the decrease in revenue from tourism for an indeterminate period would be enormous, as would the costs of remediation and decontamination.
Mission Areas Activated:
Prevention/Deterrence/Protection – This area requires knowledge of those with the ability to grow and aerosolize anthrax, reconnaissance of equipment and laboratories, and public health protection measures.
Emergency Assessment/Diagnosis – It will be necessary to monitor attack impact, determine resource needs, classify the type of event, and identify other events (if any). Environmental sampling for exposure risk assessment, identification of anthrax strain, and determination of any drug resistance will also be required.
Emergency Management/Response – Management and response will require public alerts, mobilization of the Strategic National Stockpile, activation of treatment sites, traffic/access control, special population protection, protective measures (e.g., shelter-in-place), requests for resources and assistance, and public information activities.
Incident/Hazard Mitigation – Mitigation will require PEP and PPE provision, environmental testing/decontamination, care of ill persons, victim treatment, site remediation and monitoring, notification of airlines/transport providers, public information provision, and coordination with public health agencies.
Public Protection – In order to protect the public, it will be necessary to provide symptom/exposure information, warnings, and shelter-in-place/evacuation notification, as well as to manage traffic/access flow and mobilize the Strategic National Stockpile.
Victim Care – Care to the ill must be provided and should include disbursing PEP/vaccinations and establishing treatment/distribution centers.
Investigation/Apprehension – Law enforcement will investigate the attack in collaboration with public health officials working to identify populations at risk of disease. This also requires epidemiological trace-back of victims, parallel criminal investigations, and laboratory analyses.
Recovery/Remediation – The Environmental Protection Agency (EPA) and the CDC will coordinate this area. Extensive decontamination and cleanup will be required (anthrax is long-lived in the environment) costing billions of dollars. Remediation will also require environmental testing, highly contaminated area closures, and public information provision.
Scenario 3: Biological Disease Outbreak – Pandemic Influenza
Executive Summary
| Casualties | At a 15% attack rate: 87,000 fatalities; 300,000 hospitalizations |
| Infrastructure Damage | None |
| Evacuations/Displaced Persons | Isolation of exposed persons |
| Contamination | None |
| Economic Impact | $70 to $160 billion |
| Potential for Multiple Events | Yes, would be worldwide nearly simultaneously |
| Recovery Timeline | Several months |
Scenario Overview:1
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1 Adapted from Patriarcia et al., Pandemic influenza: A planning guide for state and local officials (draft 2.1). Available from http://www.cdc.gov/od/nvpo/pubs/pandemicflu.htm.
General Description –
Influenza pandemics have occurred every 10 to 60 years, with three occurring in the twentieth century (1918, 1957-1958, and 1967-1968). Influenza pandemics occur when there is a notable genetic change (termed genetic shift) in the circulating strain of influenza. Because of this genetic shift, a large portion of the human population is entirely vulnerable to infection from the new pandemic strain.
This scenario hypothetically relates what could happen during the next influenza pandemic without an effective preplanned response. At least twenty-five cases occur first in a small village in south China. Over the next 2 months, outbreaks begin to appear in Hong Kong, Singapore, South Korea, and Japan. Although cases are reported in all age groups, young adults appear to be the most severely affected, and case-fatality rates approach 5%. Several weeks later, the virus appears in four major U.S. cities. By nature, pandemic influenza moves extremely rapidly, and the outbreaks continue.
Timeline/Event Dynamics –
When planning and preparing for the next influenza pandemic, there are two equally important timelines. Due to the rapid spread of the influenza pandemic and the time required to develop, test, produce, and distribute an effective vaccine, the disease will likely arrive in the United States before a “significant” number of people can be vaccinated. The implication of this is that, as part of any pandemic influenza preparation and response plan, there must be a mechanism for allocating the vaccine among the population.
Secondary Hazards/Events –
The greatest secondary hazard will be the problems caused by shortages of medical supplies (e.g., vaccines and antiviral drugs), equipment (e.g., mechanical ventilators), hospital beds, and health care workers. Having a detailed system for allocating resources potentially can reduce such difficulties. This system ideally should be in place well before an influenza pandemic actually occurs. Also of particular concern is the real likelihood that health care systems, particularly hospitals, will be overwhelmed. Another important secondary hazard is the disruption that might occur in society. Institutions, such as schools and workplaces, may close because a large proportion of students or employees are ill. A large array of essential services may be limited because workers are off work due to pandemic influenza. Travel between cities and countries may be sharply reduced.
Key Implications:
Estimates of impact are provided in Table 3-1.
| Health Outcomes |
15% Gross Attack Rate* |
15% Gross Attack Rate |
| Fatalities |
87,000 |
207,000 |
| Hospitalizations |
314,400 |
733,800 |
| Outpatient visits |
18.1 million |
42.2 million |
| Self-care ill |
21.3 million |
49.7 million |
| *Percent Gross Attack Rate refers to the percentage of the
entire U.S. population that will have a clinical case of influenza. |
||
| Note: Assumptions for these estimates are available
in the full-text version of this scenario, which also includes an Appendix 3-C that provides graphs and additional estimates. |
||
Table 3-1. Mean estimates (5th , 95th
percentiles) of the impact of the next
influenza pandemic in the United States without any large-scale and/or
effective interventions
__________________________________
Property damage is minimal. Service disruption, however, could be severe due to worker illness. Health care systems will be severely stressed, if not overwhelmed, and first responders are also likely to be severely strained.
Based on the estimates in Table 3-1, the economic impact, in 1995 U.S. dollars, will range from $71 billion (15% gross attack rate) to $166 billion (35% gross attack rate). These estimates include a value for time lost from work but do not include any estimate due to economic disruption or long-term health care costs.
Mission Areas Activated:
Prevention/Deterrence/Protection – Prevention is currently impossible. Protection requires pre-pandemic preparedness, providing more vaccines and conducting more vaccine research and development, antiviral drug stockpiling, and increased surveillance capacity to track illness patterns.
Emergency Assessment/Diagnosis – U.S. influenza surveillance systems will be activated. However, more information is needed regarding attack rate measurements.
Emergency Management/Response – Preparedness plans should contain clear guidelines on setting priorities for the use of scarce resources such as vaccines, drugs, and hospital beds. Federal and state governments have such plans in progress but not all are complete.
Incident/Hazard Mitigation – Success depends on the availability of scarce resources and how well these resources are distributed. Timely, effective public information communication is also important.
Public Protection – Due to late-onset symptoms and the rapid rate at which the disease spreads, evacuation and quarantine are not recommended. Protection will rely on vaccines and antiviral drugs to prevent spread of the disease.
Victim Care – Will rely on the use of antiviral drugs for treatment. Hospitalization and mechanical ventilators will be necessary for many and likely be in short supply. However, at-home care and over-the-counter medications may be helpful for some. A large number of fatalities will likely occur, requiring mortuary and burial services.
Investigation/Apprehension – Investigation is dependent on disease surveillance, although the current system has distinct limitations.
Recovery/Remediation – Not required.
Scenario 4: Biological Attack – Plague
Executive Summary
| Casualties | 2,500 fatalities; 7,000 injuries |
| Infrastructure Damage | None |
| Evacuations/Displaced Persons | Possibly |
| Contamination | Lasts for hours |
| Economic Impact | Millions of dollars |
| Potential for Multiple Events | Yes |
| Recovery Timeline | Weeks |
Scenario Overview:
General Description –
Plague is a bacterium that causes high mortality in untreated cases and has epidemic potential. It is best known as the cause of Justinian’s Plague (in the middle sixth century) and the Black Death (in the middle fourteenth century), two pandemics that killed millions. In this scenario, members of the Universal Adversary (UA) release pneumonic plague into three main areas of a major metropolitan city – in the bathrooms of the city’s major airport, at the city’s main sports arena, and at the city’s major train station.
Timeline/Event Dynamics –
Plague cases rapidly occur in the United States and Canada. As a result of foreign and domestic travel, rapid dissemination to distant locations occurs. By Day 3, the plague spreads across both the Pacific and Atlantic oceans and by Day 4, the plague is confirmed in eleven countries other than the United States and Canada.
Secondary Hazards/Events –
As the financial world in Major City and elsewhere begins to realize the likelihood of an epidemic, a huge sell-off occurs in the markets. There is a high absentee rate at banks, other financial institutions, and major corporations. Adding to these complications is the fact that bank and other financial customers may be staying home. As a result, the phone systems at financial institutions may become completely tied up, with far fewer transactions than normal occurring. The fear of plague has raised memories of the anthrax incidents of 2001, which may cause many citizens to be afraid to open their mail.
Key Implications:
Morbidity and mortality totals by the end of the fourth day are indicated in Table 4-1. Although the specific assumptions that underlie these totals are not generally available, nor can they be reliably recreated, the parameters affecting these figures include length of incubation period following primary exposure, rate of secondary transmission, incubation period following secondary exposure, and timing and effectiveness of the intervention.
Illnesses and Fatalities by Country |
||
Illnesses |
Fatalities |
|
| United States | 7,348 |
2,287 |
| Canada | 787 |
246 |
| Other Countries | 33 |
10 |
| Total | 8,168 |
2,543 |
Table 4-1. Total illnesses and fatalities by country by the end
of the fourth day (end of the exercise)
______________________________________
Although the actual physical damage to property will be negligible, there will be an associated negative impact of buildings and areas that were or could have been contaminated. Service disruption will be significant for call centers, pharmacies, and hospitals due to overwhelming casualty needs. It will be necessary to close or restrict certain transportation modes. The threat of reduced food supply will cause food prices to rise.
A huge sell-off in the economic markets is possible, and loss of life will result in a decline in consumer spending and subsequent loss of revenue in the metropolitan area. An overall national economic downturn is possible in the wake of the attack due to loss of consumer confidence.
Many people will be killed, permanently disabled, or sick as a result of the plague. The primary illness will be pneumonia, although the plague can also cause septicemia, circulatory complications, and other manifestations. The long-term effects of antimicrobial prophylaxis in large numbers will require follow-up study. The associated mental health issues relating to mass trauma and terrorism events will also require assessment.
Mission Areas Activated:
Prevention/Deterrence/Protection – This area requires knowledge of persons with the skills to grow and aerosolize plague, reconnaissance of supplies and laboratories, and public health protection measures.
Emergency Assessment/Diagnosis – Although health professionals should rapidly recognize the seriousness of the incident, diagnosis of the plague may be delayed. Detection of the plague should initiate laboratory identification of the strain and a determination of the potentially known antimicrobial drug resistance. Origin of the initial contaminant should be traced back to the source.
Emergency Management/Response – Identification of drug-resistant plague strains would require full utilization of personal protective equipment (PPE) and quarantine measures. Response will require provision of public alerts, mobilization of the National Strategic Stockpile, activation of treatment sites, traffic and access control, protection of special populations, potential quarantine measures including shelter-in-place recommendations, requests for resources and assistance, and public information activities. Effective communication between U.S. and Canadian governments is vital.
Incident/Hazard Mitigation – Victims must receive antibiotic therapy within 24 hours to prevent fatality. Exposed victims must be isolated and minimizing disease spread will require epidemiological assessments, including contact investigation and notification.
Public Protection – Victims must be evacuated and treated (and/or self-quarantined), and antimicrobial prophylaxis will be necessary for exposed persons, responders, and pertinent health care workers. Mobilization of the Strategic National Stockpile for additional critical supplies and antibiotics will be necessary. The public should be informed of signs and symptoms of plague.
Victim Care – Victims will require treatment or prophylaxis with ventilators and antibiotics, as well as information measures for preventing spread of the disease. Advanced hospital care will be required for those with pneumonia. The U.S. Department of State’s Bureau of Consular Affairs will need to be involved in order to assist foreign populations residing in the United States, or U.S. citizens exposed or ill abroad.
Investigation/Apprehension – Point-of-source exposures and plague strain must be determined using victim trace-back, criminal investigation, and laboratory analyses.
Recovery/Remediation – Extensive decontamination and cleanup will not be necessary because plague cannot live long in the environment and is viable to heat and sunlight exposure. However, some efforts should be undertaken to support political/public confidence.
Scenario 5: Chemical Attack – Blister Agent
Executive Summary
| Casualties | 150 fatalities; 70,000 hospitalized |
| Infrastructure Damage | Minimal |
| Evacuations/Displaced Persons | More than 100,000 |
| Contamination | Structures affected |
| Economic Impact | $500 million |
| Potential for Multiple Events | Yes |
| Recovery Timeline | Weeks; many long-term health affects |
Scenario Overview:
General Description –
Agent YELLOW, which is a mixture of the blister agents sulfur Mustard and Lewisite, is a liquid with a garlic-like odor. Individuals who breathe this mixture may experience damage to the respiratory system. Contact with the skin or eye can result in serious burns. Lewisite or Mustard-Lewisite also can cause damage to bone marrow and blood vessels. Exposure to high levels may be fatal.
In this scenario, the Universal Adversary (UA) uses a light aircraft to spray chemical agent YELLOW into a packed college football stadium. The agent directly contaminates the stadium and the immediate surrounding area, and generates a downwind vapor hazard. The attack causes a large number of casualties that require urgent and long-term medical treatment, but few immediate fatalities occur. Of the total stadium attendance, 70% is exposed to the liquid at the time of the attack. The remaining 30% (i.e., those in the covered areas of the stadium), plus 10% of the total population in the vapor hazard area, are exposed to vapor contamination.
Timeline/Event Dynamics –
The total time of the attack, including the last mile of the plane’s approach, is less than 5 minutes. The crowd will panic and immediately evacuate the stadium, which will require up to 30 minutes. First responders should begin arriving at the facility perimeter within 10 to 15 minutes of the attack. In order for the UA to succeed in this attack, certain meteorological conditions – wind speed, temperature, humidity, and precipitation – must be met.
Secondary Hazards/Events –
Numerous injuries will occur as a result of crowd panic, including those that result from falling and crushing. Further injuries are likely to occur due to motor vehicle accidents in the parking lot and surrounding roadways.
Key Implications:
In the case of a full, 100,000-seat stadium, 70,000 people (70%) may be contaminated in the attack. Of these, most will have only clothing and/or skin contamination, resulting in moderate-to-severe skin blisters that will appear in 2 to 12 hours. Expedient decontamination (i.e., clothing removal and heavy water spray) will avoid half of these injuries. Systemic arsenic poisoning will occur in highly contaminated individuals. However, many will inhale sufficient agent vapor to cause severe lung damage, and many more will sustain permanent damage to the eyes. Fatalities and major injuries will occur due to falling and crushing during the evacuation, and to vehicle accidents.
There will be little direct property damage due to the attack. However, the stadium site and other contaminated property will be a total loss due to decontamination measures and/or psychological impacts of future usability.
Loss of use of the stadium and adjacent athletic facilities is expected. Additionally, some public transportation and other facilities may be lost due to contamination carried by fleeing victims. Overwhelming demand will disrupt communications (landline telephone and cellular) in the local area. Finally, some victims may self-transport to health care facilities and contaminate those facilities.
Decontamination, destruction, disposal, and replacement of a major stadium could cost up to $500 million. Enrollment at the college will be negatively affected, and the local community will experience significant losses resulting from the attack. Additionally, an overall national economic downturn is possible in the wake of the attack due to a loss of consumer confidence.
Many will be permanently blinded and many more will carry lifetime scars. Many may suffer significant damage to the lungs. In addition, Mustard is a known carcinogen, and systemic poisoning from the arsenic in Lewisite is also a concern.
Mission Areas Activated:
Prevention/Deterrence/Protection – The ability to prevent the attack is contingent on the prevention of chemical warfare material (CWM) importation, weapon assembly, plane and pilot acquisition, and site reconnaissance.
Emergency Assessment/Diagnosis – Hazardous material (HazMat) teams should instantly recognize the attack. Liquid contamination and a downwind vapor hazard will be components of the hazard. Actions required include dispatch; agent detection; and hazard assessment, prediction, monitoring, and sampling.
Emergency Management/Response – Actions required include alerts, activation and notification, traffic and access control, protection of special populations, resource support and requests for assistance, and pubic information activities.
Incident/Hazard Mitigation – The spread of contamination by fleeing victims will be a major challenge. Actions required include isolating and defining the hazard; establishing, planning, and operating incident command; preserving the scene; conducting mitigation efforts; decontaminating responders; and conducting site remediation and monitoring.
Public Protection – Evacuation and/or sheltering of downwind populations in a 360-degree arc around the stadium will be required until the stadium is decontaminated.
Victim Care – Tens of thousands of people will require decontamination and both short- and long-term medical treatment.
Investigation/Apprehension – Actions required include aircraft tracking, dispatch, site control, criminal investigation, tactical deployment, and suspect apprehension.
Recovery/Remediation – The stadium and adjacent facilities must be decontaminated of liquid agent YELLOW. Decontamination waste disposal is complicated by the presence of arsenic. Environmental testing must be done. Although decontamination could technically restore the stadium, psychological impact will likely require the stadium to be rebuilt.
Scenario 6: Chemical Attack – Toxic Industrial Chemicals
Executive Summary
| Casualties | 350 fatalities; 1,000 hospitalizations |
| Infrastructure Damage | 50% of structures in area of explosion |
| Evacuations/Displaced Persons | Up to 700,000 |
| Contamination | Yes |
| Economic Impact | Billions of dollars |
| Potential for Multiple Events | Yes |
| Recovery Timeline | Months |
Scenario Overview:
General Description –
In this scenario, terrorists from the Universal Adversary (UA) land in several helicopters at fixed facility petroleum refineries. They quickly launch rocket-propelled grenades (RPGs) and plant improvised explosive devices (IEDs) before re-boarding and departing, resulting in major fires. At the same time, multiple cargo containers at a nearby port explode aboard or near several cargo ships with resulting fires. Two of the ships contain flammable liquids or solids. The wind is headed in the north-northeast direction, and there is a large, heavy plume of smoke drifting into heavily populated areas and releasing various metals into the air. One of the burning ships in the port contains resins and coatings including isocyanates, nitriles, and epoxy resins. Some IEDs are set for delayed detonation. Casualties occur onsite due to explosive blast and fragmentation, fire, and vapor/liquid exposure to the toxic industrial chemical (TIC). Downwind casualties occur due to vapor exposure.
Timeline/Event Dynamics –
Total time to plan and prepare for the attack would be on the order of 2 years, including reconnaissance, pilot and weapons training, and accumulation of weapons. Time to execute the attack would be several weeks to coordinate the shipping and coincident arrival of the containers aboard separate ships at the port. Time to execute the airborne phase of the attack would be on the order of 1 to 2 hours from liftoff from the originating airport. Time over target for the helicopters would be about 10 minutes. Time on the ground would be 2 to 3 minutes at each site. Fires resulting from the attack would take many hours, possibly days, to extinguish. In order for the UA to succeed in this attack, certain meteorological conditions – wind speed, temperature, humidity, and precipitation – must be met.
Secondary Hazards/Events –
Once they grasp the situation, authorities will evacuate or order shelter-in-place for a significant area downwind of the refineries and the port. Numerous injuries will occur as a result of population panic once downwind casualties begin to occur. Further injuries are likely to occur due to motor vehicle accidents in the surrounding roadways. (The rule of thumb is one fatality per 10,000 evacuated.) Significant contamination of the waterway may also result, including oil and cargo spills from sunk or burning ships.
Key Implications:
Assuming a densely populated area, 7,000 people may be in the actual downwind area. Of these, 5% (350) will receive lethal exposures, and half of these will die before or during treatment. An additional 15% will require hospitalization, and the remainder will be treated and released at the scene by Emergency Medical Service (EMS) personnel. However, approximately 70,000 “worried well” may seek treatment at local medical facilities.
All three refineries sustain significant damage, with 50% of the equipment and facilities requiring significant repairs or replacement. Two ships in the port sink at their moorings; the port sustains heavy damage near the ships and at a dozen points where IEDs were dropped. Depending on which chemicals are released, there may be significant property damage in the downwind area.
Refinery capacity on the west coast is significantly diminished, resulting in fuel shortages and price increases. The port is temporarily closed due to damage and contamination. Contamination in the waterway may also result. Some public transportation and other facilities may be lost. Overwhelming demand will disrupt communications (landline telephone and cellular) in the local area. Significant disruptions in health care occur due to the overwhelming demand of the injured and the “worried well.”
Decontamination, destruction, disposal, and replacement of major portions of the refineries could cost billions of dollars. Similar costs could be expected at the port. Loss of the port will have a significant impact on U.S. trade with the Pacific Rim. An overall national economic downturn is possible in the wake of the attack due to a loss of consumer confidence.
In addition to their toxic effects, many TICs are known carcinogens. Long-term damage to internal organs and eyes is possible, depending on which TICs are present.
Mission Areas Activated:
Prevention/Deterrence/Protection – Avoiding an attack would require prevention of aircraft and weapons acquisition, IED assembly, and site reconnaissance.
Emergency Assessment/Diagnosis – The presence of multiple chemicals and exposure symptoms will greatly complicate assessment and identification efforts. Actions required include dispatch; TIC detection; and hazard assessment, prediction, monitoring, and sampling.
Emergency Management/Response – Actions required include alerts, activation and notification, traffic and access control, protection of special populations, resource support and requests for assistance, and pubic information activities.
Incident/Hazard Mitigation – Mitigation measures will be complicated by multiple TICs and secondary device concerns. Actions required include isolating and defining the hazard; establishing, planning, and operating incident command; firefighting; performing bomb disposal dispatch and IED render-safe procedures; preserving the scene; conducting mitigation efforts; decontaminating responders; and performing site remediation and monitoring.
Public Protection – Evacuation and/or sheltering of downwind populations will be required.
Victim Care – Injuries to be treated will include trauma, burns, smoke inhalation, severe respiratory distress, seizures, and/or comas. Short- and long-term treatment will be required as well as decontamination.
Investigation/Apprehension – Searching for suspects and evidence in an industrial area while wearing personal protective equipment (PPE) will be a significant challenge. Actions required include dispatch, site control, criminal investigation, pursuit and tactical deployment, and apprehension of suspects.
Recovery/Remediation – The extent of decontamination required will depend on the TIC. Regardless, monitoring and sampling a large industrial port facility and refineries will be a challenge. Site restoration will be a major challenge, particularly for the refineries. Environmental impact issues are likely to significantly delay rebuilding efforts.
Scenario 7: Chemical Attack – Nerve Agent
Executive Summary
| Casualties | 6,000 fatalities (95% of building occupants); 350 injuries |
| Infrastructure Damage | Minimal, other than contamination |
| Evacuations/Displaced Persons | Yes |
| Contamination | Extensive |
| Economic Impact | $300 million |
| Potential for Multiple Events | Extensive |
| Recovery Timeline | 3 to 4 months |
Scenario Overview:
General Description –
Sarin is a human-made chemical warfare agent classified as a nerve agent. Nerve agents are the most toxic and rapidly acting of the known chemical warfare agents. Sarin is a clear, colorless, and tasteless liquid that has no odor in its pure form. However, Sarin can evaporate into a vapor and spread into the environment. Sarin is also known as GB.
In this scenario, the Universal Adversary (UA) builds six spray dissemination devices and releases Sarin vapor into the ventilation systems of three large commercial office buildings in a metropolitan area. The agent kills 95% of the people in the buildings, and kills or sickens many of the first responders. In addition, some of the agent exits through rooftop ventilation stacks, creating a downwind hazard.
For purposes of estimating federal response requirements, each building is assumed to have an occupancy of 2,000 personnel (i.e., twenty-story buildings with 100 occupants per floor), and the outdoor/subway population density of the surrounding areas is 3,900 people per square mile (one-tenth of the total population density in the vicinity of Times Square, New York).
Timeline/Event Dynamics –
The attack will require 6 months to plan, including putting faux janitors in place, shipping the agent, and fabricating the spray devices. The actual attack will take less than 10 minutes. First responders should arrive at the facility within 10 to 15 minutes of the attack. In order for the UA to succeed in this attack, certain meteorological conditions – wind speed, temperature, humidity, and precipitation – must be met.
Secondary Hazards/Events –
Numerous injuries will occur as a result of panic on the street, including falling and crushing injuries. Further injuries are likely to occur due to motor vehicle accidents in the surrounding roadways.
Key Implications:
Assuming 2,000 occupants per building, the initial fatality count will be 5,700 (95%) and 300 injured, including the initial Emergency Medical Service (EMS) and fire personnel at each building. Patients who experience prolonged seizures may sustain permanent damage to the central nervous system – assume 350 patients in this category (300 inside plus 50 outside). Fatalities and major injuries will occur due to falling and crushing during the panic on the street, and due to vehicle accidents.
Little direct damage due to the attack, except the building interiors and contents, will be highly contaminated by agent condensing on surfaces. The three buildings and their contents will be a total loss due to decontamination measures and/or psychological impacts of future usability. However, airing and washing should decontaminate adjacent structures adequately.
Overwhelming demand will disrupt communications (landline telephone and cellular) in the local area. There will be large numbers of “worried well” swamping the medical system. Loss of three fire crews and three EMS crews will impact readiness for other events in the short term.
Decontamination, destruction, disposal, and replacement of three large commercial office buildings could cost up to $300 million. Business in the buildings may never reopen, and an overall national economic downturn is possible in the wake of the attack due to loss of consumer confidence.
Those who survive usually recover within 4 to 6 weeks, with full cholinesterase level restoration within 3 to 4 months. Patients who experience prolonged seizures may sustain permanent damage to the central nervous system.
Mission Areas Activated:
Prevention/Deterrence/Protection – The ability to prevent the attack is contingent on the prevention of CWM importation, weapons assembly, and site reconnaissance.
Emergency Assessment/Diagnosis – Rapid recognition of an attack will be key to avoiding first responder casualties. Actions required include dispatch; agent detection; and hazard assessment, prediction, monitoring, and sampling.
Emergency Management/Response – Actions required include alerts, activation and notification, traffic and access control, protection of special populations, resource support and requests for assistance, and pubic information activities.
Incident/Hazard Mitigation – Actions required include isolating and defining the hazard; establishing, planning, and operating incident command; preserving the scene; conducting mitigation efforts; decontaminating responders, and conducting site remediation and monitoring.
Public Protection – Evacuation and/or sheltering of downwind populations will be required.
Victim Care – Tens of thousands of persons will require monitoring and decontamination as they are allowed to leave their buildings. Hundreds will require hospital treatment.
Investigation/Apprehension – Tracking and apprehension of the suspects will be included. Actions required include suspect tracking and apprehension, dispatch, site control, criminal investigation, and tactical deployment.
Recovery/Remediation – Anything exposed to a high-vapor agent concentration will require decontamination, including bodies. There will be little damage to the building as a direct result of the attack. However, decontamination of some materials may be difficult or impossible. Even if structures and property could be technically decontaminated, the psychological impact on future usability would be significant.
Scenario 8: Chemical Attack – Chlorine Tank Explosion
Executive Summary
| Casualties | 17,500 fatalities; 10,000 severe injuries; 100,000 hospitalizations |
| Infrastructure Damage | In immediate explosions areas, and metal corrosion in areas of heavy exposure |
| Evacuations/Displaced Persons | Up to 70,000 (self evacuate) |
| Contamination | Primarily at explosion site, and if waterways are impacted |
| Economic Impact | Millions of dollars |
| Potential for Multiple Events | Yes |
| Recovery Timeline | Weeks |
Scenario Overview:
General Description –
Chlorine gas is poisonous and can be pressurized and cooled to change it into a liquid form so that it can be shipped and stored. When released, it quickly turns into a gas and stays close to the ground and spreads rapidly. Chlorine gas is yellow-green in color and although not flammable alone, it can react explosively or form explosive compounds with other chemicals such as turpentine or ammonia.
In this scenario, the Universal Adversary (UA) infiltrates an industrial facility and stores a large quantity of chlorine gas (liquefied under pressure). Using a low-order explosive, UA ruptures a storage tank man-way, releasing a large quantity of chlorine gas downwind of the site. Secondary devices are set to impact first responders.
Timeline/Event Dynamics –
Total time to plan and prepare for the attack would be on the order of 2 years, including reconnaissance and weapons training, and accumulation of weapons. The actual infiltration, explosive charges setting, and ex-filtration would take less than 20 minutes. Except in very cold conditions, the release would be complete in less than an hour. The plume would travel downwind and be dispersed below the detection level in 6 hours. In order for the UA to succeed in this attack, certain meteorological conditions – wind speed, temperature, humidity, and precipitation – must be met.
Secondary Hazards/Events –
Authorities will shelter-in-place a significant area downwind of the site. Numerous injuries will result from population panic once downwind casualties begin to occur, and as many as 10% of the people will self-evacuate. Additional injuries are likely, due to motor vehicle accidents in the surrounding roadways. The rule of thumb is one fatality per 10,000 evacuated. Any local waterways or wetlands will absorb the chlorine gas, creating hydrochloric acid and lowering the acidity (potential of hydrogen, or pH) of the water.
Key Implications:
Assuming a high-density area, as many as 700,000 people may be in the actual downwind area, which could extend as far as 25 miles. Of these, 5% (35,000) will receive potentially lethal exposures, and half of these will die before or during treatment. An additional 15% will require hospitalization, and the remainder will be treated and released at the scene by Emergency Medical Service (EMS) personnel. However, approximately 450,000 “worried well” will seek treatment at local medical facilities.
The storage tank will be lost, along with some sensitive control systems damaged by the freezing liquefied gas. The secondary devices will cause damage to other plant facilities and equipment in a 20-meter radius of the blasts as well. There will be hundreds, if not thousands, of auto accidents during the evacuation. In areas of heavy chlorine exposure, there will also be heavy corrosion of metal objects.