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Subway Chemical Detection: A Proposed System Process for a Detect-to-Warn Capability to Save Lives. CAPT Joselito Ignacio, MA, MPH, CIH, CSP, REHS Acting Director, Chemical Defense Program Office of Health Affairs Department of Homeland Security. Subway System Challenge.
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Subway Chemical Detection: A Proposed System Process for a Detect-to-Warn Capability to Save Lives CAPT Joselito Ignacio, MA, MPH, CIH, CSP, REHS Acting Director, Chemical Defense Program Office of Health Affairs Department of Homeland Security
Subway System Challenge Chemical Incidents Pose Significant Challenges to Subway System Responses • 2008: 3.5 million passengers use mass transit rail in U.S. • Represents 33% of total number of passenger trips using all forms of public transportation (Dickens & Neff, 2010) • Lack of Strict Passenger and Baggage Screening Requirements Terrorist Interest • 1995 AumShinrikyo Sarin Attack; • 2001 thru 2005, plots foiled to attack mass transit rail in NY, Singapore, Paris and London (Hinds, 2005);
Can Chemical Detection Reduce The Challenges? Problem: A single component (technology) is perceivedas the sole solution to chemical defense Proposed Solution:Create a system that responds with speed, skill and effectiveness using technology as a tool for effective response ACTIONS
ChemicalResponseRequiresRapid Actions Problem: A single component (technology) is perceivedas the sole solution to chemical defense Proposed Solution:Create a system that responds with speed, skill and effectiveness using technology as a tool for effective response ACTIONS [Validated in Demonstration Projects] 5
Location-Independent System Process In order to design Chemical Detection Systems for placement in U.S. Subway Mass Transit Risk Assessment of Chemical Threats in Subway Performance Specifications For Chemical Detectors Chemical Detection Technologies Concept of Operations Plan (CONOP) Chemical Detector Placement Simulating Chemical Dispersion in Subway Training and Exercise Program for Chemical Event
Risk Assessment Methodology Network Analysis • Multiple Stations (Nodes) and Rail (Links) • Model-Based Risk Assessment • Identify Highest Risk Nodes and Links Threat and Vulnerability Assessments • Intelligence Sources • DHS Chemical Terrorism Risk Assessments • Nearby Chemical Manufacturing Distribution and Storage Consequence Analysis • Scenario Driven • Scenarios Provide Specific Conditions • Specific Parameters (Release Mechanism, Quantities, Duration, Environmental Conditions, Operating Conditions, and Exposure Threshold)
Chemical Detector Performance Specifications • Risk Assessment Based • Define Need for a Stationary and Autonomous Detection System • Specify Targeted Chemical Agents • Specify Operating Conditions • Specify Data Integration Requirements • Specify Common Interfering Agents
Technology Review Criteria • Reference Risk Assessment • Detection Performance Specifications • Costs (Capital and Sustainment Costs, Warranties • Vendor Workshop • Third-party Independent Test and Evaluation Review • Develop and issue a Comprehensive Request for Proposal Response Operating Curve (ROC) characterizes a detector’s ability to detect and quantify agent concentration s (Carrano, J. L. et al. Chemical and biological sensor standards study. March 29, 2011)
Detector Placement Analysis • Addresses System Adequacy • Based on Modeling and Risk Illustrations of Evenly Distributed and a Centrally Distributed Detector Placement (with Manifold Sampling Lines)(Becknell, A. F. (2011). Evaluation of facility monitors. Unpublished manuscript) • Identifies Proper Placement • Identifies Appropriate Quantity
Concept of Operations Drives Response Actions to a Chemical Release Must Include: • Detection Method (Detector, Visual Cues, and/or Post-exposure Involving Delayed Onset • Warning mechanism to Alert Staff, Patrons, EMS/Police/Fire/Public Health, and/or Communities • Mitigation Process for False Alarms • Response Process (e.g., Evacuation, Mass Human Decontamination)
Training and Exercise Training and Exercises Creates Operator and Response Proficiency Training Should Encompass • Detectors and Data integration • CONOP for Detect, Warning, Mitigation, and Response Exercises Should Encompass • Seminar to Familiarize and Revise the CONOP • Tabletop Exercise • Games to Simulate Chemical Release • Drills to Exercise Specific Tasks within CONOP
Lessons Learned Need a Detailed and Deliberate Process for the Design, Integration and Implementation of a Chemical Detect-to-Warn Capability • Risk-based; • Curtail costs; • Not detector-centric; Applicable to Venues other than Subway Systems