Arson Investigations - PDF

Summary

This document provides an overview of arson investigations, covering topics such as oxidation, combustion, heat transfer, and fire scene analysis. It also touches on indicators of arson, such as identifying the origin and possible ignition devices.

Full Transcript

Introduction Arson investigations often present complex and difficult circumstances to investigate due to the fact that the perpetrator has thoroughly planned the act is not present during the act, and the destruction is so extensive The criminalists function is rather limited to detecting and identifying relevant chemical materials collected at the scene and reconstruvcting and identifying igniter mechanisms -The ultimate determination of the cause of a fire must be made by an investigator whose training and knowledge have been augmented by the experience of fire investigation HEAT, OXYGEN AND FUEL Oxidation FE + 02- FE203 Chemically, fire is a type of oxidation, which is the combination of oxygen with other substances to produce new substances. Not all oxidation reactions proceed in a manner that one associates with a fire; e.g., rusting. Chemically, fire is a type of oxidation, which is the combination of oxygen with other substances to produce new substances. An oxidation reaction is associated with the concept of energy. Energy is associated the ability of a system to do work. Steam can turn a turbine to generate electrical energy. Energy takes many forms; e.g., heat and light. Chemically, fire is a type of oxidation, which is the combination of oxygen with other substances to produce new substances. All oxidation reactions are examples in which more energy is liberated than what is required to initiate the reaction. These are known as exothermic reactions. Combustion To start fire, the minimum temperature needed to spontaneously ignite fuel, known as ignition temperature, must be reached. The heat involved when a substance burns is known as heat of combustion. Once combustion starts enough energy in the form of heat and light (flame) is liberated, a portion of which is used to sustain the fire. Fire is a chain reaction. To initiate and sustain a fire, the following are required: A fuel (vapor) must be present. Oxygen must be available in sufficient quantity to combine with the fuel. Heat must be applied to initiate the combustion, and sufficient heat must be generated to sustain the reaction. Physical State of the Fuel A fuel achieves a reaction rate with oxygen sufficient to produce a flame only when it is in the gaseous state. Thus, rusting will not be accompanied by a flame. A liquid burns when the temperature is high enough to vaporize the fuel. The flash point is the lowest temperature at which a liquid produces enough vapor to burn. A solid such as wood burns only when exposed to heat hot enough to decompose into gaseous products (pyrolysis). Glowing combustion or smoldering is burning at the fuel-air interface, such as a cigarette, the embers of a wood fire, or a charcoal fire. Heat Transfer The three mechanisms of heat transfer are conduction, radiation, and convection. Conduction is the movement of heat through a solid object. Poor conductors are called insulators. During a fire heat may transported through metals, such as nails, bolts, and fasteners to a location far from the initial heat source creating a new fire location The three mechanisms of heat transfer are conduction, radiation, and convection. Radiation is the transfer of heat energy by electromagnetic radiation. A surface exposed to the heat of a fire may burst into flames when the surface reaches the ignition temperature The three mechanisms of heat transfer are conduction, radiation, and convection. Convection is the transfer of heat energy by the movement of molecules within a liquid or gas. In a structural fire, hot gases move to the upper portion of the structure causing surfaces to pyrolyze and burst into a fire. Flashover occurs when all the combustible fuels simultaneously ignite to engulf the entire structure. The Fire Scene The arson investigator needs to begin examining a fire scene for signs of arson as soon as the fire has been extinguished. Experience shows that most arsons are started with petroleum-based accelerants. The search of the fire scene must focus on finding the fire’s origin, which may be most productive in any search for an accelerant or ignition device. Indicators of Arson Some telltale signs of arson include evidence of separate and unconnected fires, the use of “streamers” to spread the fire from one area to another. An irregularly shaped pattern on the floor resulting from the pouring of accelerant onto the surface. Normally, a fire has a tendency to move in an upward direction, and thus the probable origin will most likely be the lowest point showing the most intense characteristics of burning. Evidence of severe burning found on the floor (as opposed to the ceiling) ofa structure is indicative of a flammable liquid. Discovery of an ignition device: The most common igniter is a match, but arsonists can construct many other types of devices to start a fire, including burning cigarettes, firearms, ammunition, a mechanical match- striker, electrical sparking devices, and a “Molotov cocktail.” Fortunately, combustible liquids are rarely entirely consumed during a fire. Collection of Fire Scene Evidence At the suspect point of origin of a fire, ash and soot, along with porous materials which may contain excess accelerant, should be collected and stored in airtight containers such as new paint cans or wide-mouth glass jars, leaving an airspace to remove samples. Never use plastic containers to store fire scene evidence. Traces of flammable liquid residues may be located with a vapor detector (sniffer) or a trained canine. The collection of all materials suspected of containing volatile liquids must be accompanied by a thorough sampling of similar but uncontaminated control specimens from another area of the fire scene, called a substrate control. Laboratory Recovery of Flammable Residues The easiest way to recover accelerant residues from fire-scene debris is to heat the airtight container in which the sample is sent to the laboratory. When the container is heated, any volatile residue in the debris is driven off and trapped in the container’s enclosed airspace. The vapor or headspace is then removed with a syringe. When the vapor is injected into the gas chromatograph, it is separated into its components, and each peak is recorded on the chromatogram. In the vapor concentration technique, a charcoal strip is placed in the airtight debris container when it is heated. The charcoal strip absorbs much of the vapors during heating. The strip is washed with a solvent which will recover the accelerant vapors. The solvent is then injected into the gas chromatograph for analysis. Gas Chromatography In the laboratory, the gas chromatograph is the most sensitive and reliable instrument for detecting and characterizing flammable residues. The vast majority of arsons are initiated by petroleum distillates such as gasoline and kerosene. The gas chromatograph separates the hydrocarbon components and produces a chromatographic pattern characteristic of a particular petroleum product. By comparing select gas chromatographic peaks recovered from fire-scene debris to known flammable liquids, a forensic analyst may be able to identify the accelerant used to initiate the fire. The chromatographic pattern of the unknown is compared to patterns produced by known petroleum products. Accelerant Identification Typically a forensic analyst compares the pattern generated by the sample to chromatograms from accelerant standards obtained under the same conditions. The pattern of gasoline, as with many other accelerants, can easily be placed in a searchable library. An invaluable reference known as the Ignitable Liquids Reference Hydrocarbon Collection (ILRC) is found on the Internet at http://ilrc.ucf.edu. Complex chromatographic patterns can be simplified by gas chromatography/mass spectrometry Explosions Explosives are substances that undergo a rapid oxidation reaction with the production of large quantities of gases. It is this sudden buildup of gas pressure that constitutes the nature of an explosion. The speed at which explosives decompose permits their classification as high or low explosives. Low Explosives The most widely used explosives in the low-explosive group are black powder and smokeless powder. Black powder is a mixture of potassium or sodium nitrate, charcoal, and sulfur. Smokeless powder consists of nitrated cotton (nitrocellulose) or nitroglycerin and nitrocellulose. Low explosives are confined to a container like a pipe. The speed of decomposition is called deflagration causing the walls of the container to fragment and fly outward in all directions. High Explosives Among the high explosives: Primary explosives are ultra-sensitive to heat, shock, or friction and provide the major ingredients found in blasting caps or primers used to detonate other explosives. Among the high explosives: Secondary explosives are relatively insensitive to heat, shock, or friction and will normally burn rather than detonate if ignited in small quantities in the open air. This group comprises the majority of commercial and military blasting, such as dynamite, TNT, PETN, and RDX. Secondary explosives must be detonated by a primary explosive. The speed of decomposition is known as detonation. Its extremely rapid producing a supersonic shock wave creating a blast effect with an outward rush of gases at speeds as high as 7,000 miles per hour. In recent years, nitroglycerin-based dynamite has all but disappeared from the industrial explosive market and has been replaced by ammonium nitrate- based explosives. Military anf Peroxide Explosives In many countries outside the United States, the accessibility of military high explosives to terrorist organizations makes them very common constituents of homemade bombs. RDX is the most popular and powerful of the military explosives, often encountered in the form of pliable plastic known as C-4. Triacetone triperoxide (TATP) is a homemade explosive that has been used by terrorist organizations. TATP can be made by combining acetone and peroxide in the presence of an acid. Its existence has led to the banning of most liquids on commercial aircraft. Collection and Analysis The entire bomb site must be systematically searched with great care given to recovering any trace of a detonating mechanism or any other item foreign to the explosion site. Objects located at or near the origin of the explosion must be collected for laboratory examination. Often a crater is located at the origin and loose soil and other debris must be preserved from its interior for laboratory analysis. One approach for screening objects for the presence of explosive residues is the ion mobility spectrometer All materials collected for the examination by the laboratory must be placed in sealed air-tight containers and labeled with all pertinent information. Debris and articles collected from different areas are to be packaged in separate air-tight containers. It has been demonstrated that some explosives can diffuse through plastic and contaminate nearby containers. Back at the Lab Typically, in the laboratory, debris collected at explosion scenes will be examined microscopically for unconsumed explosive particles. Recovered debris may also be thoroughly rinsed with organic solvents and analyzed by testing procedures that include color spot tests, thin-layer chromatography, and gas chromatography/mass spectrometry. Confirmatory identification tests may be performed on unexploded materials by infrared spectrophotometry.