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Chapter 6: Fibers

Chapter 6: Fibers.

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Chapter 6: Fibers

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  1. Chapter 6:Fibers “Wherever he steps, whatever he touches, whatever he leaves even unconsciously, will serve as silent witness against him. Not only his fingerprints or his footprints, but his hair, the fibers from his clothes, the glass he breaks, the tool marks he leaves, the paint he scratches, the blood or semen he deposits or collects—all of these and more bear mute witness against him. This is evidence that does not forget.” —Paul L. Kirk (1902 – 1970) Forensic scientist

  2. Fibers Students will learn: • How fibers can be used as circumstantial evidence to link the victim, suspect, and crime scene. • Why fibers are class evidence. • Why statistics are important in determining the value of evidence. The student will learn:

  3. Fibers • Are considered class evidence • Have probative value • Are common trace evidence at a crime scene • Can be characterized based on comparison of both physical and chemical properties

  4. Fibers at the Crime Scene • Can occur • When two people come in contact • When contact occurs with an item from the crime scene • Methods of transfer • Direct transfer — fiber transferred from fabric directly onto victim or suspect • Indirect transfer — fibers already transferred onto clothing of suspect or victim transfer onto the other party

  5. Forensics of Fiber Analysis • Cross transfers of fiber often occur in cases in which there is person-to-person contact • Investigators hope that fiber traceable back to the offender can be found at the crime scene, as well as vice versa. • Success in solving crimes often hinge on the ability to narrow the sources for the type of fiber found, as the prosecution did with their probability theory on the fibers

  6. Fiber Evidence • Fibers are gathered at a crime scene with tweezers, tape, or a vacuum.  • They generally come from clothing, drapery, wigs, carpeting, furniture, and blankets.  • For analysis, they are first determined to be natural, manufactured, or a mix of both.

  7. Collection ofFiber Evidence • Bag clothing items individually in paperbags. Make sure that different items are not placed on the same surface before being bagged. • Make tape lifts of exposed skin areas of bodies and any inanimate objects • Removed fibers should be folded into a small sheet of paper and stored in a paper bag.

  8. Fiber Evidence Fiber evidence in court cases can be used to connect the suspect to the victim or to the crime scene. In the case of Wayne Williams, fibers weighed heavily on the outcome of the case. Williams was convicted in 1982 based on carpet fibers that were found in his home, car and on several murder victims.

  9. Fiber Evidence • The problem with fiber evidence is that fibers are not unique.  • Unlike fingerprints or DNA, they cannot pinpoint an offender in any definitive manner.  • There must be other factors involved, such as evidence that the fibers can corroborate or something unique to the fibers that set them apart.

  10. Fabric • Fabric is made of fibers. Fibers are made of twisted filaments • Types of fibers and fabric • Natural—animal, vegetable or inorganic • Synthetic (Artificial)—synthesized or created from altered natural sources

  11. Synthetic Rayon Nylon Acetate Acrylic Spandex Polyester Natural Silk Cotton Wool Mohair Cashmere Types of Fibers

  12. Plant (vegetable) fibers are characterized by anatomical features. Animal fibers are recognized by their morphology and classified into major groups. Synthetic and regenerated fibers are characterized by polarized light microscopy. Identification of Fibers

  13. Fiber Comparison Can you tell the difference(s) between the cotton on the left and the rayon on the right?

  14. Classification • Natural fibers are classified according to their origin: • Plant fibers • Animal fibers • Mineral fibers

  15. Classification of fibers by their composition • Natural plant fibers may be more ribbon shaped and may contain twists at irregular intervals • Natural fibers from an animal source look like hair and will often have rough external scale patterns and medulla • Synthetic fibers tend to be smooth and uniform and some may have long striations lines on the other layer

  16. Plant Fibers • Cotton—vegetable fiber; strong, tough, flexible, moisture absorbent, not shape retentive • Most common natural fiber • Evidential value almost meaningless • Other plant fibers • Flax (linen) • Ramie • Jute • Hemp

  17. Other plant fibers hemp ramie linen jute • Flax (linen) • Ramie • Jute • Hemp Flax fibers viewed wth polarized light

  18. Animal Fibers • Most common animal fiber • Wool — sheep hair • Fine wool found in clothing • Coarse wool found in carpet common a • Other animal fibers • Mohair and cashmere — goats • Wool — camel hair • Wool — llama hair • Angora — rabbit hair • Silk—insect fiber that is spun by a silk worm (moth caterpillar) to make its cocoon • Vicunas (looks like a llama - South America) $3000 / bolt of their fir wool

  19. Mineral Fibers • Asbestos—a natural fiber that has been used in fire-resistant substances • Rock wool—a manufactured mineral fiber • Fiberglass—a manufactured inorganic fiber

  20. Synthetic fibers • More than half of all fibers used in production of textile materials are man-made • Manufactured fibers can originate from • Natural materials • Examples: rayon and acetate • Synthetic materials • Examples: nylon, polyester and acrylic • The amount of production of a particular man-made fiber and its end use influence the degree of rarity of a given fiber

  21. Polyester Red Polyester Green Polyester

  22. Synthetic Fibers(Made from derivatives of petroleum, coal and natural gas) • Nylon—most durable of man-made fibers; extremely light weight • Polyester—most widely used man-made fiber • Acrylic—provides warmth from a lightweight, soft and resilient fiber • Spandex—extreme elastic properties • Rayon—chemically-altered cellulose; soft, lustrous, versatile

  23. Polymers • Synthetic fibers are made of polymers which are long chains of repeating chemical units. • The word polymer means many (poly), units (mer). • The repeating units of a polymer are called monomers. • By varying the chemical structure of the monomers or by varying the way they are joined together, polymers are created that have different properties. • As a result of these differences, forensically they can be distinguished from one another.

  24. Synthetic (Man-Made) Fibers • The shape of a man-made fiber can determine the value placed on that fiber. • Cross section of a man-made fiber can be manufacturer-specific. • Some cross sections are more common than others, and some shapes may only be produced for a short period of time.

  25. Filament Cross-Sections Synthetic fibers are forced out of a nozzle when they are hot, and then they are woven. The holes of the nozzle are not necessarily round; therefore, the fiber filament may have a unique shape in cross-section.

  26. Synthetic Fibers • Cross sections of nylon carpet fibers seen with a scanning electron microscope (SEM)

  27. Testing for Identification • Microscopic observation • Burning—observation of how a fiber burns, the odor, color of flame, smoke and the appearance of the residue • Thermal decomposition—gently heating to break down the fiber to the basic monomers • Chemical tests—solubility and decomposition

  28. Testing for Identification • Density—mass of object divided by the volume of the object • Refractive Index—measuring the bending of light as it passes from air into a solid or liquid • Fluorescence—used for comparing fibers as well as spotting fibers for collection

  29. Dyes • Components that make up dyes can be separated and matched to an unknown. • There are more than 7000 different dye formulations. • Chromatography is used to separate dyes for comparative analysis. • The way a fabric accepts a particular dye may also be used to identify and compare samples.

  30. Identification and Comparison of Fibers • Fourier Transform Infrared analysis (FTIR)—based on selective absorption of wavelengths of light • Optical microscopy—uses polarizing light and comparison microscopes • Pyrolysis gas chromatography-mass spectrometry (PGC-MS)—burns a sample under controlled conditions, separates and analyzes each combustion product

  31. Fabric Production Fabrics are composed of individual threads or yarns, made of fibers, that are knitted, woven, bonded, crocheted, felted, knotted or laminated. Most are either woven or knitted. The degree of stretch, absorbency, water repellence, softness and durability are all individual qualities of the different fabrics.

  32. Weave Terminology • Yarn—a continuous strand of fibers or filaments, either twisted or not • Warp—lengthwise yarn • Weft—crosswise yarn • Blend—a fabric made up of two or more different types of fiber.

  33. Weave Patterns

  34. Plain Weave • The simplest and most common weave pattern • The warp and weft yarns pass under each other alternately • Design resembles a checkerboard

  35. Twill Weave • The warp yarn is passed over one to three weft yarns before going under one • Makes a diagonal weave pattern • Design resembles stair steps • Denim is one of the most common examples

  36. Satin Weave • The yarn interlacing is not uniform • Creates long floats • Interlacing weave passes over four or more yarns • Satin is the most obvious example

  37. Knitted Fabric Knitted fabrics are made by interlocking loops into a specific arrangement. It may be one continuous thread or a combination. Either way, the yarn is formed into successive rows of loops and then drawn through another series of loops to make the fabric.

  38. More about Fibers For additional information about fibers and other trace evidence, check out Court TV’s Crime Library at: www.crimelibrary.com/criminal_mind/forensics/trace/1.html

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