A Study of Fibers and Textiles

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A Study of Fibers and Textiles

How Forensic Scientists Use Fibers Fibers are used in forensic science to create a link between crime and suspect Through normal activities We shed fibers We picked up fibers Very small fibers are classified as trace evidence Fiber evaluation can show Type of fiber Color Possibility of violence Location of suspects Point of origin

Sampling and Testing Shedding—common form of fiber transfer Microscopes reveal characteristic shapes and markings Infrared spectroscopy reveals chemical structures to differentiate similar fibers Destructive Testing Methods Burning fibers Dissolving fibers in various liquids

Sampling and Testing Compare fibers found on different suspects with those found at the crime scene

Macromolecules 4 Macromolecules: Lipids (does not form polymers) Nucleic Acids Proteins Monomers: Nucleotides Monomer: amino acids Polymer: DNA/RNA Polymer: polypeptide chain (protein) Function: Hereditary information Function: structural support, storage, transport, cellular communications, movement, and defense against foreign substances, Hair is made of protein Carbohydrates Monomers: Single sugars/monosaccharides Polymer: polysaccharides Animals: glycogen (energy storage) Plants: Starch (energy storage) and Cellulose (structural) Function: Energy storage/cell-cell recognition

Polymerization Macromolecules form long chains (polymers) from single building blocks (monomers) Carbohydrates (cellulose in plants) and proteins (polypeptides from animals) are used to make fibers and textiles

Hydrolysis= addition of water to separate a polymer Fig. 5-2 HO 1 2 3 H HO H Condensation/dehydration reaction=two monomers bond together through the loss of a water molecule Short polymer Unlinked monomer Dehydration removes a water molecule, forming a new bond H2O HO 1 2 3 4 H Longer polymer Hydrolysis= addition of water to separate a polymer (reverse of dehydration reaction) (a) Dehydration reaction in the synthesis of a polymer HO 3 H Enzymes= proteins that speed up the reaction without being consumed in the reaction 1 2 4 Figure 5.2 The synthesis and breakdown of polymers Hydrolysis adds a water molecule, breaking a bond H2O HO 1 2 3 H HO H (b) Hydrolysis of a polymer

Fiber Classification —Natural Fibers: Animal Characteristics: Made of proteins Insulating properties Resists wrinkling Examples: Wool and cashmere from sheep Mohair from goats Angora from rabbits Hair from alpacas, llamas, and camels Silk from caterpillar cocoons (longer fiber does not shed easily) woven wool textile

Fiber Classification —Natural Fibers: Plant Characteristics: Made of cellulose Absorb water Insoluble in water Very resistant to damage from harsh chemicals Dissolvable only by strong acids Becomes brittle over time Plant fibers (examples): Cotton—most common textile plant fiber (picture) Coir from coconuts is durable Hemp, jute, and flax from stems grow in bundles Manila and sisal from leaves deteriorate more quickly

Fiber Classification —Natural Fibers: Mineral Characteristics: Resistant to chemical attack Insulating qualities Heat resistant Non flammable Doesn’t deteriorate in normal usage Examples: Fiberglass—a fibrous form of glass Asbestos—a crystalline structure

Fiber Classification —Synthetic Fibers 50% of fabrics are artificially produced Characteristics: Vinyl polymers Resistant to biological and chemical degradation Examples: Rayon Acetate Nylon Acrylic Polyester

Fiber Classification —Synthetic Cellulose Fibers Regenerated Fibers (derived from cellulose): Produced by processing various natural polymers Rayon Most common in this group Imitates natural fibers, but stronger Celenese® Cellulose chemically combined with acetate Found in many carpets Polyamide nylon Cellulose combined with three acetate units Breathable and lightweight Used in performance clothing

Fiber Classification —Synthetic Polymer Fibers Characteristics: Petroleum base Very different from other fibers Monomers join to form polymers Fibers are spun together into yarns No internal structures Uniform diameters

Fiber Classification —Synthetic Polymer Fibers Polyester “Polar fleece” Wrinkle-resistant Not easily broken down by light or concentrated acid Added to natural fibers for strength Nylon Easily broken down by light and concentrated acid Otherwise similar to polyester spandex nylon

Fiber Classification —Synthetic Polymer Fibers Acrylic Inexpensive Tends to “ball” easily Substitute for artificial wool or fur Olefins High performance Quick drying Resistant to wear

Comparison of Natural and Synthetic Fibers Visual Diagnostics of Some Common Textile Fibers under Magnification

Yarns, fabrics, and textiles Yarns—fibers (of any length, thick or thin, loose or tight) twisted or spun together Blending fibers meets different needs (e.g., resistance to wrinkling) Fibers are woven into fabrics or textiles Threads are arranged side by side (the warp) More threads (the weft) are woven back and forth crosswise through the warp

Weave Patterns

. . . . . . . . . . . . . Summary . . . . Fibers are a form of class evidence. Fibers are a form of trace evidence. Fibers are spun into yarns having specific characteristics. Yarns are woven, with different patterns, into clothing or textiles. Fiber evidence is gathered using different techniques.

. . . . . . . . . . . . . . . . . Summary Fibers are analyzed using burn tests, tests for solubility in different solutions, polarized light microscopy, or infrared spectroscopy. Fibers are classified as natural or synthetic. Natural fiber sources include: Animal hair Plant seeds, fruit, stems, or leaves Minerals.