Fiber Guidelines, Chapter 1 (FSC, April 1999)
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This document is an outline of fiber analysis methods intended for use by forensic fiber examiners. The particular methods employed by each examiner, laboratory, or both will depend upon sample size, sample suitability, laboratory equipment, and examiner training.
SWGMAT Quality Assurance Guidelines
SWGMAT Trace Evidence Handling Guidelines
Known (Sample): A subset of a larger population or sample originating from a verifiable source, collected as representative of that larger grouping; for example, a 2” x 2” section of carpet from a suspect’s living room.
Questioned (Sample): Materials collected as or from items of evidence that have a known location but an unknown origin; for example, loose fibers collected from a victim’s clothing.
Class Characteristics: Traits that define a group of items collectively.
Class: A group of items that share properties or characteristics.
Individual Characteristics: Traits that define and identify an item as unique and exclusive of all other items.
Individual: A unique item that is identified as itself to the exclusion of all other items.
The various analytical methods available for fiber analysis yield different kinds of information. It is highly desirable to select a combination of methods and apply them in an order that provides the most exclusionary information first. By doing this, the examiner optimizes accuracy, precision, and production while most effectively using the laboratory’s resources.
At a minimum, a fiber examiner must employ a stereomicroscope, a comparison microscope, and a compound light microscope equipped with polarized light capability. The examiner must view questioned and known fibers side by side at the same magnifications in visible light, and alternative lighting, such as polarized light or fluorescent lighting, although not necessary, is recommended if the equipment allows. For some analyses, for example, in testing for solubility, it may be necessary to place questioned and known fibers next to each other on the same slide or in adjacent wells of a spot plate. Extreme caution must be exercised with loose fibers in these circumstances so as not to confuse the source of each fiber.
Typically, fiber examinations involve a comparison of samples from known and questioned sources to determine whether they are consistent with having originated from the same source (e.g., carpet from a suspect’s car compared with foreign fibers removed from the victim’s clothing). This comparison involves the recognition and evaluation of class characteristics, which associate materials to a group but never to a single source. Conversely, individual characteristics allow the association between two or more items with each other to the exclusion of all other items. For fiber examiners, this most often occurs when pieces of fabric or cordage are physically matched.
5.3. Source Determination
Textile fibers can be exchanged between individuals, between individuals and objects, and between objects. When fibers are associated with a specific source, such as fabric from the victim, suspect, or scene, a value is placed on that association. The probative weight of this value is dependent upon many factors. The following subsections describe those factors.
5.3.1. Fiber type or types found;
5.3.2. Fiber color or colors;
5.3.3. Number of fibers found;
5.3.4. Fiber location or locations;
5.3.5. Fabric type or types;
5.3.6. Multiple fiber associations;
5.3.7. Nature of contact; and
5.3.8.Fiber transfer and persistence.
Whether a fiber is transferred and detected is also dependent on the nature and duration of the contact between the suspect, the victim, or both and the persistence of the fibers after they have been transferred.
5.3.1. Fiber Type or Types. The rarity or commonness of the fiber types found at a crime scene or on a victim or suspect affects their probative value. Cotton fibers are by far the most commonly used plant fibers in textile production. The type of cotton, the fibers’ length, and the degree of twist contribute to the diversity found in cotton fibers. Processing techniques, such as mercerization, and color applications also influence the value of cotton fiber identifications. The presence of other less common plant fibers at a crime scene or on the clothing of a victim or suspect increases its significance.
The most common animal fiber used in textile production is wool originating from sheep. The fineness or coarseness of woolen fibers often dictates the end use of wool. The finer woolen fibers are used in the production of clothing, whereas the coarser fibers are found in carpet. The diameter and the degree of scale protrusion of the fibers are other important characteristics. Woolen fibers from other animals may also be found, including camel, alpaca, cashmere, and mohair. The identification of less common animal hairs, fibers, or both at a crime scene or on the clothing of a suspect or victim would have increased significance.
Over half of all fibers used in the production of textile materials are manufactured. Some manufactured fibers originate from natural materials such as cotton or wood, whereas others originate from synthetic materials. All nonnaturally occurring fibers are manufactured, but not all manufactured fibers are synthetic (e.g., rayon). Certain types of manufactured fibers are more common than others. Polyester and nylon fibers are the most commonly encountered manufactured fibers, followed by rayons, acetates, and acrylics. There are also many other less commonly manufactured fibers. The amount of production, the end use, the cross-sectional shape, microscopic characteristics, and other traits of the fiber help to influence the degree of rarity of a particular fiber type.
5.3.2. Fiber Color or Colors. One of the greatest variations seen in textiles is color. Thus, color greatly influences the significance of a fiber comparison. Synthetic dyes and pigments belong to 29 different chemical categories with more than a dozen different application methods (7). Even simple dyes might require between eight and ten processes to convert the raw materials into a finished dye. Given that the total annual production of any particular dye might not amount to more than 10 tons and that small process batches are becoming the rule in the dyeing industry, color becomes a powerful discriminant. Color is particularly significant when the gamut of colors is spread out over the range of garments and carpeting produced in any one year and even more so when multiplied by the number of garments and carpets produced in previous years.
Individual fibers can be colored before being spun into yarn, yarns can be dyed after being spun, or the fabric can be dyed before or after its construction. Color can also be applied to the surface of a fabric by printing. The absorbance of the dye along the fiber length suggests the dyes and dyeing method used. Fading and discoloration may also add increased significance to a fiber association.
5.3.3. Number of Fibers. The number of fibers identified on the clothing of a victim associated to the clothing of a suspect is important in determining actual contact. The greater the number of fibers, the more likely that direct contact occurred between these individuals. The converse is not necessarily true, however, and even one fiber association can have probative and scientific value. Additionally, finding no fibers does not de facto mean that no contact occurred. Each case is different, and the examiner must weigh all of the relevant factors before determining the significance of the evidence.
5.3.4. Fiber Location. Where the fibers are found also affects the probative value of a particular fiber association. The location of fibers on different areas of the body or on specific items at the scene can influence the significance of the fiber association.
5.3.5. Fabric Type. Fabric construction affects the number and types of fibers that may be transferred. Tightly woven or knitted fabrics shed fewer fibers than loosely knit or woven fabrics. Fabrics composed of filament yarns shed less than fabric composed of spun yarns. Certain types of fibers also transfer more readily. The condition and wear of the fabric also affects the degree of fiber transfers: Newer fabrics may have an abundance of loosely adhering fibers on the surface of the fabric, whereas worn fabrics may have damaged areas that easily shed fibers. Damage to a fabric caused during physical contact greatly increases the likelihood of fiber transfer.
5.3.6. Multiple Fiber Associations. If many different fiber types are associated among the suspect, victim, and scene, then the likelihood that contact occurred between these items is greatly increased. Each associated fiber transfer is considered to be an independent event, and multiple associations undermine an argument that the fibers were all deposited by coincidence.
5.3.7. Nature of Contact. The type of physical contact between a suspect and a victim helps to determine the number of fibers transferred and the value placed on their discovery. Violent physical contact of an extended duration may result in many fiber transfers.
5.3.8. Fiber Transfer and Persistence. Textile fibers are transferred to the surface of a fabric either by direct (primary) transfer or indirect (secondary) transfer. The likelihood of transfer depends on the types of fabric involved in the contact and the nature and duration of the contact. Studies have shown that transferred fibers are lost at a geometric rate, depending on the types of fabrics involved and on the movement of the clothing after contact (see endnote 1). For example, the clothing of a homicide victim may retain transferred fibers for a longer time because the victim is not moving. Therefore, under these circumstances it is difficult to predict precisely how many fibers might remain on the clothing of a living individual after a given period, but it is important for investigators to retrieve clothing immediately.
Whenever a fiber is found in relation to a crime scene, victim, or suspect, it has potential significance. Matching dyed fibers, whether manufactured or natural, can be very meaningful, whereas the matching of common fibers such as white cotton or blue denim cotton can would be less significant. In some situations, however, the presence of white cotton or blue denim cotton possibly still has some meaning in resolving the truth of an issue. The discovery of cross transfers (suspect[s] to victim[s] and vice versa) dramatically increases the likelihood that two items came into contact and greatly reduces the likelihood of chance occurrence.
When a fiber examiner associates a questioned fiber to a known textile item, there are ultimately two possible explanations: (a) The questioned fiber originated from the known textile, or (b) the questioned fiber did not originate from the known textile.
To say that the questioned fiber originated from the known textile, it either had to be the only fabric of its type ever produced or now existing, or the transfer of fibers was directly observed. As neither of these situations is likely to occur, fiber examiners must conclude that because the questioned fibers exhibit the same results in all tested properties as the fibers from the known sample, the questioned fibers are consistent with originating from the source textile. Other textile sources that incorporate the same fibers can be ruled out only by context and availability. In order to say that a fiber did not originate from a particular textile is to know the history of the textile or have observed the fiber transfer from another textile.
5.4. Volume of Fiber Production
It could be argued that the large volume of fibers produced reduces the significance of a fiber association discovered in a criminal case. It can never be stated with certainty that a fiber originated from a particular textile because other textiles are produced using the same fiber types and color. The inability to positively associate a fiber to a particular textile to the exclusion of all others, however, does not mean that a fiber association is without value. Considering the volume of textiles produced worldwide each year, the number of textiles produced with any one fiber type and color is extremely small. The likelihood of two or more manufacturers exactly duplicating all of the aspects of the textile is extremely remote (see endnote 2). Beyond the comments made previously about color, shade tolerance differs between dyeing companies. Therefore, color may vary demonstrably from batch to batch. Also, the life span of a particular fabric must be considered. Only so much of a given fabric of a particular color and fiber type is produced, and it will eventually end up being destroyed or dumped in a landfill.
The world produced approximately 80 billion pounds of fabric in 1995, about half of which was cotton (5). The other approximately 44 billion pounds of fiber were manufactured or synthetic. Table 1 provides U.S. fiber production levels.
U.S. Annual Production for Manufactured Fibers: 1995
(millions of pounds)
5.4.1. Significance. As an example, given a yarn-dyed nylon fiber from a knit polo shirt of a specific color, the significance could be described in the following way:
188.8.131.52. Total fiber production;
184.108.40.206. Total nylon (of that type) production;
220.127.116.11. Total nylon production in staple form;
18.104.22.168. Total production of Item 3 in a particular denier, cross-section, optical characteristics, and luster;
22.214.171.124. Total amount of Item 4 used in production of garments;
126.96.36.199. Total garments constructed in the same fashion, including knit specifications, collar, and sleeve incorporating Item 5;
188.8.131.52. Total of Item 6 in a specific color;
184.108.40.206. Total of Item 7 from indistinguishable dye lots;
220.127.116.11. Total of Item 8 available for merchandising;
18.104.22.168. Total of Item 9 sold;
22.214.171.124. Total of Item 10 still in existence;
126.96.36.199. Total of Item 11 available to be connected with a particular criminal offense; and
188.8.131.52. Total of Item 12 actually connected with a particular criminal offense (i.e., found and submitted as evidence).
The fiber examiner is still limited to stating that the questioned fibers are consistent with originating from the evidence garment, with the understanding that all other garments listed under Item 11 (subsection 184.108.40.206) may or may not be distinguishable from the evidence garment by fiber analysis alone. This argument in no way intimates a positive match to the evidence garment to the exclusion of all other garments. Production numbers for textiles may be available for use in interpreting the significance of evidence in a crime, but the examiner must be careful to be conservative in all estimates in order to avoid false inclusions (8). Calculating exact probability statistics for this type of evidence is problematic at best, and professional statisticians must be consulted before any calculations are reported or testified.
5.5. Fiber Source
If questioned fibers are associated with known fibers, the questioned fibers either originated from the known textile or from another fabric source, which not only is composed of fibers of the exact type and color but also from a fabric that had to be available to contribute those fibers through direct or indirect contact. The chance is, therefore, remote to encounter fibers from the environment of a victim that are identical to fibers from the suspects’ environment or environments in the absence of contact (9). Put another way, the chance of finding known fibers from a randomly selected suspect source that match the questioned fibers is remote (see endnote 3).
Although examiners may be consulted concerning proper sample size, collection, or packaging, this may not happen, and the examiner must optimize the evidence that is submitted. Garfield (1) and others (2) list the following methods of sampling:
6.1. Probability Sampling (So-Called “Random Sampling”)
Every unit in the population has a known, nonzero probability of being included in the sample (e.g., collecting about 33 percent of the fibers from a pillbox or by taping and mounting them);
6.2. Nonprobability or Judgment Sampling
Every unit in the population either is or is not included in the sample on the basis of certain characteristics it has in common with other units of interest (e.g., mounting only red trilobal carpet-type fibers from the victims’ evidence given the suspect has red carpet as a possible source); and
6.3. Bulk or Lot Sampling
A sampling unit is taken from a larger amount of material that does not consist of discrete and identifiable units. Special considerations are involved with bulk sampling, such as where the sample is taken, how much sample is taken, and if the sample is considered representative of the lot (e.g., cutting a swatch from a garment for fabric and fiber examination).
Samples are adequate for analysis when they are taken in a manner consistent with generally recognized and accepted sampling techniques and practices within the context of the proposed analyses. All of the previously mentioned sampling methods have their place, and one may be more feasible than another, given crime scene or laboratory constraints. The examiner must be able to explain how the samples were taken and why that procedure was used.
Examinations typically should be conducted in the order of increasing magnification, from gross inspection to microscopical analysis. If sample size is limited, nondestructive methods must be exhausted before subjecting the sample to any destructive tests (e.g., pyrolysis).
It is highly desirable that the methods be selected in an order that provides the greatest discrimination between samples. An exclusion precludes further analysis, thereby maximizing the examiner’s time and resources.
There are three basic activities involved in an analysis (1): (a) collection of a representative sample; (b) preparation of the sample for analysis; and (c) analysis using appropriate methods.
Although these activities are ostensibly independent of each other, any one can have a significant effect on another. Because error is possible at each step, the examiner must be able to identify these errors and avoid them. Any method of analysis has certain attributes such as accuracy, precision, specificity, sensitivity, dependability, and practicality that must be considered when choosing the most appropriate method to adequately answer the question at hand. Ultimately, it is the examiner’s responsibility to evaluate all of the available information and decide the level of uncertainty that is acceptable with a given method on a given set of samples.
7.1. Physical Matches
A physical match occurs when two or more pieces of fabric or cordage are reconstructed to prove they were previously one continuous piece of fabric or cordage. This examination is conducted by describing and documenting any cut, torn, or damaged edges on questioned items and their correlation to like areas on known items. Photography is the recommended method of documentation.
Depending upon sample size, suitability, and exhibited characteristics, it may not be possible to effect a positive physical match. For descriptions of physical construction refer to the fabric and cordage guidelines in Chapter 7 of this document.
7.2. Fiber Examinations
Fiber identifications consist of determining the generic class of fiber type, which generally follows the Federal Trade Commission Guidelines (3). This analysis requires a sufficient number of examinations to unequivocally place the fiber in question into one and only one generic class (see Table 2).
Fiber comparisons consist of determining if a questioned fiber or fibers exhibits the same chemical, microscopic, and optical properties as fiber or fibers comprising part or all of a known sample. A comparison requires an examiner to complete at least two of the analytical techniques listed for each of the following categories: generic class, physical characteristics, and color (see Figure 1). The techniques selected should independently confirm the results obtained. It should be noted that some techniques allow greater discrimination than others between apparently similar samples.
Laboratory results should be reported in a uniform and consistent manner. Format, units of measurement, and accepted calculations should all be documented in the laboratory’s manuals. The contributor of the evidence must be able to “interpret the results and understand their significance” (1). The International Organization for Standardization (ISO) recommends that reports be clear, accurate, and unambiguous in the presentation of results (4). Refer to the appropriate sections of the SWGMAT Quality Assurance Guidelines for further information.
(1) Garfield, F. M. Quality Assurance Principles. Association of Official Analytical Chemists, Arlington, Virginia, 1991.
(2) Levy, P. S. and Lemeshow, S. Sampling of Populations. John Wiley and Sons, New York, 1991.
(3) Federal Trade Commission Rules and Regulations Under the Textile Products Identification Act, Title 15, U.S. Code Section 70, et seq. 16 CFR 303.7.
(4) International Standards Organization, Guide 25. American National Standards Institute, New York, 1982.
(5) Layman, P. Growth in man-made fibers slowed in 1995, Chemical and Engineering News (May 27, 1996), p. 13.
(6) Fiber Organon, January 1996.
(7) Aspland, J. R. What are dyes? What is dyeing? In: AATCC Dyeing Primer. American Association of Textile Chemists and Colorists, Research Triangle Park, North Carolina, 1981.
(8) Deadman, H. A. Fiber evidence and the Wayne Williams Trial, FBI Law Enforcement Bulletin (March and May 1984).
(9) Grieve, M. C. Fibres and their examination in forensic science. In: Forensic Science Progress (Vol. 4). Eds. A. Maehly and R. L. Williams. Springer, New York, 1990.
ASTM Annual Book of Standards: (Vol. 7.01-7.02). Textiles. American Society for Testing and Materials, West Conshohocken, Pennsylvania, 1996.
Brunello, F. The Art of Dyeing. Trans. B. Hickey. Neri Pozza Editore, Vicenza, Italy, 1973.
Dictionary of Fiber and Textile Technology. Hoechst-Celanese Corporation, Charlotte, North Carolina, 1990.
Technical Manual of the American Association of Textile Chemists and Colorists. AATCC, Research Triangle Park, North Carolina, 1997.
Textile Handbook. The American Home Economics Association, Washington, DC, 1985.
1. See, for examples, C. N. Lowrie and G. Jackson, “Secondary Transfer of Fibers,” in Forensic Science International (1994) 64:73-82, and J. Roberston, C. B. M. Kidd, and H. M. P. Parkinson, “The Persistence of Textile Fibers Transferred During Simulated Contacts,” in Journal of the Forensic Science Society (1982) 22:353-360.
2. See, for example, W. Bruschweiler and M. C. Grieve, “A Study on the Random Distribution of a Red Acrylic Target Fibre,” in Science and Justice (1997) 37:85-90.
3. See D. A. Stoney article in Journal of Forensic Sciences (1984) 24:473-482.
FORENSIC SCIENCE COMMUNICATIONS APRIL 1999 VOLUME 1 NUMBER 1