Fiber analysis

Last updated March 31, 2022

Fiber analysis is a method of identifying and examining fibers used by law enforcement agencies around the world to procure evidence during an investigation. Fiber analysis is also used by law enforcement agencies to place suspects at the scene of the crime. Transfer of fiber can occur during close contact with the victim or suspect. Fiber transfers can also occur during break-ins where fibers from the intruder are caught in.^[1]^[2] Fiber evidence is a type of trace evidence, this means it will likely be very small and sometimes could be microscopic.^[3] This method is usually not used to actually pinpoint an offender in an investigation as it is not as reliable as DNA.^[1]

Fiber analysis does not follow any officially laid-down procedure. The most common use of fiber analysis is microscopic examination of both longitudinal and cross sectional samples. While this is the most common method of undertaking fiber analysis, others do exist. These include the burning and solubility methods. These methods are most commonly used to reveal the identity of the fiber. Fiber analysis is usually not undertaken in university labs because of the usual lack of required solvents.^[2]

Methods

Scanning electron microscopy

Scanning electron microscopy (SEM) is method of photography which requires an instrument called the scanning electron microscope, which uses electrons rather than light to form an image. There are many advantages to using the SEM instead of a light microscope. Using SEM requires a large depth of field, which allows a large amount of the sample to be in focus at one time.^[4]

Atomic force microscopy

Atomic force microscopy is a method which is carried out using an atomic force microscope, which is an instrument that can analyze and characterize samples at the microscopic level. The instrument allows the analyst to look at surface characteristics with very accurate resolution ranging from 100 μm to less than 1 μm.^[5]

Comparison Microscopy

Comparison microscopes are often used by analysts to look at the general characteristics of the fibers. This technique is generally only useful when comparing a known sample from a scene to a possible source. The analysts will look at a cross section of the fibers under a comparison microscope and look at characteristics such as frays, cuts, striations, crimps, colour, thickness, and general shapes within the fiber. The comparison microscope allows for two samples to be observed simultaneously. ^[3]

Dyes

There are many types of dyes and colours that are used on fibers. To help analysts narrow down their sample the American Association of Textile Chemists generates a colour index that contains all dyes and colours that are used on fibers. This allows analysts to compare their sample to known data in order to determine possible sources.^[6]

It is also important for analysts to know the types of dyes that can be used on fibers. The most common list of dyes that are used can be seen below.^[3] These classes of dye are determined through how they are applied to fibers.^[6]

Acid Dyes: used in basic conditions, functional group of fiber is protonated and bonds to functional group of dye.^[6]
Basic Dyes: used in acidic conditions, functional group of fiber is deprotonated and bonds to functional group of dye.^[6]
Azoic Dyes: use diazo salt and a coupling agent to dye fibers.^[6]
Direct Dyes: dye is applied using heat and electrolytes.^[6]
Disperse Dyes: Van der Waal forces and hydrogen bonding dye the fibers.^[6]
Metallized Dyes: metal complexes forms between the dye and fiber.^[6]
Sulfur Dyes: dye is reduced and then oxidizes with the fiber to bond, the dye becomes insoluble.^[6]
Vat Dyes: similar process to sulfur dyes, dye becomes insoluble with fiber once oxidation occurs.^[6]

Related Research Articles

An electron microscope is a microscope that uses a beam of accelerated electrons as a source of illumination. As the wavelength of an electron can be up to 100,000 times shorter than that of visible light photons, electron microscopes have a higher resolving power than light microscopes and can reveal the structure of smaller objects. A scanning transmission electron microscope has achieved better than 50 pm resolution in annular dark-field imaging mode and magnifications of up to about 10,000,000× whereas most light microscopes are limited by diffraction to about 200 nm resolution and useful magnifications below 2000×.

Microscopy is the technical field of using microscopes to view objects and areas of objects that cannot be seen with the naked eye. There are three well-known branches of microscopy: optical, electron, and scanning probe microscopy, along with the emerging field of X-ray microscopy.

A microscope is a laboratory instrument used to examine objects that are too small to be seen by the naked eye. Microscopy is the science of investigating small objects and structures using a microscope. Microscopic means being invisible to the eye unless aided by a microscope.

A scanning electron microscope (SEM) is a type of electron microscope that produces images of a sample by scanning the surface with a focused beam of electrons. The electrons interact with atoms in the sample, producing various signals that contain information about the surface topography and composition of the sample. The electron beam is scanned in a raster scan pattern, and the position of the beam is combined with the intensity of the detected signal to produce an image. In the most common SEM mode, secondary electrons emitted by atoms excited by the electron beam are detected using a secondary electron detector. The number of secondary electrons that can be detected, and thus the signal intensity, depends, among other things, on specimen topography. Some SEMs can achieve resolutions better than 1 nanometer.

The optical microscope, also referred to as a light microscope, is a type of microscope that commonly uses visible light and a system of lenses to generate magnified images of small objects. Optical microscopes are the oldest design of microscope and were possibly invented in their present compound form in the 17th century. Basic optical microscopes can be very simple, although many complex designs aim to improve resolution and sample contrast.

Transmission electron microscopy (TEM) is a microscopy technique in which a beam of electrons is transmitted through a specimen to form an image. The specimen is most often an ultrathin section less than 100 nm thick or a suspension on a grid. An image is formed from the interaction of the electrons with the sample as the beam is transmitted through the specimen. The image is then magnified and focused onto an imaging device, such as a fluorescent screen, a layer of photographic film, or a sensor such as a scintillator attached to a charge-coupled device.

Particle-induced X-ray emission or proton-induced X-ray emission (PIXE) is a technique used for determining the elemental composition of a material or a sample. When a material is exposed to an ion beam, atomic interactions occur that give off EM radiation of wavelengths in the x-ray part of the electromagnetic spectrum specific to an element. PIXE is a powerful yet non-destructive elemental analysis technique now used routinely by geologists, archaeologists, art conservators and others to help answer questions of provenance, dating and authenticity.

$Diffraction-limited system Optical system with resolution performance at the instruments theoretical limit$

The resolution of an optical imaging system – a microscope, telescope, or camera – can be limited by factors such as imperfections in the lenses or misalignment. However, there is a principal limit to the resolution of any optical system, due to the physics of diffraction. An optical system with resolution performance at the instrument's theoretical limit is said to be diffraction-limited.

Energy-dispersive X-ray spectroscopy, sometimes called energy dispersive X-ray analysis or energy dispersive X-ray microanalysis (EDXMA), is an analytical technique used for the elemental analysis or chemical characterization of a sample. It relies on an interaction of some source of X-ray excitation and a sample. Its characterization capabilities are due in large part to the fundamental principle that each element has a unique atomic structure allowing a unique set of peaks on its electromagnetic emission spectrum. The peak positions are predicted by the Moseley's law with accuracy much better than experimental resolution of a typical EDX instrument.

A fluorescence microscope is an optical microscope that uses fluorescence instead of, or in addition to, scattering, reflection, and attenuation or absorption, to study the properties of organic or inorganic substances. "Fluorescence microscope" refers to any microscope that uses fluorescence to generate an image, whether it is a simple set up like an epifluorescence microscope or a more complicated design such as a confocal microscope, which uses optical sectioning to get better resolution of the fluorescence image.

A microtome is a cutting tool used to produce extremely thin slices of material known as sections. Important in science, microtomes are used in microscopy, allowing for the preparation of samples for observation under transmitted light or electron radiation.

Trace evidence Type of evidence of physical contact

Trace evidence is created when objects make contact. The material is often transferred by heat or induced by contact friction.

Characterization (materials science) Study of material structure and properties

Characterization, when used in materials science, refers to the broad and general process by which a material's structure and properties are probed and measured. It is a fundamental process in the field of materials science, without which no scientific understanding of engineering materials could be ascertained. The scope of the term often differs; some definitions limit the term's use to techniques which study the microscopic structure and properties of materials, while others use the term to refer to any materials analysis process including macroscopic techniques such as mechanical testing, thermal analysis and density calculation. The scale of the structures observed in materials characterization ranges from angstroms, such as in the imaging of individual atoms and chemical bonds, up to centimeters, such as in the imaging of coarse grain structures in metals.

Dark-field microscopy describes microscopy methods, in both light and electron microscopy, which exclude the unscattered beam from the image. As a result, the field around the specimen is generally dark.

The environmental scanning electron microscope (ESEM) is a scanning electron microscope (SEM) that allows for the option of collecting electron micrographs of specimens that are wet, uncoated, or both by allowing for a gaseous environment in the specimen chamber. Although there were earlier successes at viewing wet specimens in internal chambers in modified SEMs, the ESEM with its specialized electron detectors and its differential pumping systems, to allow for the transfer of the electron beam from the high vacuum in the gun area to the high pressure attainable in its specimen chamber, make it a complete and unique instrument designed for the purpose of imaging specimens in their natural state. The instrument was designed originally by Gerasimos Danilatos while working at the University of New South Wales.

Nanometrology is a subfield of metrology, concerned with the science of measurement at the nanoscale level. Nanometrology has a crucial role in order to produce nanomaterials and devices with a high degree of accuracy and reliability in nanomanufacturing.

Lipid bilayer characterization is the use of various optical, chemical and physical probing methods to study the properties of lipid bilayers. Many of these techniques are elaborate and require expensive equipment because the fundamental nature of the lipid bilayer makes it a very difficult structure to study. An individual bilayer, since it is only a few nanometers thick, is invisible in traditional light microscopy. The bilayer is also a relatively fragile structure since it is held together entirely by non-covalent bonds and is irreversibly destroyed if removed from water. In spite of these limitations dozens of techniques have been developed over the last seventy years to allow investigations of the structure and function of bilayers. The first general approach was to utilize non-destructive in situ measurements such as x-ray diffraction and electrical resistance which measured bilayer properties but did not actually image the bilayer. Later, protocols were developed to modify the bilayer and allow its direct visualization at first in the electron microscope and, more recently, with fluorescence microscopy. Over the past two decades, a new generation of characterization tools including AFM has allowed the direct probing and imaging of membranes in situ with little to no chemical or physical modification. More recently, dual polarisation interferometry has been used to measure the optical birefringence of lipid bilayers to characterise order and disruption associated with interactions or environmental effects.

The Raman microscope is a laser-based microscopic device used to perform Raman spectroscopy. The term MOLE is used to refer to the Raman-based microprobe. The technique used is named after C. V. Raman who discovered the scattering properties in liquids.

Multi-tip scanning tunneling microscopy extends scanning tunneling microscopy (STM) from imaging to dedicated electrical measurements at the nanoscale like a ″multimeter at the nanoscale″. In materials science, nanoscience, and nanotechnology, it is desirable to measure electrical properties at a particular position of the sample. For this purpose, multi-tip STMs in which several tips are operated independently have been developed. Apart from imaging the sample, the tips of a multi-tip STM are used to form contacts to the sample at desired locations and to perform local electrical measurements.

The Austrian Centre for Electron Microscopy and Nanoanalysis is a cooperation between the Institute of Electron Microscopy and Nanoanalysis (FELMI) of the Graz University of Technology (TUG) and the Graz Centre of Electron Microscopy (ZFE), which is a member of Austrian Cooperative Research (ACR) and run by the non-profit association for the promotion of electron microscopy. It is located at the “Neue Technik Steyrergasse” campus in Graz.

References

1 2 Ramsland, Katherine. "Trace Evidence". TruTV. Archived from the original on October 3, 2012. Retrieved April 5, 2011.
1 2 A. Katz, David. "Study into Fiber analysis" (PDF). Chymist.com. Retrieved April 5, 2011.
1 2 3 Farah, Shady; Kunduru, Konda Reddy; Tsach, Tsadok; Bentolila, Alfonso; Domb, Abraham J. (April 30, 2015). "Forensic comparison of synthetic fibers". Polymers for Advanced Technologies. 26 (7): 785–796. doi:10.1002/pat.3540. ISSN 1042-7147.
↑ "WHAT IS THE S.E.M.?". Iowa State University. Archived from the original on July 19, 2011. Retrieved April 5, 2011.
↑ "Atomic Force Microscopy: A Guide to Understanding and Using the AFM" (PDF). Texas State University. Archived from the original (PDF) on July 22, 2011. Retrieved April 6, 2011.
1 2 3 4 5 6 7 8 9 10 Goodpaster, John V.; Liszewski, Elisa A. (August 1, 2009). "Forensic analysis of dyed textile fibers". Analytical and Bioanalytical Chemistry. 394 (8): 2009–2018. doi:10.1007/s00216-009-2885-7. ISSN 1618-2650.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[TruTVref-1] 1 2 Ramsland, Katherine. "Trace Evidence". TruTV. Archived from the original on October 3, 2012. Retrieved April 5, 2011.

[fiberanalysis-2] 1 2 A. Katz, David. "Study into Fiber analysis" (PDF). Chymist.com. Retrieved April 5, 2011.

[:0-3] 1 2 3 Farah, Shady; Kunduru, Konda Reddy; Tsach, Tsadok; Bentolila, Alfonso; Domb, Abraham J. (April 30, 2015). "Forensic comparison of synthetic fibers". Polymers for Advanced Technologies. 26 (7): 785–796. doi:10.1002/pat.3540. ISSN 1042-7147.

[IAStateref-4] "WHAT IS THE S.E.M.?". Iowa State University. Archived from the original on July 19, 2011. Retrieved April 5, 2011.

[TXstateref-5] "Atomic Force Microscopy: A Guide to Understanding and Using the AFM" (PDF). Texas State University. Archived from the original (PDF) on July 22, 2011. Retrieved April 6, 2011.

[:1-6] 1 2 3 4 5 6 7 8 9 10 Goodpaster, John V.; Liszewski, Elisa A. (August 1, 2009). "Forensic analysis of dyed textile fibers". Analytical and Bioanalytical Chemistry. 394 (8): 2009–2018. doi:10.1007/s00216-009-2885-7. ISSN 1618-2650.

[1]

[2]

[3]

[4]

[5]

[6]