Before learning about the process of collecting fingerprints from crime scene, it is essential to understand how the fingerprints are formed and where can we find them.
Fingerprints can be found on practically any solid surface, including the human body.
Analysts classify fingerprints into three categories according to the type of surface on which they are found and whether they are visible or not, Fingerprints on soft surfaces like soap, wax, wet paint, fresh caulk, etc. are likely to be three-dimensional plastic prints, those on hard surfaces are either patent (visible) or latent (invisible) prints.
One of the most common methods for discovering and collecting latent fingerprints is by dusting a smooth or nonporous surface with fingerprint powder (black granular, aluminium flake, black magnetic, etc.).
If any prints appear, they are photographed as mentioned above and then lifted from the surface with clear adhesive tape. The lifting tape is then placed on a latent lift card to preserve the print.
However, fingerprint powders can contaminate the evidence and ruin the opportunity to perform other techniques that could turn up a hidden print or additional information.
Therefore, investigators may examine the area with an alternate light source or apply cyanoacrylate (super glue) before using powders.
It is becoming more commonplace for investigators to examine any likely surfaces (doors, doorknobs, windows, railings, etc.) with an alternate light source.
These are laser or LED devices that emit a particular wavelength, or spectrum, of light.
Some devices have different filters to provide a variety of spectra that can be photographed or further processed with powders or dye stains.
For example, investigators may use a blue light with an orange filter to find latent prints on desks, chairs, computer equipment or other objects at the scene of a break-in.
Using a fluorescent dye stain and an orange alternate light source helps this latent print appear clearly so that it can be documented. The use of various alternate light sources may help enhance the appearance of a fingerprint.
Investigators often perform cyanoacrylate (superglue) processing, or fuming, of a surface before applying powders or dye stains.
This process, typically performed on non-porous surfaces, involves exposing the object to cyanoacrylate vapours.
The vapours (fumes) will adhere to any prints present on the object allowing them to be viewed with oblique ambient light or a white light Source. Superglue fumes adhere to latent fingerprints on the neck of a glass bottle.
Porous surfaces such as paper are typically processed with chemicals, including ninhydrin and physical developer, to reveal latent fingerprints.
These chemicals react with specific components of latent print residue, such as amino acids and inorganic salts. Ninhydrin causes prints to turn a purple colour, which makes them easily photographed.
DFO (1,2-diazafluoren-9-one) is another chemical used to locate latent fingerprints on porous surfaces; it causes fingerprints to fluoresce, or glow when they are illuminated by a blue-green light. Paper treated with ninhydrin reagent reveals latent prints after being processed with a household steam iron.
In addition to the methods discussed above, there are special techniques for capturing prints from skin, clothing and other difficult surfaces.
Amido Black, an anon-specific protein stain that reacts with any protein present, is typically used for developing or enhancing blood impressions on human skin.
To reveal prints on clothing, high-tech methods such as vacuum metal deposition using gold and zinc are showing promise for the investigator.
AccuTrans, a liquid casting compound, can be used to lift powdered latent prints from rough, textured or curved surfaces. AccuTrans is basically a very thick liquid that fills in the nooks and crannies of rough or textured areas where conventional print lifting tape encounters difficulty.
Like fingerprint powders, chemical processing can reduce the investigator's ability to perform other techniques that could reveal valuable information.
Therefore, any non-destructive investigations are performed before the evidence is treated with chemicals.
For example, a ransom or hold-up note will be examined by a questioned documents expert before being treated with ninhydrin, since some formulations of ninhydrin will cause certain inks to run, thus destroying the writing.
In criminal justice cases, computerized systems are used to search various local, state and national fingerprint databases for potential matches.
Many of these systems provide a value indicating how close the match is, based on the algorithm used to perform the search. Fingerprint examiners then review the potential matches and make a final determination.
Fingerprint examinations may be conducted by forensic scientists, technicians or police officers however, the examiner should have the proper training and experience to perform the task.
Fingerprint analysis is usually performed by law enforcement agencies or crime laboratories however, casework may be sent to private companies if there is a need, such as to reduce backlogs, verify results, or handle high-profile cases. Fingerprint examination involves looking at the quality and quantity of information in order to find agreement or disagreement between the unknown print (from the crime scene) and known prints on file. To conduct the examination, fingerprint examiners use a small magnifier called a loupe to view minute details (minutiae) of a print. A pointer called a ridge counter is used to count the friction ridges.
Fingerprint examiners use the ACE-V (analysis, comparison, evaluation and verification) method to reach a determination on each print.
The analysis involves assessing a print to determine if it can be used for comparison.
If the print is not suitable for comparison because of inadequate quality or quantity of features, the examination ends and the print is reported as not suitable.
If the print is suitable, the analysis indicates the features to be used in the comparison and their tolerances (the amount of variation that will be accepted).
The analysis may also uncover physical features such as recurves, deltas, creases and scars that help indicate where to begin the comparison.
These are performed by an analyst who views the known and suspect prints side-by-side.
The analyst compares minutiae characteristics and locations to determine if they match.
Known prints are often collected from persons of interest, victims, others present at the scene or through a search of one or more fingerprint databases such as the FBI’s Integrated Automated Fingerprint Identification System (IAFIS).
IAFIS is the largest fingerprint database in the world and, as of June 2012, held more than 72 million print records from criminals, military personnel, government employees and other civilian employees.
It is where the examiner ultimately decides if the prints are from the same source (identification or individualization), different sources (exclusion) or are inconclusive.
Inconclusive results may be due to poor quality samples, lack of comparable areas, or an insufficient number of corresponding or dissimilar features to be certain.
It is when another examiner independently analyses, compares and evaluates the prints to either support or refute the conclusions of the original examiner. The examiner may also verify the suitability of determinations made in the analysis phase.
Contact by WhatsApp
Hello RealScan Biometrics