Towards the protection of ammunition headstamps during fingermark enhancement processing; a preliminary study.

Forensic recovery from fired ammunition casings remains one of the most challenging tasks during high-profile investigations. Often, the decision must be made between screening for DNA or fingerprints, and, in doing so, the impact these processes will have on the examination of ballistic markings imparted on the ammunition from the firearm itself. Traditionally, fingermark enhancement processes have yielded low success rates in their efforts to identify suspects by enhancing friction ridge detail left on the cartridge casings. Moreover, the enhancement methods utilised may often induce detrimental physical changes to the casing(s), rendering them unsuitable for subsequent ballistics (marking) examination. Recently, new technology has been shown to increase the success rate of fingermark recovery from fired ammunition, and the growing adoption of such innovation means that new challenges are encountered to maximise evidence recovery and streamline forensic workflows. One such example arises from the potential obscuration of the ammunition headstamp area during such treatments. Accordingly, this study outlines the preliminary investigations and developments of a polymer mask substrate that serves to protect the headstamp of fired ammunition casings during relevant fingermark enhancement processes. The technique also has the capacity to be used as a surface protection device to eliminate unwanted chemical deposition across other areas of interest and evidence types.

The use of longwave reflected UV imaging for the enhancement of cyanoacrylate developed fingermarks: A simple, safe and effective imaging tool.

Longwave ultraviolet reflection (LWUVR) imaging is reported as a simple, safe and non-invasive technique that significantly aids in the visualisation of cyanoacrylate developed latent fingermarks. The process can precede traditional cyanoacrylate dye staining and often removes the necessity to use these chemical contrast reagents, saving time, cost and eliminating mess. The non-destructive nature of the process and high resolution images that are obtained, builds upon issues that surround shorter-wavelength UV imaging. It has been demonstrated that, for most samples tested (a range of non-porous and semi-porous evidence), LWUVR imaging provided superior or similar results to those obtained using the traditional BY40 dye stain. The lack of penetration depth by LWUV radiation means that only the features of the surface under observation is detected by the camera, meaning that interference that may otherwise arise from fluorescence on the reverse side of the evidence (BY40 or fluorescent inks) under conventional fluorescent dye stain imaging modes, is mitigated. A new sequential processing workflow is proposed that does not impede with the conventional and widely adopted fume>stain>fluorescence sequence, but in fact allows LWUVR imaging to be conducted in a manner that serves to benefit the sequence and, ideally, save time during the examination and treatment of evidence.

Visualisation of latent fingermarks on polymer banknotes using copper vacuum metal deposition: A preliminary study.

The UK's recent move to polymer banknotes has seen some of the currently used fingermark enhancement techniques for currency potentially become redundant, due to the surface characteristics of the polymer substrates. Possessing a non-porous surface with some semi-porous properties, alternate processes are required for polymer banknotes. This preliminary investigation explored the recovery of fingermarks from polymer notes via vacuum metal deposition using elemental copper. The study successfully demonstrated that fresh latent fingermarks, from an individual donor, could be clearly developed and imaged in the near infrared. By varying the deposition thickness of the copper, the contrast between the fingermark minutiae and the substrate could be readily optimised. Where the deposition thickness was thin enough to be visually indistinguishable, forensic gelatin lifters could be used to lift the fingermarks. These lifts could then be treated with rubeanic acid to produce a visually distinguishable mark. The technique has shown enough promise that it could be effectively utilised on other semi- and non-porous substrates.