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Abstract Forensic science practitioners are often called upon to attribute crimes using trace evidence, such as explosive remnants, with the ultimate goal of associating a crime with a suspect or suspects in order to prevent further attacks. The explosive charge is an attractive component for attribution in crimes involving explosives as there are limited pathways for acquisition. However, there is currently no capability to link an explosive charge to its source via post‐blast trace residues using isotope ratios or trace elements. Here, we sought to determine if pre‐blast attribution signatures are preserved after detonation and can be subsequently recovered and detected. A field study was conducted to recover samples of post‐blast explosives from controlled detonations of ammonium nitrate‐aluminum (AN‐Al), which were then analyzed via isotope ratio mass spectrometry (IRMS) and inductively coupled plasma‐mass spectrometry (ICP‐MS) for quantitation and profiling of isotopes ratio and trace element signatures, respectively. Oxygen and nitrogen isotope ratios from AN‐Al yielded some of the most promising results with considerable overlap within one standard deviation of the reference between the spreads of pre‐ and post‐blast data. Trace element results from AN‐Al support the findings in the isotope ratio data, with 26 elements detected in both pre‐ and post‐blast samples, and several elements including B, Cd, Cr, Ni, Sn, V, and Zn showing considerable overlap. These preliminary results provide a proof‐of‐concept for the development of forensic examinations that can attribute signatures from post‐blast debris to signatures in pre‐blast explosive materials for use in future investigations. 

Abstract Recent advances in complex automated handwriting identification systems have led to a lack of understandability of these systems’ computational processes and features by the forensic handwriting examiners that they are designed to support. To mitigate this issue, this research studied the relationship between two systems: FLASH ID^®, an automated handwriting/black box system that uses measurements extracted from a static image of handwriting, and MovAlyzeR^®, a system that captures kinematic features from pen strokes. For this study, 33 writers each wrote 60 phrases from the London Letter using cursive writing and handprinting, which led to thousands of sample pairs for analysis. The dissimilarities between pairs of samples were calculated using two score functions (one for each system). The observed results indicate that dissimilarity scores based on kinematic spatial‐geometric pen stroke features (e.g., amplitude and slant) have a statistically significant relationship with dissimilarity scores obtained using static, graph‐based features used by the FLASH ID^®system. Similar relationships were observed for temporal features (e.g., duration and velocity) but not pen pressure, and for both handprinting and cursive samples. These results strongly imply that both the current implementation of FLASH ID^®and MovAlyzeR^®rely on similar features sets when measuring differences in pairs of handwritten samples. These results suggest that studies of biometric discrimination using MovAlyzeR^®, specifically those based on the spatial‐geometric feature set, support the validity of biometric matching algorithms based on FLASH ID^®output.