Application of lead isotope analysis in shooting incident investigations

References 

1. Zeichner A. Recent developments in methods of chemical analysis in investigations of firearm-related events. Anal. Bioanal. Chem. 2003;376:1178–1191
   • MEDLINE
   • CrossRef
2. Koons RD, Grant DM. Compositional variation in bullet lead manufacture. J. Foren. Sci. 2002;47(5):950–958
3. H.R. Lukens, et al., Forensic neutron activation analysis of bullet-lead specimens, USAEC Report GA-10141, Gulf General Atomic Incorporated, San Diego, CA, 1970.
4. Suzuki Y, Marumo Y. Determination of trace impurities in lead shotgun pellets by ICP–MS. Anal. Sci. 1996;12:129–132
   • CrossRef
5. Dufosse T, Touron P. Comparison of bullet alloys by chemical analysis: use of ICP–MS method. Foren. Sci. Int. 1998;91:197–206
6. Keto RO. Analysis and comparison of bullet leads by inductively-coupled plasma mass spectrometry. J. Foren. Sci. 1999;44(5):1020–1026
7. Randich E, et al. A metallurgical review of the interpretation of bullet lead compositional analysis. Foren. Sci. Int. 2002;127:174–191
8. The U.S. National Academy of Sciences Report, Forensic Analysis: Weighing Bullet Lead Evidence, 2004.
9. Andrasko J, et al. Measurement of lead isotope ratio in lead smears and bullet fragments and its application to firearm investigations. J. Foren. Sci. 1993;38(5):1161–1171
10. Stupian GW, et al. The application of lead isotope analysis to bullet individualization in two homicides. J. Foren. Sci. 2001;46(6):1342–1351
11. Cheylan P, et al. Fundamental processes in GSR formation as deduced from ICP–AES and SF-ICPMS experiments. In: Proceedings of the AAFS Meeting. Atlanta, GA, USA. 2002;
12. Gulson BI, Eames JC, Davis JD. Evaluation of exhibits from a murder case using the lead isotope method and scanning electron microscopy. J. Foren. Sci. 2002;47(5):1015–1021
13. Walder AJ, Freedman PA. Isotope ratio measurements using a double focusing magnetic sector mass analyzer with ICP as ion source. J. Anal. Atom. Spectrom. 1992;7:571–575
14. Hoogerwerff J. Nite-crime thematic network: natural isotopes and trace elements in criminalistics and environmental forensics. In: Proceedings of the Second Meeting of the EAFS. Cracow, Poland. 2000;
15. Plazner I, Ehrlich S, Halicz L. Isotope-ratio measurements of lead in NIST standard reference materials by multiple-collector inductively coupled plasma mass spectrometry. Fresen. J. Anal. Chem. 2001;370:624–628
16. Heumann KG. Precision and accuracy in isotope ratio measurements by plasma source mass spectrometry. J. Anal. Atom. Spectrom. 1998;13:1001–1008
17. Dillon JH. The sodium rhodizonate test: a chemically specific chromophoric test for lead in gunshot residues. AFTE J. 1990;22(3):251–256
18. Belshaw NS. A new variable dispersion double-focussing plasma mass spectrometer with performance illustrated for PB isotopes. Int. J. Mass Spectrom. 1998;181:51–58
19. Peters CA. The basis for compositional bullet lead comparisons. Foren. Sci. Commun. 2002;4(3):
20. Wolten GM, Nesbitt RS. On the mechanism of gunshot residue particle formation. J. Foren. Sci. 1980;25(3):533–545
21. Wallace JS, McQuillan J. Discharge residues from cartridge-operated industrial tools. J. Foren. Sci. Soc. 1984;24(5):495–508
22. Zeichner A, Levin N, Springer E. Gunshot residue particles formed by using different types of ammunition in the same firearm. J. Foren. Sci. 1991;36(4):1020–1026
23. Guranatnam L, Himberg K. The identification of gunshot residue particles from lead-free Sintox ammunition. J. Foren. Sci. 1994;39(2):532–536
24. Harris A. Analysis of primer residue from CCI Blazer lead free ammunition by scanning electron microscopy/energy dispersive X-ray. J Foren. Sci. 1995;40(1):27–30
25. Andrasko J. Characterization of smokeless powder flakes from fired cartridge cases and from discharge patterns on clothing. J. Foren. Sci. 1992;37(4):1030–1047
26. MacCrehan WA. Investigating the effect of changing ammunition on the composition of organic additives in gunshot residues (OGSR). J. Foren. Sci. 2001;46(1):57–62