Energetic characteristics of transition metal complexes

Journal of Hazardous Materials

Volumn 171, Issue 1-3, 2009, Pages 1175-1177

  Wojewódka, Andrzej ^a   Bełzowski, Janusz ^a   Wilk, Zenon ^b   Staś, Justyna ^b  

^a SILESIAN UNIVERSITY OF TECHNOLOGY   (Poland)

^b INSTITUTE OF INDUSTRIAL ORGANIC CHEMISTRY   (Poland)

Author keywords

Bubble energy equivalent; Shock wave; Shock wave energy equivalent; Transition metal complexes; Underwater detonation test

Indexed keywords

BUBBLE ENERGY; BUBBLE ENERGY EQUIVALENT; ENERGETIC CHARACTERISTICS; ETHYLENE DIAMINE; HIGH EXPLOSIVES; OVERPRESSURE; PRIMARY EXPLOSIVE; SHOCK WAVE ENERGY; SHOCK WAVE ENERGY EQUIVALENT; UNDERWATER DETONATION; UNDERWATER DETONATION TEST;

BUBBLES (IN FLUIDS); CHROMIUM; EQUIVALENCE CLASSES; MERCURY (METAL); METAL COMPLEXES; METALS; NICKEL; SHOCK WAVES; TRANSITION METAL COMPOUNDS; WAVE ENERGY CONVERSION; WAVES; ZINC;

DETONATION;

ETHYLENEDIAMINE; HYDRAZINE; NITRATE; PERCHLORATE; TRANSITION ELEMENT;

EXPLOSIVE; NITRATE; PERCHLORATE; SHOCK WAVE; TRANSITION ELEMENT;

ARTICLE; CHEMICAL ANALYSIS; COMPLEX FORMATION; CONTROLLED STUDY; ENERGY TRANSFER; EXPLOSION; SHOCK WAVE;

ETHYLENEDIAMINES; EXPLOSIVE AGENTS; HYDRAZINES; MATERIALS TESTING; METALS; NITRATES; REPRODUCIBILITY OF RESULTS; TEMPERATURE; THERMODYNAMICS; TRANSITION ELEMENTS;

EID: 70349257222     PISSN: 03043894     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jhazmat.2009.06.104     Document Type: Article

References (12)

1. Zhu S.G., Wu Y.C., Zhang W.Y., and Mu J.G. Evaluation of a new primary explosive: nickel hydrazine nitrate (NHN) complex. Propellant Explosives and Pyrotechnics 22 (1997) 317-320
2. Hao C.H. The relationship between the structure and some performances of mercuric-5-nitrotetrazole. Proceedings of 11th Symposium on Explosives and Pyrotechnics (1975) 1-13
3. Cudziło S., and Szmigielski R. Synthesis and investigation of some di-(R-1,2,4-triazolato)copper(II) perchlorates. Biuletyn WAT 12 (2003) 5-17
4. Talawar M.B., et al. Synthesis, characterization, thermolysis and performance evaluation of mercuric-5-nitrotetrazole (MNT). Journal of Hazardous Materials A113 (2004) 27-33
5. Ilyushin M.A., and Tselinskii I.V. Primary explosives, the present and prospects. Russian Journal of Chemistry 41 4 (1997) 3-13
6. Talawar M.B., et al. Studies on lead-free initiators: synthesis, characterization and performance evaluation of transition metal complexes of carbohydrazide. Journal of Hazardous Materials A113 (2004) 65-77
7. Zhilin Yu., Ilyushin M.A., Tselinskii I.V., Kozlov A.S., and Lisker I.S. High-energy-capacity cobalt(III) tetrazolates. Russian Journal of Applied Chemistry 76 4 (2003) 572-576
8. Patil K.C. Metal-hydrazine complexes as precursors to oxide materials. Proceedings - Indian Academy of Sciences, Chemical Sciences, vol. 96, no. 6 (1986) 459-464
9. II macrocyclic complexes containing biimidazole. Polyhedron 16 23 (1997) 3997-4004
10. Talawar M.B., Agrawal A.P., Anniyappan M., Wani D.S., Bansode M.K., and Gore G.M. Primary explosives: electrostatic discharge initiation, additive effect and its relation to thermal and explosive characteristics. Journal of Hazardous Materials B137 (2006) 1074-1078
11. Koslik P., Staś J., Wilk Z., and Zakrzewski A. Research of high explosives based on RDX, HMX and CL-20 in the small scale underwater test examination. Central European Journal of Energetic Materials 4 3 (2007) 3-13
12. European Standard EN 13763-15, Explosives for civil uses - Detonators and relays - Part 15: Determination of equivalent initiating capability, 2004.