[53] Liang J, Olivares C, Field J A and Sierra-Alvarez R 2013 Microbial toxicity of the insensitive munitions compound, 2,4-dinitroanisole (DNAN), and its aromatic amine metabolites J. Hazard. Mater. 262 281–87
[54] Olivares C, Liang J, Abrell L, Sierra-Alvarez R and Field J A 2013 Pathways of reductive 2,4-dinitroanisole (DNAN) biotransformation in sludge Biotechnol. Bioeng. 110 1595–604
[55] Olivares C I, Abrell L, Khatiwada R, Chorover J, Sierra-alvarez R and Field J A 2016 (Bio) transformation of 2,4-dinitroanisole (DNAN) in soils J. Hazard. Mater. 304 214–21
[56] Arthur J D, Mark N W, Taylor S, Šimunek J, Brusseau M L and Dontsova K M 2017 Batch soil adsorption and column transport studies of 2,4-dinitroanisole (DNAN) in soils J. Contam. Hydrol. 199 14–23
[57] Temple T, Ladyman M, Mai N, Galante E, Ricamora M, Shirazi R and Coulon F 2018 Investigation into the environmental fate of the combined Insensitive high explosive constituents 2,4-dinitroanisole (DNAN), 1-nitroguanidine (NQ) and nitrotriazolone (NTO) in soil Sci. Total Environ. 625 1264–71
[58] Taylor S, Walsh M E, Becher J B, Ringelberg D B, Mannes P Z and Gribble G W 2017 Photo-degradation of 2,4-dinitroanisole (DNAN): an emerging munitions compound Chemosphere 167 193–203
[59] Williams L R, Eck W and Johnson M S 2014 Toxicity of IMX formulations and components: what we know and path forward JANNAF Work. Proc. pp 92–104
[60] Lent E M, Crouse L C B, Hanna T and Wallace S 2012 The Subchronic Oral Toxicity of DNAN and NTO in Rats 87-XE-0DBP-10 US Army Institute of Public Health
[61] Dodard S G, Sarrazin M, Hawari J, Paquet L, Ampleman G, Thiboutot S and Sunahara G I 2013 Ecotoxicological assessment of a high energetic and insensitive munitions compound: 2,4-Dinitroanisole (DNAN) J. Hazard. Mater. 262 143–50
[62] Kennedy A J, Poda A R, Melby N L, Moores L C, Jordan S M, Gust K A and Bednar A J 2017 Aquatic toxicity of photo-degraded insensitive munition 101 (IMX-101) constituents Environ. Toxicol. Chem. 36 2050–57
[63] Lotufo G R, Rosen G, Wild W and Carton G 2013 Tehcnical Report: Summary review of the aquatic toxicology of munitions constituents ERDC/EL TR-13-8, Hanover, USA
[64] Mirecki J E, Porter B, Weiss J and Charles A 2006 Technical Report: Environmental transport and fate process descriptors for propellant compounds ERDC/EL TR-06-7, Hanover, USA
[65] Hartley W R, Roberts W C and Brower E 1992 Drinking Water Health Advisory: Munitions ed W C Roberts and W R Hartley (Boca Raton, FL: Lewis Publishers)
[66] Bordeleau G, Martel R, Drouin M, Ampleman G and Thiboutot S 2014 Biodegradation of nitroglycerin from propellant residues on military training ranges J. Environ. Qual. 43 441
[67] Lee K E, Balas-Hummers W A, Di Stasio A R, Patel C H, Samuels P J, Roos B D and Fung V 2010 Technical Report: Qualification testing of the insensitive TNT replacement explosive IMX-101, Picatinny Arsenal, NJ, USA
[68] Walsh M R, Temple T, Bigl M F, Tshabalala S F, Mai N and Ladyman M 2017 Investigation of energetic particle distribution from high-order detonations of munitions, propellants Prop. Explos. Pyrotech. 42 602–88
[69] Mulherin N D, Jenkins T F and Walsh M E 2005 Technical Report: Stability of nitroguanidine in moist, unsaturated soils ERDC/CRREL-TR-05-2, Hanover, USA
[70] Walsh M R, Walsh M E, Ramsey C A, Brochu S, Thiboutot S and Ampleman G 2013 Perchlorate contamination from the detonation of insensitive high-explosive rounds J. Hazard. Mater. 262 228–33
[71] Smith P N, Theodorakis C W, Anderson T A and Kendall R J 2001 Preliminary assessment of perchlorate in ecological receptors at the longhorn army ammunition plant (LHAAP), Karnack, Texas Ecotoxicology 10 305–13
[72] Blake S, Hall T, Harman M, Kanda R, McLaughlin C and Rumsby P 2009 Technical report: perchlorate – risks to UK drinking water sources Department for Environment, Food & Rural Affairs No. 7845, Swindon, UK
[73] Leung A M, Pearce E N and Braverman L E 2014 Environmental perchlorate exposure: potential adverse thyroid effects Curr. Opin. Endocrinol. Diabetes. Obes. 21 372–76
[74] Steinmaus C M 2016 Perchlorate in water supplies: sources, exposures, and health effects Curr. Environ. Heal. Reports 3 136–43
[75] Walsh M, Thiboutot S and Gullett B 2017 Technical report: characterization of residues from the detonation of insensitive munitions distribution statement ER-2219. Defence Research and Development, Ottawa, Canada
[76] Dontsova K, Brusseau M, Arthur J, Mark N, Taylor S, Pesce-rodriguez R, Walsh M, Lever J and Šim J 2014 Technical Report: Dissolution of NTO, DNAN and insensitive munitions formulations and their fates in soils ERDC/CRREL TR-14-23, Hanover, USA
[77] Braida W J, Wazne M, Ogundipe A, Tuna G S, Pavlov J and Koutsospyros A 2012 Transport of nitrotriazolone (NTO) in soil lysimeters Prot. Restor. Environ. Conf. XI (Thessaloniki, Greece)
[78] Mark N, Arthur J, Dontsova K, Brusseau M and Taylor S 2016 Adsorption and attenuation behavior of 3-nitro-1,2,4-triazol-5-one (NTO) in eleven soils Chemosphere 144 1249–55
[79] Richard T and Weidhaas J 2014 Biodegradation of IMX-101 explosive formulation constituents: 2,4-dinitroanisole (DNAN), 3-nitro-1,2,4-triazol-5-one (NTO), and nitroguanidine J. Hazard. Mater. 280 561–69
[80] Arthur J D, Mark N W, Taylor S, Šimůnek J, Brusseau M L and Dontsova K M 2018 Dissolution and transport of insensitive munitions formulations IMX-101 and IMX-104 in saturated soil columns Sci. Total Environ. 624 758–68
[81] Mark N, Arthur J, Dontsova K, Brusseau M, Taylor S and Šimůnek J 2017 Column transport studies of 3-nitro-1,2,4-triazol-5-one (NTO) in soils Chemosphere 171 427–34
[82] Mark N W 2014 Batch and ColumnTransport Studies of Environmental