Evaporation and degradation of the nerve agent, VX [O-ethyl S-2-(N,N-diisopropylamino)ethyl methylphosphonothioate] was explored on common urban or industrial surfaces, including sand, soil, and concrete. Concentration profiles of VX vapor were obtained using a laboratory-sized wind tunnel and thermal desorber in conjunction with gas chromatography. Results show that released VX vapors amounted to <20% of the applied mass and evaporation rates were found to be 0.12 μg/min in sand, 0.088 μg/min in soil, 0.16 μg/min in concrete (water–cement ratio, w/c = 0.50), which are ∼5–10 times slower than in the glass surface. At elevated temperature of 35°C, rates remarkably increased at 0.44 μg/min in sand, 0.12 μg/min in soil, and 0.67 μg/min in concrete. Rates also increased with lower w/c in concrete (0.48 μg/min in concrete [w/c = 0.42] and 0.76 μg/min in concrete [w/c = 0.31]). On the other hand, a drop of neat VX sorbed into the matrices remained for days and degraded following a pseudo first-order rate reaction. Estimated half-lives of VX in these matrices were ∼6 days in sand, 8 days in soil, and 3 days in concrete (w/c = 0.50) at room temperature. Degradation products were the following: ethyl methylphosphonic acid (EMPA), ethyl methylphosphonothioic acid (EMPT), methylphosphonic acid (MPA), 2-(diisopropylamino)ethanethiol (DESH), and bis(2-diisopropylaminoethyl) sulfide [(DES)2]. Parameters, which were quantified and evaluated in this study, will be useful for database establishment in risk assessment of exposure of the general population to highly lethal VX.
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References
1.
BandyopadhyayI., KimM.J., LeeY.S., and ChurchillD.G. (2006). Favorable pendant-amino metal chelation in VX nerve agent model systems. J. Phys. Chem. A, 110, 3655.
2.
BordoK., and RubahnH-G. (2012). Effect of deposition rate on structure and surface morphology of thin evaporated Al films on dielectric and semiconductors. Mater. Sci., 18, 313.
3.
BorisovaA.G., GumerovV.M., and PiskunovM.V. (2016). Influence of surface roughness and porosity of inclusion in water droplet on heat transfer enhancement. MATEC Web of Conferences, 84, 00006, Novosibirsk, Russia, March 2–4, 2016. International Symposium and School of Young Scientist “Interfacial Phenomena and Heat Transfer” (IPHT 2016).
4.
BrevettC.A.S., PenceJ., NickolR.G., MyersJ.P., MaloneyE., GiannarasC.V., FlowersA., SumpterK.B., DurstH.D., and KingB.E. (2008). Evaporation Rates of Chemical Warfare Agents Using 5-cm Wind Tunnels. I. Casarm Sulfur Mustard (HD) from Glass. Aberdeen Proving Ground, MD: Edgewood Chemical Biological Center, Technical Report ECBC-TR-647.
5.
BrevettC.A.S., SumpterK.B., PenceJ., NickolR.G., KingB.E., GiannarasC.V., and DurstH.D. (2009). Evaporation and degradation of VX on silica sand. J. Phys. Chem. C., 113, 6622.
6.
ColumbusI., WaysbortD., MarcovitchI., YehezkelL., and MizrahiD.M. (2012). VX fate on common matrices: Evaporation versus degradation. Environ. Sci. Technol., 46, 3921.
7.
FengA., McCoyB.J., MunirZ.A., and CagliostroD.E. (1996). Water adsorption and desorption kinetics on silica insulation. J. Colloid. Interface Sci., 180, 276.
8.
Flytzani-StephanopoulosM., and SchmidtL.D. (1979). Evaporation rates and surface profiles on heterogeneous surfaces with mass transfer and surface reaction. Chem. Eng. Sci., 34, 365.
9.
Hernon-KennyL.A., BehringerD.L., and CrenshawM.D. (2016). Comparison of latex body paint with wetted gauze wipes for sampling the chemical warfare agents VX and sulfur mustard from common indoor surfaces. Forensic Sci. Int., 262, 143.
10.
GrenshawM.D., HayesT.L., MillerT.L., and ShannonC.M. (2001). Comparison of the hydrolytic stability of S-(N, N-diethylaminoethyl) isobutyl methylphsphonothiolate with VX in dilute solution. J. Appl. Toxicol., 21, S3.
11.
GroenewoldG.S., WillliamsJ.M., AppelhansA.D., GreshamG.L., OlsonJ.E., JefferyM.T., and RowlandB. (2002). Hydrolysis of VX on concrete: Rate of degradation by direct surface interrogation using an ion trap secondary ion mass spectrometer. Environ. Sci. Technol., 36, 4790.
12.
GuraS., TzananiN., HershkovitzM., BarakR., and DaganS. (2006). Fate of the chemical warfare agent VX in asphalt: A novel approach for the quantification of VX in organic surfaces. Arch. Environ. Contam. Toxicol., 51, 1.
13.
HookG.L., KimmG., KochD., SavageP.B., DingB., and SmithP.A. (2003). Detection of VX contamination in soil through solid-phase microextraction sampling and gas chromatography/mass spectrometry of the VX degradation product bis(diisopropylaminoethyl)disulfide. J. Chromatogr. A, 992, 1.
14.
JangY.J., KimK., TsayO.G., AtwoodD.A., and ChruchillD.G. (2015). Update 1 of: Destruction and detection of chemical warfare agents. Chem. Rev., 115, PR1.
15.
JohnsenB.A., TornesJ.A., and OpstadtA.M. (1988). Research Report on Verification of CWC: Development of Procedures for Verification of Alleged Use of Chemical Warfare Agents, Part VII. Norwegian Defense Research Establishment Report FFI/RAPPORT-88/6010, Kjeller, Norway.
16.
JungH., KahD., LimK.C., and LeeJ.Y. (2017). Fate of sulfur mustard on soil: Evaporation, degradation, and vapor emission. Environ. Poll., 220, 478.
17.
KingeryA.F., and AllenH.E. (1993). Extraction and Chromatographic Development of Selected Organophosphorus Compounds from Soil and Aqueous Media. Aberdeen Proving Ground, MD: U.S. Army Environmental Center Technical Support Divisions.
18.
KingeryA.F., and AllenH.E. (1995). The environmental fate of organophosphorus nerve agents: A review. Toxicol. Environ. Chem., 47, 155.
19.
MacNaughtonM.G., and BrewerJ.H. (1994). Environmental Chemistry and Fate of Chemical Warfare Agents. San Antonio, TX: Department of the Army Corps of Engineers, Huntsville Division, Southwest Research Institute, Final Report (SwRI Project 01-5864).
20.
MenonP., and TeoA. (2017). Malaysia Condemns use of VX at Airport; Prepares to Deport North Korean. Reuters, Kuala Lumpur: Friday March 3.
21.
MizrahiD.M., and ColumbusI. (2005). 31P MAS NMR: A useful tool for the evaluation of VX natural weathering in various urban matrices. Environ. Sci. Technol., 39, 8931.
22.
NikitinM.B.D., KerrP.K., and FeickertA. (2013). Syria's Chemical Weapons: Issues for Congress. Report #R42848, Congressional Research Service 7–5700, www.crs.gov
23.
TrappR. (1985). The Detoxification and Natural Degradation of Chemical Warfare Agents. London: Talyor & Francis Publisher.
24.
VerweijA., and BoterH.L. (1976). Degradation of S-2-di-isopropylaminoethyl O-ethyl methylphosphonothioate in soil: Phosphorus-containing products. Pest. Sci., 7, 355.
25.
WagnerG.W., and FryR.A. (2009). Observation of distinct surface AlIV sites and phosphonate binding modes in γ-alumina and concrete by high-field 27Al and 31P MAS NMR. J. Phys. Chem. C, 113, 13352.
26.
WagnerG.W., O'ConnorR.J., and LawrenceR.P. (2001). Preliminary study on the fate of VX in concrete. Langmuir, 17, 4336.
27.
WagnerG.W., O'ConnorR.J., EdwardsJ.L., and BrevettC.A.S. (2004). Effect of drop size on the degradation of VX in concrete. Langmuir, 20, 7146.
28.
WaysbortD., ManisterskiE., LeaderH., ManisterskiB., and AshaniY. (2004). Laboratory setup for long-term monitoring of the volatilization of hazardous materials: Preliminary tests of O-ethyl S-2-(N, N-diisopropylamino)ethyl methylphosphonothiolate on asphalt. Environ. Sci. Technol., 38, 2217.
29.
WeberD.J., ScudderM.K., MouryC.S., ShuelyW.J., MolnarJ.W., and MillerM.C. (2006). Development of the 5-cm Agent Fate Wind Tunnel. Aberdeen Proving Ground, MD: Edgewood Chemical Biological Center: Technical Report ECBC-TR-327.
30.
WillisM.P., MantoothB.A., and LalainT.A. (2012). Novel methodology for the estimation of chemical warfare agent mass transport dynamics, part I: Evaporation. J. Phys. Chem. C, 116, 538.
31.
YokotaT., KiragaK., and YamaneH. (1975). Mass spectrometry of trimethylsilyl derivatives of gibberellin glucosides and glucosyl esters. Phytochemistry, 14, 1569.
