Simple detection of adamsite based on substitution-type reactions
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- SIMPLE DETECTION OF ADAMSITE BASED ON SUBSTITUTION-TYPE REACTIONS
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- 2.2 Procedures
- 3. RESULTS AND DISCUSSION
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Science & Military 1/2007 Expert papers
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SIMPLE DETECTION OF ADAMSITE BASED ON SUBSTITUTION-TYPE REACTIONS Vladimír PITSCHMANN, Emil HALÁMEK, Zbyněk KOBLIHA
tubes based on substitution-type reactions were developed. The first method is based on electrophilic reaction of adamsite with sodium nitrite in acidic solution which results in red nitroso or isonitroso derivate. The second method is based on nucleophilic reaction of adamsite with ammonium thiocyanate, affording a yellow product. The detection limit for adamsite in air is 0.5 µg for the first described method and 5 µg for the second. Visual evaluation of detector tubes is based on intensity of color developed on the indication layer.
1. INTRODUCTION Adamsite [10-chloro-5,10-dihydrophenarsazine, code labeling DM] is a warfare agent of the first generation, with irritating effect on the upper respiratory tract (for selected properties see Tab. 1).
Tab. 1 Some selected properties of adamsite [1] Parameter Value CAS Number 578-94-9 Molecular weight 277.54 Structural formula
Boiling point, °C 410 Melting point, °C 195 Volatility, mg.m -3 19 300 (0 °C), 26 000 (20 °C), 72 500 (25 °C) Solubility acetone, furfural, hexane (insoluble in water) ICt 50
-3
22 – 150 LCt 50 , mg.min.m -3 11 000 – 35 000
The first compound of this type is 10-bromo- 5,10-dihydrophenarsazine, prepared in 1913 at Bayer works in Germany. Adamsite itself was synthesized two years later by German chemist Heinrich Wieland and at the end of World War I independently developed by a team of American chemists at Illinois University, headed by Roger Adams who suggested its possible military use. During the World War II, its non-nitrogen analogue excelsior (5-chloro-10-methylacridarsine) was introduced in Germany. Six thousand one hundred tons of adamsite have been stockpiled by the Soviet Union, 300 t by the U.S.A. and 3 700 t by Germany. In March 1939, the Czechoslovak Army possessed one ton of adamsite. At present, this substance is subject to the Chemical Weapons Convention. Only scarce data on the military use of adamsite are at disposal. It was probably first deployed by Italian troops already before the end of World War I. It was used by British intervention forces during the Russian civil war and by the American Army in Vietnam. In all these cases adamsite proved to be an insidious and very effective warfare agent. It is also known that for its incapacitating effect adamsite was used by police forces as riot controlling agent. At present, it may be misused by terrorists. Thus, e.g., an information was disclosed about plans of some militant Islamic groups to use adamsite against selected embassies and state buildings in Belgium [2]. For this reason, investigation on chemical analysis of adamsite and structurally similar compounds cannot be underestimated. The practically only warfare state of adamsite is a toxic smoke capable of attacking efficiently the upper respiratory tract. This fact significantly limits the potentialities of technical means for detection of adamsite in air, in which also detection tubes play an unsubstitutable role. As regards the reaction principles, only a few functional variants of detection tubes are known. A simplest device contains glass wool for effective trapping of the aerosol, and an ampoule filled with sulfuric acid which with adamsite affords red coloration of unknown composition [3]. A similar reaction is also produced by action of formic acid (on heating) and perchloric acid which gives a pink colored product [4]. This system is little selective and therefore a detection tube has been developed that contains an ampoule with mercury(I) nitrate solution in concentrated sulfuric acid. The presence of adamsite manifests itself by a characteristic green product of unknown composition. A detection tube based on this principle has been introduced in the Czechoslovak Army (labeled by two white stripes) and even today a similar device is offered by the As N
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Russian Krismas company under specification IT- 15-30 [5]. Recently, a tube for detection of adamsite (and CR) has been described in the literature that contains silica gel impregnated with 4-chloro-5,7- dinitrobenzofurazane [6]. Another suitable reaction is based on formation of red sodium salt of the nitration product. Adamsite is first nitrated with concentrated nitric acid and the formed nitro derivative is then treated with concentrated solution of sodium hydroxide to give the red sodium salt [7]. This reaction has also been utilized for colorimetric determination of adamsite at 530 nm [8] but its use in a detection tube has not been described. Of less used reactions, one may mention the reaction of adamsite with HI under formation of diphenylamine which is separated by distillation and proved e.g. by blue coloration on reaction with nitrates in concentrated sulfuric acid [9]. The aim of the present study is to describe the preparation, properties and use of two types of detection tubes for detection of adamsite in air, based on electrophilic or nucleophilic substitution reactions affording colorimetrically (visually) evaluated colored products.
The indicator packings and detection solutions were prepared using the following chemicals: ammonium thiocyanate, sodium nitrite, hydrochloric acid 35% (all p.a., Sigma – Aldrich), and anhydrous ethanol (Riedel-de Haën). The detection solution for the reference tubes was prepared with mercury(I) nitrate and 96% sulfuric acid (p.a., Sigma-Aldrich). The employed silica gel (Grace, Germany), had particle size 0.5-0.7 mm, specific surface 200 m 2 .g
and 120 % sorption capacity (H 2 O). The coating tubes, sealing elements and other mechanical components were furnished by the Tejas company (Jablonec, Czech Republic). The detector tubes were tested using 10-chloro- 5,10-dihydrophenarsazine (NBC Defence Institute, University of Defence, Brno) of 96.3 % purity, as checked by classical iodometric method [8].
Preparation of detection tubes with sodium nitrite The detector tube contained an indication packing (layer) and a glass ampoule with detection solution. The indication layer consisted of silica gel which had been purified by boiling with dilute hydrochloric acid, washing with distilled water until the washings
heating at 130 °C. The purified silica gel (100 g) was impregnated with 110 ml of 1% aqueous solution of sodium nitrite. The mixture was dried, first on air until the material became loose and then in a drying box at 90 to 110 °C for 2 hours.
The thus-obtained milky white indication packing was poured into a glass tube to form 10 mm high layer and fixed by polyethylene starlets and a polyamide net. Finally, a glass ampoule containing 20% hydrochloric acid was inserted and the tube was hermetically flame-sealed. Detector tubes construction – see Figure 1.
Fig. 1 Construction of detector tubes Preparation of detection tubes with thiocyanates The detector tube contained a carrier and a glass ampoule with detection solution. Activated purified silica gel was employed as the carrier; the detection solution consisted of 5% ammonium thiocyanate solution in ethanol. Other construction elements were the same as described for detector based on sodium nitrite.
The reference detector tube contained a carrier and a glass ampoule with detection solution. Activated purified silica gel was employed as the carrier; the detection solution consisted of 0.1% solution of mercury(I) nitrate in concentrated sulfuric acid. The remaining construction elements were the same as described for the newly devised detectors.
The detector tube was opened by breaking both sealed ends of the glass body and 20 µl of an acetone solution of adamsite of concentration 5, 25, 50, 150, 250, 500 and 1500 µg.ml -1
was applied on the indication layer using a micropipette. Then, 1 dm 3 of
uncontaminated air was pumped through the layer using a manual air pump Universal 86 (Kavalier Votice, Czech Republic). The ampoule was crushed with a metal spike and the detection solution was thoroughly shaken down onto the carrier. The change in coloration of the indication layer (carrier) was evaluated visually.
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3. RESULTS AND DISCUSSION
In the search for suitable color reactions of compounds structurally close to adamsite we made use of the known fact that polyvinylcarbazole [10] or indole [11] in an acidic medium afford deeply colored nitroso products on reaction with nitrite ions. A similar reaction also takes place with adamsite. The devised detector tube is based on formation of an orange to red colored product, probably a nitroso or isonitroso derivative, formed in an electrophilic substitution reaction of adamsite with nitrous acid arising by treatment of sodium nitrite with hydrochloric acid:
Some irritants of the group of aromatic arsenic compounds (eg diphenylchlorarsane) react with sodium thiocyanate under formation of colored substances [12]. With the mentioned nucleophilic reagent, adamsite affords a yellow product, probably phenarsazine thiocyanate. The probable reaction course may be represented by the following reaction scheme:
Both the devised substitution reactions take place in the detector tubes within wide range of reaction conditions. In the case of the nitrosation reaction that takes place in the presence of acids, the ampoule with 20% hydrochloric acid ensures sufficient stability of the reaction medium. The reaction of adamsite with thiocyanates requires no special adjustment of reaction conditions. The high rate of both the substitution reaction types makes it possible to practically immediately evaluate the color change
of indication layers in the detection tube. The arising coloration is stable. The detection limit for the sodium nitrite method amounts to 0.5 µg of adamsite, for the ammonium thiocyanate method it is 5 µg. The results obtained (Tab. 2) can be interpreted so that for taking 1 dm 3
ideal trapping on the carrier, the detection limit for adamsite aerosol will reach 0.5 mg.m -3
5 mg.m -3
for the respective methods. In the reference tube, silica gel instead of glass wool was employed as the carrier to ensure comparable reaction conditions.
Tab. 2 Results of tests with detector tubes for detection of adamsite Coloration of detector DM (µg) NaNO 2 NH 4 SCN Reference 0.1 no
no light
orange 0.5
light yellow no orange 1 yellow no
yellow-green 3 yellow no brow-green 5 deep yellow light yellow green-brown 10 orange yellow
deep
green 30
deep orange deep yellow deep green
This change results in variable coloration of the indication packing. As detection limit for the reference tube we may regard 1 µg of adamsite which gives rise to still perceivable green coloration. The orange coloration at lower concentrations has to be ascribed to the action of concentrated sulfuric acid alone. The course and results of the tests are not influenced by harmful substances, commonly present in the atmosphere. The sodium nitrite detector tube may exhibit a color response in the presence of some aromatic amines or hydroxy compounds. Thus, e.g., with phenol it shows a red coloration as the result of the Liebermann reaction [13]. Substitution reactions similar to those of adamsite are not known for any of the known warfare agents (except for diphenylchlorarsane) or other compound of military significance. All the devised reagents, used as detection solutions or immobilized on a carrier, are stable. This makes possible a production of detector tubes of long lifetime and usability.
The proposed detector tubes are suitable primarly for chemical detector CHP-71, which belongs to standard equipment of the combined and special chemical units of Czech and Slovak military. The detector tubes can also be used in new semi- As N H Cl NaNO 2 + + HCl As N H Cl As N Cl NO NaCl + + H 2 O N OH Expert papers Science & Military 1/2007
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automatic chemical detector CHP-5, which recently became a part of standard equipment of the Czech military.
References
[1] STŘEDA, L., HALÁMEK, E., KOBLIHA, Z.: Bojové chemické látky. 1. vyd. Praha: Státní úřad pro jadernou bezpečnost, 2004, s. 84. ISBN 80-239-3102-4. [2] On the street. ASA Newsletter, 2003, vol. 96, p. 15.
[3] Zjišťování látek otravných. Praha: Správa civil-
ní obrany, 1954, s. 39, 62. [4] PITSCHMANN, V., HALÁMEK, E.,
TUŠAROVÁ, I., KOBLIHA, Z.: Oritest, Pra- ha. Činidlo pro testování alkaloidů. CZ 15428
U1. Int. Cl. G 01 N 21/78. 2005. [5] ZOLOTOV, YU. A., IVANOV, V. M., AMELIN, V. G.: Chemical Test Methods of Analysis. 1-st ed. Amsterdam: Elsevier, 2002, pp. 248, 268. ISBN: 0-444-50261-0. [6] EVGEN´EV, M. I., GARMONOV, S. YU., BELOV,
P. E., TSEKHMISTER, V .I., DRUZHININ, A. .A: Test Method for the Determination of Toxic Irritants in Air. J. Anal.
Chem., 2003, vol. 58, p. 485. [7] FRANKE, S.: Lehrbuch der Militärchemie. Band 2. 2. Auflage. Berlin: Militärverlag der DDR, 1977, s. 344. [8] FRANKE, S.: Lehrbuch der Militärchemie. Band 2. 2. Auflage. Berlin: Militärverlag der DDR, 1977, s. 349. [9] TOMEČEK, I., MATOUŠEK, J.: Analýza
bojových otravných látek. 1. vyd. Praha: SNP, 1961, s. 99. [10]
ABE, S.: The color reaction of polyvinyl- carbazole with nitrogen dioxide and its application for the detection of nitrogen dioxide. Chem. Lett., 1977, pp. 237-240. [11] ANDONOVSKI, B. S., STOJKOVIČ, G. M.: Spectrophotometry study of the reaction of indole with nitrite ions in hydrochloric acid. Bulletin of the Chemists and Technologists of
Macedonia, 2002, vol. 21, pp. 177-185. [12] SARTORI, M.: Die Chemie der Kampfstoffe. Braunschweig: Friedr. Vieweg & Sohn, 1935, s. 220. [13]
FRAENKL, M., SVOBODOVÁ, D., GASPARIČ, J.: A critical investigation of the Liebermann colour test. Microchim. Acta, 1986, vol. 90, pp. 367-386.
doc. Ing. Vladimír PITSCHMANN, CSc. 1)
prof. Ing. Emil HALÁMEK, CSc. 2)
prof. Ing. Zbyněk KOBLIHA, CSc. 2)
1) Oritest spol. s r.o. Staropramenní 17 150 00 Praha Česká republika E-mail: pitschmann@oritest.cz 2) Univerzita obrany Brno Ústav OPZHN Sídliště Víta Nejedlého 682 03 Vyškov Česká republika E-mail: emil.halamek@unob.cz zbynek.kobliha@unob.cz
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