Potassium perchlorate is the inorganic salt with the chemical formula KClO4. Like other perchlorates, this salt is a strong oxidizer when the solid is heated at high temperature although it usually reacts very slowly in solution with reducing agents or organic substances. This colorless crystalline solid is a common oxidizer used in fireworks, ammunition percussion caps, explosive primers, and is used variously in propellants, flash compositions, stars, and sparklers. It has been used as a solid rocket propellant, although in that application it has mostly been replaced by the more performant ammonium perchlorate.

Potassium perchlorate
Names
Other names
Potassium chlorate(VII); Perchloric acid, potassium salt; peroidin
Identifiers
3D model (JSmol)
ChEMBL
ChemSpider
ECHA InfoCard 100.029.011 Edit this at Wikidata
EC Number
  • 231-912-9
RTECS number
  • SC9700000
UNII
UN number 1489
  • InChI=1S/ClHO4.K/c2-1(3,4)5;/h(H,2,3,4,5);/q;+1/p-1 checkY
    Key: YLMGFJXSLBMXHK-UHFFFAOYSA-M checkY
  • InChI=1/ClHO4.K/c2-1(3,4)5;/h(H,2,3,4,5);/q;+1/p-1
    Key: YLMGFJXSLBMXHK-REWHXWOFAB
  • [K+].[O-]Cl(=O)(=O)=O
Properties
KClO4
Molar mass 138.55 g/mol
Appearance colourless/ white crystalline powder
Density 2.5239 g/cm3
Melting point 610 °C (1,130 °F; 883 K)
decomposes from 400 °C[4][5]
0.76 g/100 mL (0 °C)
1.5 g/100 mL (25 °C)[1]
4.76 g/100 mL (40 °C)
21.08 g/100 mL (100 °C)[2]
1.05·10−2[3]
Solubility negligible in alcohol
insoluble in ether
Solubility in ethanol 47 mg/kg (0 °C)
120 mg/kg (25 °C)[2]
Solubility in acetone 1.6 g/kg[2]
Solubility in ethyl acetate 15 mg/kg[2]
1.4724
Structure
Rhombohedral
Thermochemistry
111.35 J/mol·K[6]
150.86 J/mol·K[6]
-433 kJ/mol[7]
-300.4 kJ/mol[2]
Hazards
GHS labelling:
GHS03: OxidizingGHS07: Exclamation mark[5]
Danger
H271, H302, H335[5]
P220, P280[5]
NFPA 704 (fire diamond)
Safety data sheet (SDS) MSDS
Related compounds
Other anions
Potassium chloride
Potassium chlorate
Potassium periodate
Other cations
Ammonium perchlorate
Sodium perchlorate
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
☒N verify (what is checkY☒N ?)

KClO4 has a relatively low solubility in water (1.5 g in 100 mL of water at 25 °C).[1]

Production

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Potassium perchlorate in crystal form

Potassium perchlorate is prepared industrially by treating an aqueous solution of sodium perchlorate with potassium chloride. This single precipitation reaction exploits the low solubility of KClO4, which is about 1/100 as much as the solubility of NaClO4 (209.6 g/100 mL at 25 °C).[8]

It can also be produced by bubbling chlorine gas through a solution of potassium chlorate and potassium hydroxide,[citation needed] and by the reaction of perchloric acid with potassium hydroxide; however, this is not used widely due to the dangers of perchloric acid.

Another preparation involves the electrolysis of a potassium chlorate solution, causing KClO4 to form and precipitate at the anode. This procedure is complicated by the low solubility of both potassium chlorate and potassium perchlorate, the latter of which may precipitate onto the electrodes and impede the current.

Oxidizing properties

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KClO4 is an oxidizer in the sense that it exothermically "transfers oxygen" to combustible materials, greatly increasing their rate of combustion relative to that in air. Thus, it reacts with glucose to give carbon dioxide, water molecules and potassium chloride:

3 KClO4 + C6H12O6 → 6 CO2 + 6 H2O + 3 KCl

The conversion of solid glucose into hot gaseous CO2 is the basis of the explosive force of this and other such mixtures. With sugar, KClO4 yields a low explosive, provided a necessary confinement. Otherwise such mixtures simply deflagrate with an intense purple flame characteristic of potassium. Flash compositions used in firecrackers usually consist of a mixture of aluminium powder and potassium perchlorate. This mixture, sometimes called flash powder, is also used in ground and air fireworks.

As an oxidizer, potassium perchlorate can be used safely in the presence of sulfur, whereas potassium chlorate cannot. The greater reactivity of chlorate is typical – perchlorates are kinetically poorer oxidants. Chlorate produces chloric acid (HClO3), which is highly unstable and can lead to premature ignition of the composition. Correspondingly, perchloric acid (HClO4) is quite stable.[9]

For a commercial use, potassium perchlorate is mixed 50/50 with potassium nitrate to fabricate Pyrodex, a black powder substitute, and when not compressed within a muzzle loading firearm or in a cartridge, burns at a sufficiently slow rate to prevent it from being categorized with the black powder as a "low explosive", and to demote it as "flammable" material.

Debated medical use

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Potassium perchlorate can be used as an antithyroid agent used to treat hyperthyroidism, usually in combination with one other medication. This application exploits the similar ionic radius and hydrophilicity of perchlorate and iodide.

The administration of known goitrogen substances can also be used as a prevention in reducing the biological uptake of iodine, (whether it is the nutritional non-radioactive iodine-127 or radioactive iodine, most commonly iodine-131 (half-life = 8.02 days), as the body cannot discern between different iodine isotopes). Perchlorate ions, a common water contaminant in the USA due to the aerospace industry, has been shown to reduce iodine uptake and thus is classified as a goitrogen. Perchlorate ion is a competitive inhibitor of the process by which iodide is actively accumulated into the thyroid follicular cells. Studies involving healthy adult volunteers determined that at levels above 7 micrograms per kilogram per day (μg/(kg·d)), perchlorate begins to temporarily inhibit the thyroid gland's ability to absorb iodine from the bloodstream ("iodide uptake inhibition", thus perchlorate is a known goitrogen).[10] The reduction of the iodide pool by perchlorate has a dual effect – reduction of excess hormone synthesis and hyperthyroidism, on the one hand, and reduction of thyroid inhibitor synthesis and hypothyroidism on the other. Perchlorate remains very useful as a single dose application in tests measuring the discharge of radioiodide accumulated in the thyroid as a result of many different disruptions in the further metabolism of iodide in the thyroid gland.[11]

Treatment of thyrotoxicosis (including Graves' disease) with 600-2,000 mg potassium perchlorate (430-1,400 mg perchlorate) daily for periods of several months, or longer, was once a common practice, particularly in Europe,[10][12] and perchlorate use at lower doses to treat thyroid problems continues to this day.[13] Although 400 mg of potassium perchlorate divided into four or five daily doses was used initially and found effective, higher doses were introduced when 400 mg/d was discovered not to control thyrotoxicosis in all subjects.[10][11]

Current regimens for treatment of thyrotoxicosis (including Graves' disease), when a patient is exposed to additional sources of iodine, commonly include 500 mg potassium perchlorate twice per day for 18–40 days.[10][14]

Prophylaxis with perchlorate-containing water at concentrations of 17 ppm, corresponding to 0.5 mg/(kg·d) intake for a person of 70 kg consuming 2 litres of water per day, was found to reduce the baseline of radioiodine uptake by 67%[10] This is equivalent to ingesting a total of just 35 mg of perchlorate ions per day. In another related study were subjects drank just 1 litre of perchlorate-containing water per day at a concentration of 10 ppm, i.e. daily 10 mg of perchlorate ions were ingested, an average 38% reduction in the uptake of Iodine was observed.[15]

However, when the average perchlorate absorption in perchlorate plant workers subjected to the highest exposure has been estimated as approximately 0.5 mg/(kg·d), as in the above paragraph, a 67% reduction of iodine uptake would be expected. Studies of chronically exposed workers though have thus far failed to detect any abnormalities of thyroid function, including the uptake of iodine.[16] This may well be attributable to sufficient daily exposure, or intake, of stable iodine-127 among these workers and the short 8 hr biological half life of perchlorate in the body.[10]

To completely block the uptake of iodine-131 (half-life = 8.02 days) by the purposeful addition of perchlorate ions to a public water supply, aiming at dosages of 0.5 mg/(kg·d), or a water concentration of 17 ppm, would therefore be grossly inadequate at truly reducing a radio-iodine uptake. Perchlorate ion concentrations in a region water supply, would need to be much higher, at least 7.15 mg/kg of body weight per day or a water concentration of 250 ppm, assuming people drink 2 liters of water per day, to be truly beneficial to the population at preventing bioaccumulation when exposed to an iodine-131 contamination,[10][14] independent of the availability of iodate or iodide compounds.

The distribution of perchlorate tablets, or the addition of perchlorate to the water supply, would need to continue for 80–90 days (~10 half-life of 8.02 days) after the release of iodine-131. After this time, the radioactive iodine-131 would have decayed to less than 1/1000 of its initial activity at which time the danger from the biological uptake of iodine-131 is essentially over.[17]

Limitations and criticisms

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So, perchlorate administration could represent a possible alternative to iodide tablets distribution in case of a large-scale nuclear accident releasing important quantities of iodine-131 in the atmosphere. However, the advantages are not always clear and would depend on the extent of a hypothetical nuclear accident. As for the stable iodide intake to rapidly saturate the thyroid gland before it accumulates radioactive iodine-131, a careful cost-benefit analysis has to be first done by the nuclear safety authorities. Indeed, blocking the thyroid activity of a whole population for three months can also have negative consequences for the human health, especially for young children.

So, the decision of perchlorate, or stable iodine, administration cannot be left to the individual initiative and falls under the authority of the government in case of a major nuclear accident.

Injecting perchlorate or iodide directly in the public drinking water is also probably as restrictive as tablets distribution.

See also

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References

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  1. ^ a b "Potassium Perchlorate MSDS". J.T. Baker. 2007-02-16. Retrieved 2007-12-10.
  2. ^ a b c d e "potassium perchlorate". chemister.ru. Retrieved 14 April 2018.
  3. ^ "Ksp solubility product constants of many popular salts at SolubilityOFthings".
  4. ^ Benenson, Walter; Stöcker, Horst (13 January 2006). Handbook of Physics. Springer. p. 780. ISBN 978-0387952697.
  5. ^ a b c d Sigma-Aldrich Co., Potassium perchlorate. Retrieved on 2022-02-17.
  6. ^ a b Potassium perchlorate in Linstrom, Peter J.; Mallard, William G. (eds.); NIST Chemistry WebBook, NIST Standard Reference Database Number 69, National Institute of Standards and Technology, Gaithersburg (MD) (retrieved 2014-05-27)
  7. ^ Zumdahl, Steven S. (2009). Chemical Principles 6th Ed. Houghton Mifflin Company. p. A22. ISBN 978-0-618-94690-7.
  8. ^ Helmut Vogt, Jan Balej, John E. Bennett, Peter Wintzer, Saeed Akbar Sheikh, Patrizio Gallone "Chlorine Oxides and Chlorine Oxygen Acids" in Ullmann's Encyclopedia of Industrial Chemistry 2002, Wiley-VCH, Weinheim. doi:10.1002/14356007.a06_483
  9. ^ Greenwood, N. N.; Earnshaw, A. (1997). Chemistry of the Elements (2nd Edn.), Oxford:Butterworth-Heinemann. ISBN 0-7506-3365-4.
  10. ^ a b c d e f g Greer, Monte A.; Goodman, Gay; Pleus, Richard C.; Greer, Susan E. (2002). "Health Effects Assessment for Environmental Perchlorate Contamination: The Dose Response for Inhibition of Thyroidal Radioiodine Uptake in Humans". Environmental Health Perspectives. 110 (9): 927–37. doi:10.1289/ehp.02110927. PMC 1240994. PMID 12204829.
  11. ^ a b Wolff, J (1998). "Perchlorate and the thyroid gland". Pharmacological Reviews. 50 (1): 89–105. PMID 9549759.
  12. ^ Barzilai, D; Sheinfeld, M (1966). "Fatal complications following use of potassium perchlorate in thyrotoxicosis. Report of two cases and a review of the literature". Israel Journal of Medical Sciences. 2 (4): 453–6. PMID 4290684.
  13. ^ Woenckhaus, U.; Girlich, C. (2005). "Therapie und Prävention der Hyperthyreose" [Therapy and prevention of hyperthyroidism]. Der Internist (in German). 46 (12): 1318–23. doi:10.1007/s00108-005-1508-4. PMID 16231171.
  14. ^ a b Bartalena, L.; Brogioni, S; Grasso, L; Bogazzi, F; Burelli, A; Martino, E (1996). "Treatment of amiodarone-induced thyrotoxicosis, a difficult challenge: Results of a prospective study". Journal of Clinical Endocrinology & Metabolism. 81 (8): 2930–3. doi:10.1210/jcem.81.8.8768854. PMID 8768854.
  15. ^ Lawrence, J. E.; Lamm, S. H.; Pino, S.; Richman, K.; Braverman, L. E. (2000). "The Effect of Short-Term Low-Dose Perchlorate on Various Aspects of Thyroid Function". Thyroid. 10 (8): 659–63. doi:10.1089/10507250050137734. PMID 11014310.
  16. ^ Lamm, Steven H.; Braverman, Lewis E.; Li, Feng Xiao; Richman, Kent; Pino, Sam; Howearth, Gregory (1999). "Thyroid Health Status of Ammonium Perchlorate Workers: A Cross-Sectional Occupational Health Study". Journal of Occupational & Environmental Medicine. 41 (4): 248–60. doi:10.1097/00043764-199904000-00006. PMID 10224590.
  17. ^ "Nuclear Chemistry: Half-Lives and Radioactive Dating - For Dummies". Dummies.com. 2010-01-06. Retrieved 2013-01-21.
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