| Record Information |
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| Version | 1.0 |
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| Creation Date | 2016-07-13 19:54:27 UTC |
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| Update Date | 2018-04-30 21:14:58 UTC |
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| Lmdb | LMDB00641 |
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| Secondary Accession Numbers | None |
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| Metabolite Identification |
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| Common Name | Thallium |
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| Description | A mercury-thallium alloy, which forms a eutectic at 8.5% thallium, is reported to freeze at -60 C, some 20 ∞C below the freezing point of mercury. This alloy is used in thermometers and low-temperature switches. In organic synthesis thallium(III) salts, as thallium trinitrate or triacetate, are useful reagents performing different transformations in aromatics, ketones, olefins, among others. Thallium is a constituent of the alloy in the anode plates in magnesium seawater batteries. Soluble thallium salts are added to gold plating baths to increase the speed of plating and to reduce grain size within the gold layer. A thallium stress test is a form of scintigraphy, where the amount of thallium in tissues correlates with tissue blood supply. Viable cardiac cells have normal Na+/K+ ion exchange pumps. The Tl+ cation binds the K+ pumps and is transported into the cells. Exercise or dipyridamole induces widening (vasodilation) of normal coronary arteries. This produces coronary steal from areas where arteries are maximally dilated. Areas of infarct or ischemic tissue will remain "cold". Pre- and post-stress thallium may indicate areas which will benefit from myocardial revascularization. Redistribution indicates the existence of coronary steal and the presence of ischemic coronary artery disease. Although thallium is a modestly abundant element in the Earth's crust, with a concentration estimated to be about 0.7 mg/kg, mostly in association with potassium-based minerals in clays, soils, and granites, thallium is not generally economically recoverable from these sources. The major source of thallium for practical purposes is the trace amount that is found in copper, lead, zinc, and other heavy-metal-sulfide ores. One of the main methods of removing thallium (both radioactive and normal) from animals is to use Prussian blue, which is a material which absorbs thallium. Up to 20 g per day of Prussian blue is fed by mouth to the person, and it passes through their digestive system and comes out in the stool. Hemodialysis and hemoperfusion are also used to remove thallium from the blood serum. At later stage of the treatment additional potassium is used to mobilize thallium from the tissue. Thallium is a chemical element with the symbol Tl and atomic number 81. This soft gray poor metal resembles tin but discolors when exposed to air. Chemists William Crookes and Claude-Auguste Lamy discovered thallium independently in 1861 by the newly developed method of flame spectroscopy. Each discovered the new element in residues of sulfuric acid production. Thallium and its compounds are extremely toxic, and should be handled with great care. There are numerous recorded cases of fatal thallium poisoning. Contact with skin is dangerous, and adequate ventilation should be provided when melting this metal. Thallium(I) compounds have a high aqueous solubility and are readily absorbed through the skin. Exposure to them should not exceed 0.1 mg per m2 of skin in an 8-hour time-weighted average (40-hour work week). Thallium is a suspected animal carcinogen. For a long time thallium compounds were easily available as rat poison. This fact and that it is water soluble and nearly tasteless led to frequent intoxications caused by accident or criminal intent. Thallium can also be obtained from the smelting of lead and zinc ores. Manganese nodules found on the ocean floor also contain some thallium, but the collection of these nodules has been and continues to be prohibitively expensive. There is also the potential for damaging the environment of the oceans. In addition, several other thallium minerals, containing 16% to 60% thallium, occur in nature as complexes of sulfides or selenides that primarily contain antimony, arsenic, copper, lead, and/or silver. However, these minerals are rare, and they have had no commercial importance as sources of thallium. The Allchar deposit in southern Macedonia was the only area where thallium was ever actively mined. This deposit still contains a loosely estimated 500 tonnes of thallium, and it is a source for several rare thallium minerals, for example lorandite. The compounds with oxidation state +3 resemble the corresponding aluminium(III) compounds. They are moderately strong oxidizing agents, as illustrated by the reduction potential of +0.72 volts for Tl3+. The thallium(III) oxide is a black solid which decomposes above 800 ∞C, forming the thallium(I) oxide and oxygen. The saturated solution of equal parts of thallium(I) formate (Tl(CHO2)) and thallium(I) malonate (Tl(C3H3O4)) in water is known as Clerici solution. It is a mobile odorless liquid whose color changes from yellowish to clear upon reducing the concentration of the thallium salts. With the density of 4.25 g/cm3 at 20 ∞C, Clerici solution is one of the heaviest aqueous solutions known. It was used in the 20th century for measuring density of minerals by the flotation method, but the use is discontinued due to the high toxicity and corrosiveness of the solution. The two main oxidation states of thallium are +1 and +3. In the oxidation state +1 most compounds closely resemble the corresponding potassium or silver compounds (the ionic radius of thallium(I) is 1.47 while that of potassium is 1.33 and that of silver is 1.26),[citation needed] which was the reason why thallium was sometimes considered to be an alkali metal in Europe (but not in England) in the years immediately following its discovery.:126 For example, the water-soluble and very basic thallium(I) hydroxide reacts with carbon dioxide forming water-soluble thallium carbonate This carbonate is the only water soluble heavy metal carbonate.[citation needed] The similarity with silver compounds is observed with the halide, oxide, and sulfide compounds. Thallium(I) bromide is a photosensitive yellow compound very similar to the silver bromide, while the black thallium(I) oxide and thallium(I) sulfide are very similar to the silver oxide and silver sulfide.[citation needed] |
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| Structure | |
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| Synonyms | | Value | Source |
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| [TLCL] | ChEBI | | Thallium chloride | ChEBI | | Thallous chloride | ChEBI | | TLCL | ChEBI | | 81TL | HMDB | | Talio | HMDB | | Thallous chloride TL 201 | HMDB | | Tl | HMDB | | Thallium chloride, (201)TL-labeled | HMDB | | Thallium chloride, (203)TL,(35)CL-labeled | HMDB | | Thallium chloride, (205)TL,(35)CL-labeled | HMDB | | Thallium monochloride | HMDB | | Thallium chloride, (205)TL,(37)CL-labeled | HMDB | | Thallium chloride, (203)TL,(37)CL-labeled | HMDB |
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| Chemical Formula | ClTl |
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| Average Molecular Weight | 239.83 |
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| Monoisotopic Molecular Weight | 239.943281 |
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| IUPAC Name | chlorothallane |
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| Traditional Name | thallous chloride |
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| CAS Registry Number | 7440-28-0 |
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| SMILES | Cl[Tl] |
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| InChI Identifier | InChI=1S/ClH.Tl/h1H;/q;+1/p-1 |
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| InChI Key | GBECUEIQVRDUKB-UHFFFAOYSA-M |
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| Chemical Taxonomy |
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| Description | belongs to the class of inorganic compounds known as post-transition metal chlorides. These are inorganic compounds in which the largest halogen atom is Chlorine, and the heaviest metal atom is a post-transition metal. |
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| Kingdom | Inorganic compounds |
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| Super Class | Mixed metal/non-metal compounds |
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| Class | Post-transition metal salts |
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| Sub Class | Post-transition metal chlorides |
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| Direct Parent | Post-transition metal chlorides |
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| Alternative Parents | |
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| Substituents | - Post-transition metal chloride
- Inorganic chloride salt
- Inorganic salt
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| Molecular Framework | Not Available |
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| External Descriptors | |
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| Ontology |
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| Status | Detected and Quantified |
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| Origin | Not Available |
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| Biofunction | Not Available |
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| Application | Not Available |
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| Cellular locations | Not Available |
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| Physical Properties |
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| State | Not Available |
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| Experimental Properties | | Property | Value | Reference |
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| Melting Point | Not Available | Not Available | | Boiling Point | Not Available | Not Available | | Water Solubility | Not Available | Not Available | | LogP | Not Available | Not Available |
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| Predicted Properties | |
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| Spectra |
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| Spectra | | Spectrum Type | Description | Splash Key | View |
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| Predicted GC-MS | Predicted GC-MS Spectrum - GC-MS (Non-derivatized) - 70eV, Positive | splash10-000i-0090000000-9137aecf784ddee36f62 | Spectrum | | Predicted GC-MS | Predicted GC-MS Spectrum - GC-MS (Non-derivatized) - 70eV, Positive | Not Available | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 10V, Negative | splash10-0006-0090000000-16a4cb30e5946cdb2eda | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 20V, Negative | splash10-0006-0090000000-16a4cb30e5946cdb2eda | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 40V, Negative | splash10-0006-0090000000-16a4cb30e5946cdb2eda | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 10V, Positive | splash10-0006-0090000000-89708d5af246693b1621 | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 20V, Positive | splash10-0006-0090000000-89708d5af246693b1621 | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 40V, Positive | splash10-0006-0090000000-89708d5af246693b1621 | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 10V, Positive | splash10-0006-0090000000-7f59adc064ffa4550e4a | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 20V, Positive | splash10-0006-0090000000-7f59adc064ffa4550e4a | Spectrum | | Predicted LC-MS/MS | Predicted LC-MS/MS Spectrum - 40V, Positive | splash10-0006-0090000000-7f59adc064ffa4550e4a | Spectrum |
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