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Potasa (K), kemikal na elemento ng Pangkat 1 (Ia) ng pana-panahong talahanayan, ang grupo ng metal na alkali, kailangang-kailangan para sa parehong halaman at buhay ng hayop. Ang potasa ay ang unang metal na nakahiwalay ng electrolysis, ng chemist ng Ingles na si Sir Humphry Davy, nang makuha niya ang elemento (1807) sa pamamagitan ng pag-decompose ng tinunaw na potassium hydroxide (KOH) na may isang baterya ng voltaic.
Mga Katangian ng Elemento
| numero ng atomic | 19 |
|---|---|
| konting bigat | 39.098 |
| temperatura ng pagkatunaw | 63.28 ° C (145.90 ° F) |
| punto ng pag-kulo | 760 ° C (1,400 ° F) |
| tiyak na gravity | 0.862 (sa 20 ° C, o 68 ° F) |
| estado ng oksihenasyon | +1, −1 (bihira) |
| pagsasaayos ng elektron | 2-8-8-1 o 1s 2 2s 2 2p 6 3s 2 3p 6 4s 1 |
Mga katangian, pangyayari, at paggamit
Ang potasa metal ay malambot at puti na may isang kulay-pilak na ningning, ay may mababang punto ng pagkatunaw, at isang mahusay na conductor ng init at kuryente. Ang potasa ay nagbibigay ng kulay ng lavender sa isang siga, at berde ang singaw nito. Ito ang ikapitong pinaka masaganang elemento sa crust ng Earth, na bumubuo ng 2.6 porsyento ng masa nito.
Ang potasa ng potasa ng Patay na Dagat ay tinatayang humigit-kumulang na 1.7 porsiyento na potassium chloride, at maraming iba pang mga maalat na katawan ng tubig ay mayaman sa potasa. Ang mga basurang likido mula sa ilang mga gawaing asin ay maaaring maglaman ng hanggang sa 40 gramo bawat litro ng potassium chloride at ginagamit bilang isang mapagkukunan ng potasa.
Most potassium is present in igneous rocks, shale, and sediment in minerals such as muscovite and orthoclase feldspar that are insoluble in water; this makes potassium difficult to obtain. As a result, most commercial potassium compounds (often loosely called potash) are obtained via electrolysis from soluble potassium compounds, such as carnallite (KMgCl3∙6H2O), sylvite (potassium chloride, KCl), polyhalite (K2Ca2Mg[SO4]4∙2H2O), and langbeinite (K2Mg2[SO4]3), which are found in ancient lake beds and seabeds.
Potassium is produced by sodium reduction of molten potassium chloride, KCl, at 870 °C (1,600 °F). Molten KCl is continuously fed into a packed distillation column while sodium vapour is passed up through the column. By condensation of the more volatile potassium at the top of the distillation tower, the reaction Na + KCl → K + NaCl is forced to the right. Efforts to devise a scheme for commercial electrolytic production of potassium have been unsuccessful because there are few salt additives that can reduce the melting point of potassium chloride to temperatures where electrolysis is efficient.
There is little commercial demand for potassium metal itself, and most of it is converted by direct combustion in dry air to potassium superoxide, KO2, which is used in respiratory equipment because it liberates oxygen and removes carbon dioxide and water vapour. (The superoxide of potassium is a yellow solid consisting of K+and O2− ions. It also can be formed by oxidation of potassium amalgam with dry air or oxygen.) The metal is also used as an alloy with sodium as a liquid metallic heat-transfer medium. Potassium reacts very vigorously with water, liberating hydrogen (which ignites) and forming a solution of potassium hydroxide, KOH.
Sodium-potassium alloy (NaK) is used to a limited extent as a heat-transfer coolant in some fast-breeder nuclear reactors and experimentally in gas-turbine power plants. The alloy is also used as a catalyst or reducing agent in organic synthesis.
In addition to the alloys of potassium with lithium and sodium, alloys with other alkali metals are known. Complete miscibility exists in the potassium-rubidium and potassium-cesium binary systems. The latter system forms an alloy melting at approximately −38 °C (−36 °F). Modification of the system by the addition of sodium results in a ternary eutectic melting at approximately −78 °C (−108 °F). The composition of this alloy is 3 percent sodium, 24 percent potassium, and 73 percent cesium. Potassium is essentially immiscible with all the alkaline-earth metals, as well as with zinc, aluminum, and cadmium.
Potassium (as K+) is required by all plants and animals. Plants need it for photosynthesis, regulation of osmosis and growth, and enzyme activation. Every animal has a closely maintained potassium level and a relatively fixed potassium-sodium ratio. Potassium is the primary inorganic cation within the living cell, and sodium is the most abundant cation in extracellular fluids. In higher animals, selective complexants for Na+ and K+ act at cell membranes to provide “active transport.” This active transport transmits electrochemical impulses in nerve and muscle fibres and in balancing the activity of nutrient intake and waste removal from cells. Too little or too much potassium in the body is fatal; however, potassium in the soil ensures the presence of this indispensable element in food.
The potassium content of plants varies considerably, though it is ordinarily in the range of 0.5–2 percent of the dry weight. In humans the ratio of potassium between the cell and plasma is approximately 27:1. The potassium content of muscle tissue is approximately 0.3 percent, whereas that of blood serum is about 0.01–0.02 percent. The dietary requirement for normal growth is approximately 3.3 grams (0.12 ounce) of potassium per day, but the ingestion of more than 20 grams (0.7 ounce) of potassium results in distinct physiological effects. Excess potassium is excreted in the urine, and a significant quantity may be lost during sweating.
Natural potassium consists of three isotopes: potassium-39 (93.26 percent), potassium-41 (6.73 percent), and radioactive potassium-40 (about 0.01 percent); several artificial isotopes have also been prepared. Potassium-39 is normally about 13.5 times more plentiful than potassium-41. The natural radioactivity of potassium is due to beta radiation from the potassium-40 isotope (109 years half-life). The disintegration of potassium-40 is used in geological age calculations (see potassium-argon dating). Potassium easily loses the single 4s electron, so it normally has an oxidation state of +1 in its compounds, although compounds that contain the anion, K−, can also be made.
