| Parisite | |
|---|---|
 Parisite from Muzo, Vasquez-Yacopí Mining District, Boyacá Department, Colombia, size: 1.3 x 1 x .7 cm | |
| General | |
| Category | Carbonate |
| Formula (repeating unit) | Ca(Ce,La)2(CO3)3F2 |
| IMA symbol | Pst[1] |
| Strunz classification | 5.BD.20b |
| Dana classification | 16a.01.05.01 |
| Crystal system | Monoclinic |
| Crystal class | Domatic (m) (same H-M symbol) |
| Space group | Cc |
| Unit cell | a = 12.305 Å, b = 7.1056 Å, c = 28.2478 Å; β = 98.246°; Z = 12 |
| Identification | |
| Formula mass | 537.24 g/mol |
| Color | Brown, brownish yellow, gray-yellow, grayish yellow, yellow, waxy yellow, colourless to yellow in transmitted light |
| Crystal habit | Acicular |
| Mohs scale hardness | 4+1⁄2 |
| Luster | Vitreous - greasy |
| Streak | White |
| Diaphaneity | Transparent to translucent |
| Specific gravity | 4.34 |
| Density | 4.38 |
| References | [2][3][4] |
Parisite is a rare mineral consisting of cerium, lanthanum and calcium fluoro-carbonate, Ca(Ce,La)2(CO3)3F2. Parisite is mostly parisite-(Ce), but when neodymium is present in the structure the mineral becomes parisite-(Nd).
It is found only as crystals, which belong to the trigonal or monoclinic pseudo-hexagonal system and usually have the form of acute double pyramids terminated by the basal planes; the faces of the hexagonal pyramids are striated horizontally, and parallel to the basal plane there is a perfect cleavage. The crystals are hair-brown in color and are translucent. The hardness is 4.5 and the specific gravity is 4.36. Light which has traversed a crystal of parisite exhibits a characteristic absorption spectrum.
At first, the only known occurrence of this mineral was in the famous emerald mine at Muzo in Colombia, South America, where it was found by J.J. Paris, who rediscovered and worked the mine in the early part of the 19th century; here it is associated with emerald in a bituminous limestone of Cretaceous age.
Closely allied to parisite, and indeed first described as such, is a mineral from the nepheline-syenite district of Julianehaab in south Greenland. To this the name synchysite has been given. The crystals are rhombohedral (as distinct from hexagonal; they have the composition CeFCa(CO3)2, and specific gravity of 2.90. At the same locality there is also found a barium-parisite, which differs from the Colombian parisite in containing barium in place of calcium, the formula being (CeF)2Ba(CO3)3: this is named cordylite on account of the club-shaped form of its hexagonal crystals. Bastnasite is a cerium lanthanum and neodymium fluoro-carbonate (CeF)CO3, from Bastnas, near Riddarhyttan, in Vestmanland, Sweden, and the Pikes Peak region in Colorado, United States.
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How parasites change their host's behavior - Jaap de Roode
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The Most Gruesome Parasites – Neglected Tropical Diseases – NTDs
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À CAUSE D'UNE DÉMANGEAISON INTENSE DANS LE NEZ, ELLE VA À L'HÔPITAL ET FAIT UNE DÉCOUVERTE HORRIBLE
Transcription
Which of these entities has evolved the ability to manipulate an animal many times its size? The answer is all of them. These are all parasites, organisms that live on or inside another host organism, which they harm and sometimes even kill. Parasite survival depends on transmitting from one host to the next, sometimes through an intermediate species. Our parasites elegantly achieve this by manipulating their host's behavior, sometimes through direct brain hijacking. For example, this is the Gordian worm. One of its hosts, this cricket. The Gordian worm needs water to mate, but the cricket prefers dry land. So once it's big enough to reproduce, the worm produces proteins that garble the cricket's navigational system. The confused cricket jumps around erratically, moves closer to water, and eventually leaps in, often drowning in the process. The worm then wriggles out to mate and its eggs get eaten by little water insects that mature, colonize land, and are, in turn, eaten by new crickets. And thus, the Gordian worm lives on. And here's the rabies virus, another mind-altering parasite. This virus infects mammals, often dogs, and travels up the animal's nerves to its brain where it causes inflammation that eventually kills the host. But before it does, it often increases its host's aggressiveness and ramps up the production of rabies-transmitting saliva, while making it hard to swallow. These factors make the host more likely to bite another animal and more likely to pass the virus on when it does. And now, meet Ophiocordyceps, also known as the zombie fungus. Its host of choice is tropical ants that normally live in treetops. After Ophiocordyceps spores pierce the ant's exoskeleton, they set off convulsions that make the ant fall from the tree. The fungus changes the ant's behavior, compelling it to wander mindlessly until it stumbles onto a plant leaf with the perfect fungal breeding conditions, which it latches onto. The ant then dies, and the fungus parasitizes its body to build a tall, thin stalk from its neck. Within several weeks, the stalk shoots off spores, which turn more ants into six-legged leaf-seeking zombies. One of humanity's most deadly assailants is a behavior-altering parasite, though if it's any consolation, it's not our brains that are being hijacked. I'm talking about Plasmodium, which causes malaria. This parasite needs mosquitoes to shuttle it between hosts, so it makes them bite more frequently and for longer. There's also evidence that humans infected with malaria are more attractive to mosquitoes, which will bite them and transfer the parasite further. This multi-species system is so effective, that there are hundreds of millions of malaria cases every year. And finally, there are cats. Don't worry, there probably aren't any cats living in your body and controlling your thoughts. I mean, probably. But there is a microorganism called Toxoplasma that needs both cats and rodents to complete its life cycle. When a rat gets infected by eating cat feces, the parasite changes chemical levels in the rat's brain, making it less cautious around the hungry felines, maybe even attracted to them. This makes them easy prey, so these infected rodents get eaten and pass the parasite on. Mind control successful. There's even evidence that the parasite affects human behavior. In most cases, we don't completely understand how these parasites manage their feats of behavior modification. But from what we do know, we can tell that they have a pretty diverse toolbox. Gordian worms seem to affect crickets' brains directly. The malaria parasite, on the other hand, blocks an enzyme that helps the mosquitoes feed, forcing them to bite over and over and over again. The rabies virus may cause that snarling, slobbering behavior by putting the immune system into overdrive. But whatever the method, when you think about how effectively these parasites control the behavior of their hosts, you may wonder how much of human behavior is actually parasites doing the talking. Since more than half of the species on Earth are parasites, it could be more than we think.
References
- ^ Warr, L.N. (2021). "IMA–CNMNC approved mineral symbols". Mineralogical Magazine. 85 (3): 291–320. Bibcode:2021MinM...85..291W. doi:10.1180/mgm.2021.43. S2CID 235729616.
- ^ Mineralienatlas
- ^ "Parisite-(Ce)".
- ^ "Parisite-(Ce) Mineral Data".
External links
- Anthony, John W.; Bideaux, Richard A.; Bladh, Kenneth W.; Nichols, Monte C., eds. (1990–2013). "Parisite-(Ce)" (PDF). Handbook of Mineralogy. Chantilly, VA: Mineralogical Society of America.
This article incorporates text from a publication now in the public domain: Chisholm, Hugh, ed. (1911). "Parisite". Encyclopædia Britannica. Vol. 20 (11th ed.). Cambridge University Press. p. 825.
This page was last edited on 20 February 2023, at 13:16