Libyan Desert Glass Meteorite Tektite HIGH-GRADE Dark Streak US Seller IMCA#RARE for Sale

Libyan Desert Glass Meteorite Tektite HIGH-GRADE Dark Streak US Seller IMCA#RARE For Sale

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Libyan Desert Glass Meteorite Tektite HIGH-GRADE Dark Streak US Seller IMCA#RARE:
$88.88

This specimen weighs 35.60 Carats which is the same as 7.11 grams. It measures 28 mm x 20 mm x 18 mm.

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This is a very nice, and highly translucent and high quality specimen of Libyan Desert Glass. And if you don't know what that is, well then, get ready to be amazed! This is what was formed from an ancient meteorite impact in the middle of the deserts of Egypt. The sand was immediately fused into this beautiful yellow glass! It is highly collectible and more and more rare all the time.

This piece is particularly rare because not only is it super clear with amazing clarity and really high quality and that is already rare in and of itself but also there are these dark streaks and that makes the ABSOLUTELY THE HARDEST TO FIND AND MOST HIGHLY SOUGHT AFTER PIECE BECAUSE OF THESE STREAKS- why!?!? Because just recently it has been rumored and scientists are beginning to believe that these dark streaks are the particles of the ACTUAL phantom meteorite that no one has ever been able to find. We have all agreed that these Libyan desert glass pieces are and were made from a huge gigantic meteorite that struck millions of years ago, but no one has ever found the meteorite or pieces of it. And the best guess is that it evaporated upon impact, and if that is the case- then this is THE ONLY way to ever have a piece of this ancient natural disaster. These pieces with the dark streaks are the rarest and hardest to find and are usually like $20/gram because of that.

It it getting more difficult to find and I was just selling some stuff that I had in an old collection. So I am offering this beautiful piece for you. Times are tough and I am just trying to make some money, and I know it will find a nice home out there somewhere. I hope it finds a good home out there. Don't let this one pass you by. If you have any questions, do not hesitate to ask me. Have fun offerding. Thanks so much for visiting my sale and have a great day!

If you purchase from me you should know that the authenticity of this meteorite is guaranteed!

I am a member of the IMCA or the International Meteorite Collector's Association. This is an organization that is a check and balance of those who collect, trade and sell meteorites. You can only join this organization by having the utmost integrity. You must to have two references from existing members to get in and a good reputation. Members of this organization maintain a high standard by monitoring each others' activities for accuracy and honesty. It is every IMCA member's responsibility and pleasure to offer help and assistance to fellow members in order to ensure specimens are genuine. It is not wise to purchase meteorites on or other sources from those who are not IMCA members. This is a very tight-knit community made up of meteorite hunters, dealers, collectors, and scientists who look out for each other to make sure that the meteorites offered to the public are authentic and genuine. I encourage you to visit the IMCA website and get more information on what being a member means, and how your purchases from its members are guaranteed.

IMCA Member #7446

Below is some information from Wikipedia about Libyan desert glass:Tektite

From Wikipedia, the free encyclopedia

This article is about impact rocks. For the oceanographic research habitat, see Tektite habitat. For the video game character, see Recurring enemies in The Legend of Zelda series § Tektite.

Two splash-form tektites, molten terrestrial ejecta from a meteorite impact

Tektites (from Greek τηκτός tēktós, "molten") are gravel-size bodies composed of black, green, brown or gray natural glass formed from terrestrial debris ejected during meteorite impacts. The term was coined by Austrian geologist Franz Eduard Suess (1867–1941), son of Eduard Suess.[1] They generally range in size from millimeters to centimeters. Millimeters-size tektites are known as microtektites.[2][3][4]

Tektites are characterized by:

a fairly homogeneous composition;

an extremely low content of water and other volatiles;

an abundance of lechatelierite;

a general lack of microscopic crystals known as microlites and chemical relation to the local bedrock or local sediments;

their distribution within geographically extensive strewnfields

Contents [hide]

1 Characteristics

2 Classification

3 Occurrence

4 Age

5 Origins

5.1 Terrestrial source theory

5.2 Nonterrestrial source theories

6 See also

7 References

8 Literature

8.1 Books

9 External links

Although tektites are superficially similar to some terrestrial volcanic glasses (obsidians), they have unusual distinctive physical characteristics that distinguish them from such glasses. First, they are completely glassy and lack any microlites or phenocrysts, unlike terrestrial volcanic glasses. Second, although high in silica (>65 wt%), the bulk chemical and isotopic composition of tektites is closer to those of shales and similar sedimentary rocks and quite different from the bulk chemical and isotopic composition of terrestrial volcanic glasses. Third, tektites contain virtually no water (<0.02 wt%), unlike terrestrial volcanic glasses. Fourth, the flow-banding within tektites often contains particles and bands of lechatelierite, which are not found in terrestrial volcanic glasses. Finally, a few tektites contain partly melted inclusions of shocked and unshocked mineral grains, i.e. quartz, apatite, and zircon, as well as coesite.[2][3][4]

The difference in water content can be used to distinguish tektites from terrestrial volcanic glasses. When heated to their melting point, terrestrial volcanic glasses will turn into a foamy glass because of their content of water and other volatiles. Unlike terrestrial volcanic glass, a tektite will produce only a few bubbles at most when heated to its melting point, because of its much lower water and other volatiles content.[5]

On the basis of morphology and physical characteristics, tektites have traditionally been divided into four groups. The tektites which have been found on land have traditionally been subdivided into three groups: (1) splash-form (normal) tektites, (2) aerodynamically shaped tektites, and (3) Muong Nong-type (layered) tektites. Splash-form and aerodynamically shaped tektites are only differentiated on the basis of their appearance and some of their physical characteristics. Splash-form tektites are centimeter-sized tektites that are shaped like spheres, ellipsoids, teardrops, dumbbells, and other forms characteristic of isolated molten bodies. They are regarded as having formed from the solidification of rotating liquids, and not atmospheric ablation. Aerodynamically shaped tektites, which are mainly part of the Australasian strewn field, are splash-form tektites (buttons) which display a secondary ring or flange. The secondary ring or flange is argued as having been produced during the high-speed reentry and ablation of a solidified splash-form tektite into the atmosphere. Muong Nong tektites are typically larger, greater than 10 cm in size and 24 kg in weight, irregular, and layered tektites. They have a chunky, blocky appearance, exhibit a layered structure with abundant vesicles, and contain mineral inclusions, such as zircon, baddeleyite, chromite, rutile, corundum, cristobalite and coesite.[2][3][4][5]

Microtektites, the fourth group of tektites, are tektites that are less than 1 mm in size. They exhibit a variety of shapes ranging from spherical to dumbbell, disc, oval, and teardrop. The color of microtektites ranges from colorless and transparent to yellowish and pale brown. They frequently contain bubbles and lechatelierite inclusions. Microtektites are typically found in deep-sea sediments that are of the same ages as those of the four known strewn fields.[3][4] Microtektites of the Australasian strewn field have also been found on land within Chinese loess deposits, and in sediment-filled joints and decimeter-sized weathering pits developed within glacially eroded granite outcrops of the Victoria Land Transantarctic Mountains, Antarctica.[6][7]

A very rare aerodynamically shaped Australite - Shallow Bowl

Occurrence[edit]

Since 1963, it has been known that the majority of known tektites occur only within four geographically extensive strewn fields: the Australasian, Central European, Ivory Coast, and North American strewn fields.[8][9] As summarized by Koeberl,[10] the tektites within each strewn field are related to each other with respect to the criteria of petrological, physical, and chemical properties as well as their age. In addition, three of the four strewn fields have been clearly linked with impact craters using those same criteria.[2][3][4] Recognized types of tektites, grouped according to their known strewn fields, their associated craters, and ages are:

Australasian strewnfield (no associated crater identified, age: 0.77–0.78 million years):

Australites (Australia, dark, mostly black);

Indochinites (South East Asia, dark, mostly black);

Rizalite (Philippines, black).

Central European strewnfield (Nördlinger Ries impact crater (24 km), Germany, age: 15 million years):

Moldavites (Czech Republic, green).

Ivory Coast strewnfield (Lake Bosumtwi impact crater (10 km), Ghana, age: 1 million years):

Ivorites (Ivory Coast, black).

North American paras (Chesapeake Bay impact crater (40 km), United States – age: 34 million years):

Bediasites (Texas – black to dark brown, some with metallic finish);

Georgiaites (Georgia – green).[2][3][10]

Comparing the number of known impact craters versus the number of known strewn fields, Artemieva considered essential factors such as the crater must exceed a certain diameter to produce distal ejecta, and that the event must be relatively recent.[11] Limiting to diameters 10 km or more and younger than 50 Ma, the study yielded a list of 13 candidate craters, of which the youngest eight are given below,

Name Location Age

(million years) Diameter

(km) Strewn field

? Indochina? 0.78 32-114?[12] Australasian strewn field

Zhamanshin Kazakhstan 0.9 ± 0.1 14 ?

Bosumtwi Ghana 1.07 10 Ivory Coast strewn field

Elgygytgyn Siberia 3.5 ± 0.5 18 ?

Karakul Tajikistan <5 52 ?

Karla Russia 5 ± 1 10 ?

Ries Germany 15.1 ± 0.1 24 Central European strewn field

Chesapeake Bay USA 35.5 ± 0.3 40 North American strewn field

Popigai Siberia 35.7 ± 0.2 100 ?

Preliminary papers in the late 1970s suggested either Zhamanshin[13] or Elgygytgyn[14] as the source of the Australasian strewnfield.

Povenmire and others have proposed the existence of an additional tektite strewn field, the Central American strewn field. Evidence for this reported tektite strewn field consists of tektites recovered from western Belize in the area of the villages of Bullet Tree Falls, Santa Familia and Billy White. This area lies about 55 km east-southeast of Tikal where 13 tektites, two of which were dated as being 820,000 years old, of unknown origin were found. A limited amount of evidence is interpreted as indicating that the proposed Central American strewn field likely covers Belize, Honduras, Guatemala, Nicaragua and possibly parts of southern Mexico. It is speculated that the hypothesized Pantasma Impact Crater in northern Nicaragua might be the source of these tektites.[15][16][17]

Age[edit]

The ages of tektites from the four strewnfields have been determined using radiometric dating methods. The age of moldavites, a type of tektite found in Czech Republic, was determined to be 14 million years, which agrees well with the age determined for the Nördlinger Ries crater (a few hundred kilometers away in Germany) by radiometric dating of Suevite (an impact breccia found at the crater). Similar agreements exist between tektites from the North American strewnfield and the Chesapeake Bay impact crater and between tektites from the Ivory Coast strewnfield and the Lake Bosumtwi Crater. Ages of tektites have usually been determined by either the K-Ar method, fission-track dating, the Ar-Ar technique, or combination of these techniques.[2][3][4]

Origins[edit]

Terrestrial source theory[edit]

A simple, spherical splash-form Indochinite tektite

The overwhelming consensus of Earth and planetary scientists is that tektites consist of terrestrial debris that was ejected during the formation of an impact crater. During the extreme conditions created by an hypervelocity meteorite impact, near-surface terrestrial sediments and rocks were either melted, vaporized, or some combination of these and ejected from an impact crater. After ejection from the impact crater, the material formed millimeter- to centimeter-sized bodies of molten material, which as they re-entered the atmosphere, rapidly cooled to form tektites that fell to Earth to create a layer of distal ejecta hundreds or thousands of kilometers away from the impact site.[2][3][4][18][19][20]

A moldavite tektite

The terrestrial source for tektites is supported by well-documented evidence. The chemical and isotopic composition of tektites indicates that they are derived from the melting of silica-rich crustal and sedimentary rocks, which are not found on the Moon. In addition, some tektites contain relict mineral inclusions (quartz, zircon, rutile, chromite, and monazite) that are characteristic of terrestrial sediments and crustal and sedimentary source rocks. Also, three of the four tektite strewnfields have been linked by their age and chemical and isotopic composition to known impact craters. A number of different geochemical studies of tektites from the Australasian strewnfield concluded that these tektites consist of melted Jurassic sediments or sedimentary rocks that were weathered and deposited about 167 Ma ago. Their geochemistry suggests that the source of Australasian tektites is a single sedimentary formation with a narrow range of stratigraphic ages close to 170 Ma more or less. This effectively refutes multiple impact hypotheses.[2][3][4][19][20]

Although it is widely accepted that the formation of and widespread distribution of tektites requires the intense (superheated) melting of near-surface sediments and rocks at the impact site and the following high-velocity ejection of this material from the impact crater, the exact processes involved remain poorly understood. One possible mechanism for the formation of tektites is by the jetting of highly shocked and superheated melt during the initial contact/compression stage of impact crater formation. Alternatively, various mechanisms involving the dispersal of shock-melted material by an expanding vapor plume, which is created by a hypervelocity impact, have been used to explain the formation of tektites. Any mechanism by which tektites are created must explain chemical data that suggest that parent material from which tektites were created came from near-surface rocks and sediments at an impact site. In addition, the scarcity of known strewn fields relative to the number of identified Impact craters indicate that very special and rarely met circumstances are required in order for tektites to be created by a meteorite impact.[2][3][19][20]

Nonterrestrial source theories[edit]

Aerodynamically shaped Australite; the button shape caused by ablation of molten glass in the atmosphere.

Though the meteorite impact theory of tektite formation is widely accepted, there has been considerable controversy about their origin in the past. In contrast to a terrestrial impact source for tektites, it was argued that tektites consist of material that was ejected from the Moon by major hydrogen-driven lunar volcanic eruptions and then drifted through space to later fall to Earth as tektites. The major proponents of the lunar origin of tektites include NASA scientist John A. O'Keefe, NASA aerodynamicist Dean R. Chapman, meteorite and tektite collector Darryl Futrell, and long-time tektite researcher Hal Povenmire.[21] From the 1950s to the 1990s, O'Keefe argued for the lunar origin of tektites based upon their chemical, i.e. rare-earth, isotopic, and bulk, composition and physical properties.[5][21] Chapman used complex orbital computer models and extensive wind tunnel tests to argue that the so-called Australasian tektites originated from the Rosse ejecta ray of the large crater Tycho on the Moon's nearside.[22] O'Keefe, Povenmire, and Futrell claimed on the basis of behavior of glass melts that the homogenization, which is called "fining", of silica melts that characterize tektites could not be explained by the terrestrial-impact theory.[clarification needed] They also argued that the terrestrial-impact theory could not explain the vesicules and extremely low water and other volatile content of tektites.[5][21] Futrell also reported the presence of microscopic internal features within tektites, which argued for a volcanic origin.[23][24]

At one time, theories advocating the lunar origin of tektites enjoyed considerable support as part of a spirited controversy about the origin of tektites that occurred during the 1960s. Starting with the publication of research concerning lunar samples returned from the Moon, the consensus of Earth and planetary scientists shifted in favor of theories advocating a terrestrial impact versus lunar volcanic origin. For example, one problem with the lunar origin theory is that the arguments for it that are based upon the behavior of glass melts use data from pressures and temperatures that are vastly uncharacteristic of and unrelated to the extreme conditions of hypervelocity impacts.[25][26] In addition, various studies have shown that hypervelocity impacts are likely quite capable of producing low volatile melts with extremely low water content.[10] The consensus of Earth and planetary scientists regards the chemical, i.e. rare-earth, isotopic, and bulk composition evidence as decisively demonstrating that tektites are derived from terrestrial crustal rock, i.e. sedimentary rocks, that are unlike any known lunar crust.[3][10][27]

In 1960, another non-terrestrial hypothesis for the origin of tektites was proposed by the Russian-born mathematician Matest M. Agrest, who suggested that tektites were formed as a result of nuclear blasts produced by extraterrestrial beings. He used this as an argument to support his paleocontact hypothesis.[28][citation needed]