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05. Apr. - Ta­tort Franken – Das stein­erne Grab der Rie­sen­lurche
10. Apr. - Min­er­alien­börse im Lausitz-Cen­ter in Hoy­er­sw­er­da
11. Apr. - Min­er­alien­börse im Lausitz-Cen­ter in Hoy­er­sw­er­da
11. Apr. - 23. Min­er­alien-IN­FO im Ahrn­tal - Südtirol
11. Apr. - Min­er­alien.- und Fos­silien­börse Rosen­heim - Auer Fes­thalle
12. Apr. - 31. Min­er­alien- und Fos­silien­samm­ler­börse Eg­gen­burg / AT
12. Apr. - Min­er­alien­börse Her­born-Merken­bach
17. Apr. - GERA: Bild­vor­trag „Der Ein­fluss Preußens auf den Berg­bau im
19. Apr. - 25. Bay­er­wald-Min­er­alien­börse Bad Kötzt­ing, DE
26. Apr. - 34. Min­er­alien- und Fos­silien­börse Arns­berg-Müschede, DE
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Deutschland/Nordrhein-Westfalen/Arnsberg, Bezirk/Hochsauerlandkreis/Arnsberg/Holzen
 
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05. Apr. - Ta­tort Franken – Das stein­erne Grab der Rie­sen­lurche
10. Apr. - Min­er­alien­börse im Lausitz-Cen­ter in Hoy­er­sw­er­da
11. Apr. - Min­er­alien­börse im Lausitz-Cen­ter in Hoy­er­sw­er­da
11. Apr. - 23. Min­er­alien-IN­FO im Ahrn­tal - Südtirol
11. Apr. - Min­er­alien.- und Fos­silien­börse Rosen­heim - Auer Fes­thalle
12. Apr. - 31. Min­er­alien- und Fos­silien­samm­ler­börse Eg­gen­burg / AT
12. Apr. - Min­er­alien­börse Her­born-Merken­bach
17. Apr. - GERA: Bild­vor­trag „Der Ein­fluss Preußens auf den Berg­bau im
19. Apr. - 25. Bay­er­wald-Min­er­alien­börse Bad Kötzt­ing, DE
26. Apr. - 34. Min­er­alien- und Fos­silien­börse Arns­berg-Müschede, DE
09. May - 77. In­ter­na­tio­nale Min­er­alien­börse in Freiberg/Sach­sen
09. May - 50. Min­er­alien- & Fos­silien­börse “MIN­ER­AN­T2026” - Gol­d­en
09. May - 43. Aschaf­fen­burg­er Min­er­alien­börse
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Mineralien Kalender
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Mineralienatlas (name for mineral atlas) is the platform for people interested in mineralogy, geology, palaeontology and mining since 2001. We operate a significant database for minerals, fossils, rocks and their localities. Mineralienatlas is not limited to a section. We bring together information and inform comprehensive.

To complete our information constantly, we need your support. With us, everyone can and should participate. Currently Mineralienatlas is used and expanded by 10531 members. Every month hundreds of thousands of visitors use our website as an information source.
 
Geolitho Foundation non-profit GmbH
Geolitho Foundation non-profit GmbH is the non-profit supporter of the Mineral Atlas (Mineralienatlas), the Lithotheque, the Geolitho Collection Management and the Marketplace and Store by collectors for collectors. The Foundation promotes public education in the field of mineralogy, geology, paleontology and mining by operating, maintaining and further expanding earth science projects.
 
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The min­ing area Marien­berg in the Erzge­birge Re­gionAfter the discovery of silver deposits in Christiansdorf - the now called Freiberg - over the time the mining was also expanded on the upper mountain. Thus from about 1240, the tin deposits (with the beginnings of subsurface mining also silver) around Ehrenfriedersdorf was mined. By finding rich silver adits in the 2nd third of the 15th Century the great mountain towns like Schneeberg (municipal law since 1477) and Annaberg (municipal law since 1496) was founded. (Article in german)
Af­ter the dis­cov­ery of sil­ver de­posits in Chris­tians­dorf - the now called Freiberg - over the time the min­ing was al­so ex­pand­ed on the up­per moun­tain. Thus from about 1240, the tin de­posits (with the be­gin­n­ings of sub­sur­face min­ing al­so sil­ver) around Ehren­fried­ers­dorf was mined. By find­ing rich si ... moreAfter the discovery of silver deposits in Christiansdorf - the now called Freiberg - over the time the mining was also expanded on the upper mountain. Thus from about 1240, the tin deposits (with the beginnings of subsurface mining also silver) around Ehrenfriedersdorf was mined. By finding rich silver adits in the 2nd third of the 15th Century the great mountain towns like Schneeberg (municipal law since 1477) and Annaberg (municipal law since 1496) was founded. (Article in german)
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Min­er­alien­por­trait Spha­ler­itDer Name des Minerals stammt vom griechischen sphaleros. Dieses bedeutet trügerisch, weil aus der zusammen mit Bleiglanz gefundenen Zinkblende kein Blei gewonnen werden konnte und das Element Zink noch nicht entdeckt war. Blende war die Bergmannsbezeichnung für taubes Erz. Sphalerit ist das wichtigste Zinkerz, aus welchem neben dem Metall Zink auch Cadmium, Indium und ....

Sphalerit gehört zum kubischen Kristallsystem und zur hexakistetraedrischen Klasse. Die Struktur der Kristalle ist ähnlich der Diamantstruktur, wobei, anders als bei Diamant, um jedes S-Ion an den Tetraederecken vier Zinkionen angeordnet sind. Im Gegensatz zu Diamant verläuft die Spaltbarkeit in den Sphaleritkristallen nicht nach den Flächen des Oktaeders, sondern nach den Flächen des Rhombendodekaeders {110}, da diese Gitterebenen gleichviel Zn- und ... Ein Beitrag von Peter Seroka
Der Name des Min­er­als stammt vom griechischen sphaleros. Die­s­es be­deutet trügerisch, weil aus der zusam­men mit Bleiglanz ge­fun­de­nen Zink­blende kein Blei ge­won­nen wer­den kon­nte und das El­e­ment Zink noch nicht ent­deckt war. Blende war die Berg­manns­bezeich­nung für taubes Erz. Spha­ler­it ist das wichtigs ... moreDer Name des Minerals stammt vom griechischen sphaleros. Dieses bedeutet trügerisch, weil aus der zusammen mit Bleiglanz gefundenen Zinkblende kein Blei gewonnen werden konnte und das Element Zink noch nicht entdeckt war. Blende war die Bergmannsbezeichnung für taubes Erz. Sphalerit ist das wichtigste Zinkerz, aus welchem neben dem Metall Zink auch Cadmium, Indium und ....

Sphalerit gehört zum kubischen Kristallsystem und zur hexakistetraedrischen Klasse. Die Struktur der Kristalle ist ähnlich der Diamantstruktur, wobei, anders als bei Diamant, um jedes S-Ion an den Tetraederecken vier Zinkionen angeordnet sind. Im Gegensatz zu Diamant verläuft die Spaltbarkeit in den Sphaleritkristallen nicht nach den Flächen des Oktaeders, sondern nach den Flächen des Rhombendodekaeders {110}, da diese Gitterebenen gleichviel Zn- und ... Ein Beitrag von Peter Seroka
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Ge­o­log­ic and min­er­a­log­i­cal ex­pe­di­tion through Namibia and the Na­maqua­landReport about a geologic - and geology of deposits excursion through central and southern Namibia as well as the Namaqualand bordering to the South and parts of the Northern cape in autumn, 2009., Amongst other localities in Namibia the author visited the tin deposit Uis, the explorations project Namib Lead near Swakopmund, as well as the important mines Rosh Pinah and Scorpion Zinc in the south of Namibia. In the Republic South Africa the trip led to the copper mining region of Okiep as well as the lead zinc mines of Aggeneys and, finally, to the Kalahari manganese ore districts of Postmasburg and Kuruman.

(Full text in german)
Re­port about a ge­o­log­ic - and ge­ol­o­gy of de­posits ex­cur­sion through cen­tral and south­ern Namibia as well as the Na­maqua­land bor­der­ing to the South and parts of the North­ern cape in au­tumn, 2009., Amongst other lo­cal­i­ties in Namibia the au­thor visit­ed the tin de­posit Uis, the ex­plo­ra­tions pro­ject Na ... moreReport about a geologic - and geology of deposits excursion through central and southern Namibia as well as the Namaqualand bordering to the South and parts of the Northern cape in autumn, 2009., Amongst other localities in Namibia the author visited the tin deposit Uis, the explorations project Namib Lead near Swakopmund, as well as the important mines Rosh Pinah and Scorpion Zinc in the south of Namibia. In the Republic South Africa the trip led to the copper mining region of Okiep as well as the lead zinc mines of Aggeneys and, finally, to the Kalahari manganese ore districts of Postmasburg and Kuruman.

(Full text in german)
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Min­er­alien­por­trait - Mag­netitDie ersten konkreten Beschreibungen der magnetischen Eigenschaften des Magnetit stammen vom griechischen Philosophen und Wissenschaftler Thales von Miletus aus dem 6. Jh. v. Chr. 300 Jahre später waren diese Eigenschaften auch im alten China bekannt. Erste chinesische Kompasse sind im 1. Jh. verwendet worden. Chinesische Mediziner konnten mittels Magnetit winzige Eisenfragmente aus dem Auge entfernen.

Wenngleich die Eigenschaft des Magnetismus schon den Griechen (Stein Magnetis des Theophrast von Eresos: "Über die Steine)"), Römern (Stein Magnes von Plinius dem Älteren; Gaius Plinius Secundus: "Historia Naturalis") und den Chinesen bekannt waren, dauerte es bis zum Jahr 1088, dass der chinesische Enzyklopädist Shen Kua in seinem in diesem Jahr erschienenen "Buch Meng Ch'i Pi T'an" den ersten klaren Bericht über einen aufgehängten Magnetkompass schrieb. Etwa um 1180 erschien die Beschreibung einer Kompassnadel als Navigationsmittel für die Seefahrt durch den englischen Wissenschaftler und Lehrer Alexander Neckam. Im Jahr 1269 veröffentlichte Petrus Peregrinus ... Ein Mineralien-Portrait erstellt von Peter Seroka
Die er­sten konkreten Beschrei­bun­gen der mag­netischen Ei­gen­schaften des Mag­netit stam­men vom griechischen Philo­sophen und Wis­sen­schaftler Thales von Mile­tus aus dem 6. Jh. v. Chr. 300 Jahre später waren diese Ei­gen­schaften auch im al­ten Chi­na bekan­nt. Er­ste chi­ne­sische Kom­passe sind im 1. Jh. ver­wend ... moreDie ersten konkreten Beschreibungen der magnetischen Eigenschaften des Magnetit stammen vom griechischen Philosophen und Wissenschaftler Thales von Miletus aus dem 6. Jh. v. Chr. 300 Jahre später waren diese Eigenschaften auch im alten China bekannt. Erste chinesische Kompasse sind im 1. Jh. verwendet worden. Chinesische Mediziner konnten mittels Magnetit winzige Eisenfragmente aus dem Auge entfernen.

Wenngleich die Eigenschaft des Magnetismus schon den Griechen (Stein Magnetis des Theophrast von Eresos: "Über die Steine)"), Römern (Stein Magnes von Plinius dem Älteren; Gaius Plinius Secundus: "Historia Naturalis") und den Chinesen bekannt waren, dauerte es bis zum Jahr 1088, dass der chinesische Enzyklopädist Shen Kua in seinem in diesem Jahr erschienenen "Buch Meng Ch'i Pi T'an" den ersten klaren Bericht über einen aufgehängten Magnetkompass schrieb. Etwa um 1180 erschien die Beschreibung einer Kompassnadel als Navigationsmittel für die Seefahrt durch den englischen Wissenschaftler und Lehrer Alexander Neckam. Im Jahr 1269 veröffentlichte Petrus Peregrinus ... Ein Mineralien-Portrait erstellt von Peter Seroka
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Min­er­al Por­trait PyriteThe term used in the plural "pyrites" has often been misused in the past or in common for marcasite, chalcopyrite, pyrrhotite and other yellow to brass-colored minerals. The word pyrite is derived from the Greek "pyrites lithos" (derived pyr = fire and lithos = stone) and describes a characteristic of the mineral, when rubbing against steel or flint (flint) to generate sparks. In prehistoric tombs pyrite concretions and unrolled pyrite where found, which supposed to be used for lighting a fire. (Article in German)
The term used in the plu­ral "pyrites" has of­ten been mi­sused in the past or in com­mon for mar­c­a­site, chal­copy­rite, pyr­rhotite and other yel­low to brass-col­ored min­er­als. The word pyrite is de­rived from the Greek "pyrites lithos" (de­rived pyr = fire and lithos = stone) and de­scribes a char­ac­teris­tic ... moreThe term used in the plural "pyrites" has often been misused in the past or in common for marcasite, chalcopyrite, pyrrhotite and other yellow to brass-colored minerals. The word pyrite is derived from the Greek "pyrites lithos" (derived pyr = fire and lithos = stone) and describes a characteristic of the mineral, when rubbing against steel or flint (flint) to generate sparks. In prehistoric tombs pyrite concretions and unrolled pyrite where found, which supposed to be used for lighting a fire. (Article in German)
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Min­er­al Por­trait - REE - Rare Earth El­e­mentsThis is the most comprehensive synopsis related to the history, the mineralogy, the exploitation and the most actual economic and political resumé on rare earth elements and their minerals to be found in the internet. REE belong to the most important raw materials of the 21st century, which are used in a large number of key technologies. However, due to the fact that almost 97% of the world's REE are mined and produced in China, REE have become an ongoing political issue, mainly amongst technology providing countries like the US, Japan and Western Europe.

This portrait tries to explain the characteristics of REE and their role for our modern world. Written and investigated by Peter Seroka. (Article in german)
This is the most com­pre­hen­sive syn­op­sis re­lat­ed to the his­to­ry, the min­er­al­o­gy, the ex­ploi­ta­tion and the most ac­tu­al eco­nom­ic and po­lit­i­cal re­sumé on rare earth el­e­ments and their min­er­als to be found in the in­ter­net. REE be­long to the most im­por­tant raw ma­te­rials of the 21st cen­tu­ry, which are used ... moreThis is the most comprehensive synopsis related to the history, the mineralogy, the exploitation and the most actual economic and political resumé on rare earth elements and their minerals to be found in the internet. REE belong to the most important raw materials of the 21st century, which are used in a large number of key technologies. However, due to the fact that almost 97% of the world's REE are mined and produced in China, REE have become an ongoing political issue, mainly amongst technology providing countries like the US, Japan and Western Europe.

This portrait tries to explain the characteristics of REE and their role for our modern world. Written and investigated by Peter Seroka. (Article in german)
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In­di­ca­tor stoneA Scandinavian indicator stone is a glacial erratic composed of a characteristic rock type derived from a small known source area in Scandinavia. This term not only applies to igneous and metamorphic rocks but also to some sedimentary rocks. The Jotnian Sandstone and most of the Palaeozoic limestones, and the Old Red Sandstone are not included in the definition, although the presence of these and other rocks provide some evidence about the source area(s) of erratics and should certainly not be neglected in a stone count. In all cases we recommend including the whole assemblage of erratics/stones in such account. This makes it possible to use several methods of Interpretation. However, it should be pointed out that the practise used in the past, whereby each researcher had her/his own method of interpreting stone counts, has proved to be unsatisfactory. We demonstrate on the bases of over 2000 counts of indicator stones that we have carried out on assemblages mostly from Lower Saxony and Schleswig-Holstein, but also from other N.German states and neighbouring countries, that the TGZ method (LÜTTIG 1958) yields the most reliable results. In addition to this method, the sources of individual indicator stones may be plotted on a so-called circle map and can be integrated with possible source data and the relative frequencies of other erratics in the assemblage. Some rock types are more suitable as indicator stones then others. It is unwise to use clearly unsuitable rock types; this would considerably reduce the reliability of the method and lead to erroneous results.
A Scan­di­na­vian in­di­ca­tor stone is a gla­cial er­rat­ic com­posed of a char­ac­teris­tic rock type de­rived from a small known source area in Scan­di­navia. This term not on­ly ap­plies to ig­neous and me­ta­mor­ph­ic rocks but al­so to some sed­i­men­tary rocks. The Jot­nian Sand­s­tone and most of the Palaeo­zoic lime­s­tone ... moreA Scandinavian indicator stone is a glacial erratic composed of a characteristic rock type derived from a small known source area in Scandinavia. This term not only applies to igneous and metamorphic rocks but also to some sedimentary rocks. The Jotnian Sandstone and most of the Palaeozoic limestones, and the Old Red Sandstone are not included in the definition, although the presence of these and other rocks provide some evidence about the source area(s) of erratics and should certainly not be neglected in a stone count. In all cases we recommend including the whole assemblage of erratics/stones in such account. This makes it possible to use several methods of Interpretation. However, it should be pointed out that the practise used in the past, whereby each researcher had her/his own method of interpreting stone counts, has proved to be unsatisfactory. We demonstrate on the bases of over 2000 counts of indicator stones that we have carried out on assemblages mostly from Lower Saxony and Schleswig-Holstein, but also from other N.German states and neighbouring countries, that the TGZ method (LÜTTIG 1958) yields the most reliable results. In addition to this method, the sources of individual indicator stones may be plotted on a so-called circle map and can be integrated with possible source data and the relative frequencies of other erratics in the assemblage. Some rock types are more suitable as indicator stones then others. It is unwise to use clearly unsuitable rock types; this would considerably reduce the reliability of the method and lead to erroneous results.
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Edelsteintage Konstanz
https://www.mineral-bosse.de
https://crystalparadise.de/
hausen - Mineraliengrosshandel.com
https://fossilsworldwide.de/
https://www.juwelo.de