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Mineralien Kalender
https://fossilsworldwide.de/
https://www.chiemgauer-mineralien-fossiliensammler.de/
https://www.mineral-bosse.de
hausen - Mineraliengrosshandel.com
https://www.lithomania.de
993 Gäste, 18 Mitglieder (3 Versteckte)
palpatine, Quarzhai, Bode, Junibolte, Haspelknecht, loismin, Bruno80090, FF, helgesteen, blackforestmining2, Walpurgin, sulzbacher, grille, nwsachse, Stronkolo
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Edelsteintage Konstanz
https://www.edelsteine-neuburg.de
https://www.juwelo.de
13. May - Mi­cro­mount-Um­lauf: Min­er­alien aus Pak­is­tan
17. May - Gera, Mu­se­um für Na­turkunde: Ausstel­lungseröff­nung
21. May - 29. In­ter­na­tio­nale Jahres­ta­gung Geo­Top der Fach­sek­tion Geo­to
06. June - GERA: „Min­er­alien­tr­eff im Ju­ni“
07. June - 4. Fest der edlen Steine im Rit­tergut Treb­sen/Sach­sen
13. June - Min­er­alien­börse in Knit­telfeld
14. June - Min­er­alien­börse im Fin­d­lings­park Nocht­en
21. June - Min­er­alien­börse
https://www.mineralbox.biz
https://crystalparadise.de/
https://vfmg.de/der-aufschluss/
Deutschland/Sachsen/Erzgebirgskreis/Aue-Bad Schlema, Große Kreisstadt/Lagerstätte Schlema-Alberoda/Schacht 12
 
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Fluorit
© Schluchti
Edelsteintage Konstanz
https://www.edelsteine-neuburg.de
https://www.juwelo.de
13. May - Mi­cro­mount-Um­lauf: Min­er­alien aus Pak­is­tan
17. May - Gera, Mu­se­um für Na­turkunde: Ausstel­lungseröff­nung
21. May - 29. In­ter­na­tio­nale Jahres­ta­gung Geo­Top der Fach­sek­tion Geo­to
06. June - GERA: „Min­er­alien­tr­eff im Ju­ni“
07. June - 4. Fest der edlen Steine im Rit­tergut Treb­sen/Sach­sen
13. June - Min­er­alien­börse in Knit­telfeld
14. June - Min­er­alien­börse im Fin­d­lings­park Nocht­en
21. June - Min­er­alien­börse
Calender
https://www.mineralbox.biz
https://crystalparadise.de/
https://vfmg.de/der-aufschluss/
 
 
 
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 10586 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.
 
https://www.mineral-bosse.de
https://fossilsworldwide.de/
hausen - Mineraliengrosshandel.com
Edelsteintage Konstanz
https://www.chiemgauer-mineralien-fossiliensammler.de/
https://www.lithomania.de
 
Min­er­alien­por­trait WulfenitDas Mineral Wulfenit wurde - so die allgemein verbreitete Version bzw. der allgemein verbreitete Irrtum - Ende des 18. Jh. vom österreichischen Jesuiten (Abbé), Botaniker und Mineralogen Franz Freiherr von Wulfen entdeckt und von ihm in seiner berühmten "Abhandlung vom Kärnthnerischen Bleyspathe" im Jahr 1785 beschrieben und gezeichnet, obwohl es bereits 1772 eine Veröffentlichung des Siebenbürgener Mineralogen und Geologen Ignaz von Born gab, mit dem Titel: "Plumbum spatosum flavo-rubrum pellucidum" (von Annaberg in Niederösterreich). Von Wulfen selbst zitierte den berühmten Bergrat Scopoli, welcher in seiner "Einleitung zur Kenntnis der Fossilien" den kärntherischen Bleyspat als " ungestaltete, ockergelblichte, versteinerte Bleyerde, welche im Zentner 27 bis 30 Pfund Blei enthält " beschrieb... ein Beitrag von Peter Seroka
Das Min­er­al Wulfenit wurde - so die all­ge­mein ver­breit­ete Ver­sion bzw. der all­ge­mein ver­breit­ete Ir­r­tum - Ende des 18. Jh. vom öster­reichischen Je­suit­en (Ab­bé), Bo­tanik­er und Min­er­alo­gen Franz Frei­herr von Wulfen ent­deckt und von ihm in sein­er berühmten "Ab­hand­lung vom Kärn­th­nerischen Bleys­pathe" im ... moreDas Mineral Wulfenit wurde - so die allgemein verbreitete Version bzw. der allgemein verbreitete Irrtum - Ende des 18. Jh. vom österreichischen Jesuiten (Abbé), Botaniker und Mineralogen Franz Freiherr von Wulfen entdeckt und von ihm in seiner berühmten "Abhandlung vom Kärnthnerischen Bleyspathe" im Jahr 1785 beschrieben und gezeichnet, obwohl es bereits 1772 eine Veröffentlichung des Siebenbürgener Mineralogen und Geologen Ignaz von Born gab, mit dem Titel: "Plumbum spatosum flavo-rubrum pellucidum" (von Annaberg in Niederösterreich). Von Wulfen selbst zitierte den berühmten Bergrat Scopoli, welcher in seiner "Einleitung zur Kenntnis der Fossilien" den kärntherischen Bleyspat als " ungestaltete, ockergelblichte, versteinerte Bleyerde, welche im Zentner 27 bis 30 Pfund Blei enthält " beschrieb... ein Beitrag von Peter Seroka
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Min­er­al por­trait gar­netThis portrait mainly deals with the 6 classic garnets, their amazing history, the world’s best known classic and modern localities and deposits and their use as a gems or abrasives. It also deals with the common belief related to the non-existence of blue garnets and its refutation proven by new finds. A separate chapter deals with synthetic garnets. But it also deals with the mix up of definitions, groupings and old and unnecessary terms, which have finally been terminated or brought to a common denominator.

In 2012 the IMA (CNMNC) has defined garnets as members of the Garnet Supergroup, which include all minerals isostructural with garnet regardless of what elements occupy the four atomic sites; i.e. the supergroup includes several chemical classes . Those minerals are closely related to each other and may form a series with each other. Some garnets form intermediary minerals between each member, and may even be intergrown within a single crystal.

With the publication of the new nomenclature of the garnet supergroup, the term “garnet group” does not have its meaning anymore and the intermediate working term “Garnet superstructural group” has been replaced by “Garnet Supergroup”.
There are 32 approved species and 5 “candidate” species waiting on approval. The 32 species are subdivided by their Z-charge into 29 species, which belong to 5 groups and to 3 single representative species.
One of those 5 groups is the “Garnet group”, consisting of the 6 former (classic) garnets Pyrope, Grossular, Spessartine, Almandine, Uvarovite and Andradite plus 8 rarer garnets , as Menzerite-(Y), Eringaite, Goldmanite, Momoiite, Knorringite, Calderite, Majorite and Morimotoite.
This por­trait main­ly deals with the 6 clas­sic gar­nets, their amaz­ing his­to­ry, the world’s best known clas­sic and mod­ern lo­cal­i­ties and de­posits and their use as a gems or abra­sives. It al­so deals with the com­mon be­lief re­lat­ed to the non-ex­is­tence of blue gar­nets and its refu­ta­tion proven by new ... moreThis portrait mainly deals with the 6 classic garnets, their amazing history, the world’s best known classic and modern localities and deposits and their use as a gems or abrasives. It also deals with the common belief related to the non-existence of blue garnets and its refutation proven by new finds. A separate chapter deals with synthetic garnets. But it also deals with the mix up of definitions, groupings and old and unnecessary terms, which have finally been terminated or brought to a common denominator.

In 2012 the IMA (CNMNC) has defined garnets as members of the Garnet Supergroup, which include all minerals isostructural with garnet regardless of what elements occupy the four atomic sites; i.e. the supergroup includes several chemical classes . Those minerals are closely related to each other and may form a series with each other. Some garnets form intermediary minerals between each member, and may even be intergrown within a single crystal.

With the publication of the new nomenclature of the garnet supergroup, the term “garnet group” does not have its meaning anymore and the intermediate working term “Garnet superstructural group” has been replaced by “Garnet Supergroup”.
There are 32 approved species and 5 “candidate” species waiting on approval. The 32 species are subdivided by their Z-charge into 29 species, which belong to 5 groups and to 3 single representative species.
One of those 5 groups is the “Garnet group”, consisting of the 6 former (classic) garnets Pyrope, Grossular, Spessartine, Almandine, Uvarovite and Andradite plus 8 rarer garnets , as Menzerite-(Y), Eringaite, Goldmanite, Momoiite, Knorringite, Calderite, Majorite and Morimotoite.
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Das Chibiny-Mas­siv auf der Hal­binsel Ko­laDas Chibiny-Massiv auf der russischen Halbinsel Kola, das eine Fläche von über 1300 km² einnimmt, liegt zwischen den Seen Imandra im Westen und Umbozero im Osten. Höchster Berg ist der Tchasnachorr mit fast 1200 m. Im Osten liegen die Täler der Flüsse Tuljok, Vuonnemiok und Maivaitajok.

Eine vielfältige Vegetation reicht von einer lichten Fichten-Birken-Taiga über Wald- und Strauchtundra bis hin zur Flechtentundra und zu steinigem Ödland. Dabei nehmen letztgenannte Zonen einen großen Teil des kristallinen Chibiny-Massivs ein...
Das Chibiny-Mas­siv auf der rus­sischen Hal­binsel Ko­la, das eine Fläche von über 1300 km² ein­n­immt, liegt zwischen den Seen Iman­dra im West­en und Um­boze­ro im Os­ten. Höch­ster Berg ist der Tchas­na­chorr mit fast 1200 m. Im Os­ten lie­gen die Täler der Flüsse Tuljok, Vuon­ne­miok und Mai­vai­ta­jok.

Eine vie ... moreDas Chibiny-Massiv auf der russischen Halbinsel Kola, das eine Fläche von über 1300 km² einnimmt, liegt zwischen den Seen Imandra im Westen und Umbozero im Osten. Höchster Berg ist der Tchasnachorr mit fast 1200 m. Im Osten liegen die Täler der Flüsse Tuljok, Vuonnemiok und Maivaitajok.

Eine vielfältige Vegetation reicht von einer lichten Fichten-Birken-Taiga über Wald- und Strauchtundra bis hin zur Flechtentundra und zu steinigem Ödland. Dabei nehmen letztgenannte Zonen einen großen Teil des kristallinen Chibiny-Massivs ein...
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Min­er­al por­trait calcite... Among the most spectacular finds are the fantastic light blue calcites from the Julia mine in Bilbao, which enraptured collectors' hearts to about the mid-1970s. At about the same time the zinc mine Las Manforas at Aliva supplied excellent, highl lustrous Calcites, often associated with the world's best red Sphalerites. ...

Amonsgt the forms of calcite the pinacoid is unique as it consists of exactly two parallel and oriented perpendicular to the c-axis surfaces. All other Calcite forms have either six or twelve areas. The pinacoid is an open form, with which it can not really include space; so the pinacoid must accompany other forms on the calcite crystal ...

A mineral portrait written by Peter Seroka with contributions from Ingo Löffler, Edgar Müller, Rainer Albert, William Waltermann (written in German)
... Among the most spec­tac­u­lar finds are the fan­tas­tic light blue calcites from the Ju­lia mine in Bil­bao, which en­rap­tured col­lec­tors' hearts to about the mid-1970s. At about the same time the zinc mine Las Man­fo­ras at Ali­va sup­plied ex­cel­lent, highl lus­trous Calcites, of­ten as­so­ci­at­ed with the worl ... more... Among the most spectacular finds are the fantastic light blue calcites from the Julia mine in Bilbao, which enraptured collectors' hearts to about the mid-1970s. At about the same time the zinc mine Las Manforas at Aliva supplied excellent, highl lustrous Calcites, often associated with the world's best red Sphalerites. ...

Amonsgt the forms of calcite the pinacoid is unique as it consists of exactly two parallel and oriented perpendicular to the c-axis surfaces. All other Calcite forms have either six or twelve areas. The pinacoid is an open form, with which it can not really include space; so the pinacoid must accompany other forms on the calcite crystal ...

A mineral portrait written by Peter Seroka with contributions from Ingo Löffler, Edgar Müller, Rainer Albert, William Waltermann (written in German)
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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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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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Min­er­alien­por­trait Cerus­sit... Wer das Mineral Cerussit zuerst entdeckte und wo es zuerst gefunden wurde, bleibt im Dunkel der Geschichte. Um dem Kind jedoch einen Namen zu geben, wird die erste Erwähnung dem Renaissancegelehrten Conrad Gesner angetragen - was jedoch nicht bedeutet, dass dieser das Mineral entdeckte oder zuerst beschrieb. (Gesner (1516 bis 1565) gilt als der berühmteste und wichtigste Naturforscher und Gelehrter der Schweiz).

Tatsache ist, dass Cerussit (und Hydrocerussit) schon in der Antike den damaligen Bergleuten bekannt war; besonders in den Gruben von Lavrion in Griechenland sowie aus den reichen Blei-und Silberminen in Sardinien. Cerussit ist ein sehr häufiges Mineral, welches sich in den Oxidationszonen aus Galenit und carbonathaltigren Wässern bildete ... Ein Beitrag von Peter Seroka
... Wer das Min­er­al Cerus­sit zuerst ent­deckte und wo es zuerst ge­fun­den wurde, bleibt im Dunkel der Geschichte. Um dem Kind je­doch ei­nen Na­men zu geben, wird die er­ste Er­wäh­nung dem Re­nais­sancegelehrten Con­rad Ges­n­er ange­tra­gen - was je­doch nicht be­deutet, dass dies­er das Min­er­al ent­deckte oder zuer ... more... Wer das Mineral Cerussit zuerst entdeckte und wo es zuerst gefunden wurde, bleibt im Dunkel der Geschichte. Um dem Kind jedoch einen Namen zu geben, wird die erste Erwähnung dem Renaissancegelehrten Conrad Gesner angetragen - was jedoch nicht bedeutet, dass dieser das Mineral entdeckte oder zuerst beschrieb. (Gesner (1516 bis 1565) gilt als der berühmteste und wichtigste Naturforscher und Gelehrter der Schweiz).

Tatsache ist, dass Cerussit (und Hydrocerussit) schon in der Antike den damaligen Bergleuten bekannt war; besonders in den Gruben von Lavrion in Griechenland sowie aus den reichen Blei-und Silberminen in Sardinien. Cerussit ist ein sehr häufiges Mineral, welches sich in den Oxidationszonen aus Galenit und carbonathaltigren Wässern bildete ... Ein Beitrag von Peter Seroka
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https://crystalparadise.de/
Mineralien Kalender
https://www.mineralbox.biz
https://www.juwelo.de
https://www.edelsteine-neuburg.de
https://vfmg.de/der-aufschluss/