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Mineralien Kalender
hausen - Mineraliengrosshandel.com
https://www.lithomania.de
https://www.edelsteine-neuburg.de
https://crystalparadise.de/
https://vfmg.de/der-aufschluss/
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felsenmammut, Micha68
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https://www.mineralbox.biz
https://www.chiemgauer-mineralien-fossiliensammler.de/
https://www.mineral-bosse.de
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
Edelsteintage Konstanz
https://fossilsworldwide.de/
https://www.juwelo.de
Griechenland/Attika (Attikí, Attica)/East Attica/Lavreotiki/Lavrion (Laurion), Bergbaudistrikt/Km 3, Revier/Km 3 Minen/Km 3 Tagebau
 
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Annabergit
© Fritz Schreiber
https://www.mineralbox.biz
https://www.chiemgauer-mineralien-fossiliensammler.de/
https://www.mineral-bosse.de
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
Edelsteintage Konstanz
https://fossilsworldwide.de/
https://www.juwelo.de
 
 
 
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.
 
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https://www.chiemgauer-mineralien-fossiliensammler.de/
https://www.lithomania.de
https://fossilsworldwide.de/
Edelsteintage Konstanz
https://www.mineral-bosse.de
 
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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Stein­bruch Kar­ren­bergDie Bildung der Achate am Karrenberg ist äußerst komplex und hochinteressant. Erkennbar wird dies zum einen an der Abfolge der Mineralisationen im Mandelbereich. In der direkten Umgebung der größeren Mandeln kann man mit viel Glück einen kleinen Graphiteinschluss ausma ein Beitarg von u.a. Klaus Schäfer chen, der von einigen Sammlern durch angenommene Bildung von Kohlenstoffgasen als mitverantwortlich für die Hohlraumbildung angesehen wird. Diese Graphiteinschlüsse wurden bei der Bildung des Schlotes, als dieser durch tiefer gelegen karbonische Schichten brach, mitgerissen. Die von aussen nach .... Ein Beitrag von Klaus Schäfer
Die Bil­dung der Achate am Kar­ren­berg ist äußerst kom­plex und hoch­in­teres­sant. Erkenn­bar wird dies zum ei­nen an der Ab­folge der Min­er­al­i­sa­tio­nen im Man­del­bereich. In der di­rek­ten Umge­bung der größeren Man­deln kann man mit viel Glück ei­nen klei­nen Graphitein­sch­luss aus­ma ein Bei­targ von u.a. Klaus Sch ... moreDie Bildung der Achate am Karrenberg ist äußerst komplex und hochinteressant. Erkennbar wird dies zum einen an der Abfolge der Mineralisationen im Mandelbereich. In der direkten Umgebung der größeren Mandeln kann man mit viel Glück einen kleinen Graphiteinschluss ausma ein Beitarg von u.a. Klaus Schäfer chen, der von einigen Sammlern durch angenommene Bildung von Kohlenstoffgasen als mitverantwortlich für die Hohlraumbildung angesehen wird. Diese Graphiteinschlüsse wurden bei der Bildung des Schlotes, als dieser durch tiefer gelegen karbonische Schichten brach, mitgerissen. Die von aussen nach .... Ein Beitrag von Klaus Schäfer
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Min­er­al por­trait olivine (ger­man)Olivine is not a separate mineral, but a member belonging to the forsterite-fayalite mixing series. Olivine belongs to the olivin-groupe whose end-members are calcio-olivine and tephroite. Forsterite is a magnesium silicate; fayalite an iron silicate. If commonly is spoken of olivine, it is usually a more or less iron-rich forsterite. The color of olivine is generally yellowish green, olive green to black. You will find much more interesting details in our portrait about this common mineral series.

Written and investigated by Peter Seroka. (Article in german)
Olivine is not a se­parate min­er­al, but a mem­ber be­long­ing to the fors­terite-fay­alite mix­ing se­ries. Olivine be­longs to the olivin-groupe whose end-mem­bers are cal­cio-olivine and tephroite. Fors­terite is a mag­ne­si­um sil­i­cate; fay­alite an iron sil­i­cate. If com­mon­ly is spo­ken of olivine, it is usu­al­ly ... moreOlivine is not a separate mineral, but a member belonging to the forsterite-fayalite mixing series. Olivine belongs to the olivin-groupe whose end-members are calcio-olivine and tephroite. Forsterite is a magnesium silicate; fayalite an iron silicate. If commonly is spoken of olivine, it is usually a more or less iron-rich forsterite. The color of olivine is generally yellowish green, olive green to black. You will find much more interesting details in our portrait about this common mineral series.

Written and investigated by Peter Seroka. (Article in german)
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The Franken­holz Mine – A Hid­den Chapter of In­dus­trial His­to­ryFrom early tunnel construction in the 18th century to its final closure in the 1950s, the Frankenholz Mine in Germany’s Saar region was a key site of coal mining history. With ambitious shaft projects, its own cableway connection to Bexbach, and remarkable geological features – including fossil discoveries and natural oil seepages – the mine reflects both the rise of industrial progress and the dangers of underground work. Gas explosions, water ingress, and tragic accidents shaped the lives of thousands of miners. Frankenholz remains a compelling reminder of a bygone mining era.
From ear­ly tun­nel con­struc­tion in the 18th cen­tu­ry to its fi­nal clo­sure in the 1950s, the Franken­holz Mine in Ger­many’s Saar re­gion was a key site of coal min­ing his­to­ry. With am­bi­tious shaft pro­jects, its own ca­ble­way con­nec­tion to Bexbach, and re­mark­able ge­o­log­i­cal fea­tures – in­clud­ing fos­sil disc ... moreFrom early tunnel construction in the 18th century to its final closure in the 1950s, the Frankenholz Mine in Germany’s Saar region was a key site of coal mining history. With ambitious shaft projects, its own cableway connection to Bexbach, and remarkable geological features – including fossil discoveries and natural oil seepages – the mine reflects both the rise of industrial progress and the dangers of underground work. Gas explosions, water ingress, and tragic accidents shaped the lives of thousands of miners. Frankenholz remains a compelling reminder of a bygone mining era.
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Ge­o­log­ic Por­trait - Weather­ing and Ero­sionWeathering is a continous process by which rocks are broken down and decomposed by the action of humidity (rain), wind, temperature changes, chemical agents, bacteria and plants. Being an integral part of the rocks cycle, weathering is the initial stage towards denudation, which results in general lowering of the land surface. An essential feature is that it affects rocks in situ; no transportation is involved. This is the factor which dsitinguishes weathering from erosion. The two main types of weathering are mechanical and chemical. Climate plays a leading role in weathering, whereas chemical weathering is almost absent in arid regions. Effecrtive freeze-thaw cycles are confined to cold temperate and permafrost climates.

Erosion is part of the process of denudation which involves the wearing away of land surface by mechanical action of transported debris. Main cycles of erosion are glaciers, wind erosion, marine erosion.
Weather­ing is a conti­nous pro­cess by which rocks are bro­ken down and de­com­posed by the ac­tion of hu­mid­i­ty (rain), wind, tem­per­a­ture changes, chem­i­cal agents, bac­te­ria and plants. Be­ing an in­te­gral part of the rocks cy­cle, weather­ing is the ini­tial stage to­wards de­nu­da­tion, which re­sults in gen­er­al l ... moreWeathering is a continous process by which rocks are broken down and decomposed by the action of humidity (rain), wind, temperature changes, chemical agents, bacteria and plants. Being an integral part of the rocks cycle, weathering is the initial stage towards denudation, which results in general lowering of the land surface. An essential feature is that it affects rocks in situ; no transportation is involved. This is the factor which dsitinguishes weathering from erosion. The two main types of weathering are mechanical and chemical. Climate plays a leading role in weathering, whereas chemical weathering is almost absent in arid regions. Effecrtive freeze-thaw cycles are confined to cold temperate and permafrost climates.

Erosion is part of the process of denudation which involves the wearing away of land surface by mechanical action of transported debris. Main cycles of erosion are glaciers, wind erosion, marine erosion.
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Fal­tenEine durch Faltung entstandene Verbiegung oder Verkrümmung einer ehemals horizontal geschichteten Gesteinseinheit in allen Größenordnungen. Je nach Form unterscheidet man Knickfalten, Biegefalten oder Fließfalten. Die Faltenformen Sattel (Antiform) und Mulde (Synform) sind abhängig von der Mächtigkeit des verfalteten Schichtpaketes, den mechanischen Eigenschaften der Gesteine, dem Vorhandensein von Abscherflächen und auftretenden Spannungen.
Eine durch Fal­tung ent­s­tan­dene Ver­bie­gung oder Verkrüm­mung ein­er ehe­mals hor­i­zon­tal geschichteten Gestein­sein­heit in allen Größenord­nun­gen. Je nach Form un­ter­schei­det man Knick­fal­ten, Biege­fal­ten oder Fließ­fal­ten. Die Fal­ten­for­men Sat­tel (An­ti­form) und Mulde (Syn­form) sind ab­hängig von der Mächtigke ... moreEine durch Faltung entstandene Verbiegung oder Verkrümmung einer ehemals horizontal geschichteten Gesteinseinheit in allen Größenordnungen. Je nach Form unterscheidet man Knickfalten, Biegefalten oder Fließfalten. Die Faltenformen Sattel (Antiform) und Mulde (Synform) sind abhängig von der Mächtigkeit des verfalteten Schichtpaketes, den mechanischen Eigenschaften der Gesteine, dem Vorhandensein von Abscherflächen und auftretenden Spannungen.
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Min­er­alien­por­trait Ze­olitheNatürliche Zeolithe sind Gerüst-Aluminosilikate der Alkali- und Erdalkalimetalle, besonders Ca, Na und K. Weniger häufig sind Zeolithe, welche Ba, Sr, Cs, Li und Mg enthalten. Bis heute sind 97 natürliche Spezies bekannt, darunter die wichtigsten Klinoptilolith, Chabasit, Phillipsit, Mordenit, Laumontit, Stilbit, Heulandit, Analcim, Natrolith und Thomsonit. Charakteristisch für alle Zeolithe ist ihre dreidimensionale Aluminosilikat-Struktur mit variablen polyedrischen Gruppen, deren Struktur mit Wasser gefüllte relativ große Kanäle und Hohlräume zwischen diesen Polyedern enthält. Diese Hohlräume und Kanäle können Kationen (z.B. Metall-Ionen), Wasser und andere Moleküle enthalten, welche den Zeolithe ihre wichtigsten Eigenschaften als Molekularsiebe, Katalysatoren, Ionenaustauscher etc. verleihen.
Natür­liche Ze­olithe sind Gerüst-Alu­mi­nosi­likate der Al­ka­li- und Er­dal­ka­lime­t­alle, be­son­ders Ca, Na und K. Weniger häu­fig sind Ze­olithe, welche Ba, Sr, Cs, Li und Mg en­thal­ten. Bis heute sind 97 natür­liche Spezies bekan­nt, darun­ter die wichtig­sten Klinop­tilolith, Ch­ab­a­sit, Phil­lip­sit, Mor­denit, Lau ... moreNatürliche Zeolithe sind Gerüst-Aluminosilikate der Alkali- und Erdalkalimetalle, besonders Ca, Na und K. Weniger häufig sind Zeolithe, welche Ba, Sr, Cs, Li und Mg enthalten. Bis heute sind 97 natürliche Spezies bekannt, darunter die wichtigsten Klinoptilolith, Chabasit, Phillipsit, Mordenit, Laumontit, Stilbit, Heulandit, Analcim, Natrolith und Thomsonit. Charakteristisch für alle Zeolithe ist ihre dreidimensionale Aluminosilikat-Struktur mit variablen polyedrischen Gruppen, deren Struktur mit Wasser gefüllte relativ große Kanäle und Hohlräume zwischen diesen Polyedern enthält. Diese Hohlräume und Kanäle können Kationen (z.B. Metall-Ionen), Wasser und andere Moleküle enthalten, welche den Zeolithe ihre wichtigsten Eigenschaften als Molekularsiebe, Katalysatoren, Ionenaustauscher etc. verleihen.
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hausen - Mineraliengrosshandel.com
https://vfmg.de/der-aufschluss/
https://www.juwelo.de
Mineralien Kalender
https://www.edelsteine-neuburg.de
https://crystalparadise.de/