🧲📚 The El Laco system is an enigmatic and well-preserved magnetite-(apatite) deposit located in Chile, with three major genetic models for its formation.
🔍🗻 The deposit consists of strata-bound magnetite-(apatite) bodies interbedded with undecided rocks, with evidence of replacement by kaolinite and albite.
🔬🌡️ Diagnostic rocks for magnetite-(apatite) systems include magnetite with large apatite crystals, apatite with dioxide and magnetite, and dioxide with apatite and magnetite.
🔍 The origin of magnetite-(apatite) rocks and their geological characteristics.
🔬 Insights from the El Laco system, including lava lake structures and intermingling of minerals.
⚗️ Geochemical analysis revealing high field strength elements, low titanium magnetite, and isotopic signatures indicating contamination.
🔍 Conventional oxygen isotopes cannot distinguish between magnetite precipitated from a melt or from a magmatic hydrothermal fluid.
🌡️ Triple oxygen isotopes suggest contamination with early Cambrian evaporite-rich sedimentary sequences.
💧 The lack of liquid water in the volcanic system indicates extensive crystal contamination.
🔑 The El Laco system exhibits similar behavior to other systems like fertile mercado and kiruna, where rhyolite contains water-rich magnetite.
🌋 In the coastal courtyard of Chile, magnetite blades with inclusions of iron-rich magnetite and titanite are found, along with glenoperoxin and fluorapatite.
🔬 Melt inclusions in magnetite and apatite rocks suggest complex interactions and residual melts, with different compositions and temperatures.
💧 Fluid separation and formation of gastric brines occur in the system, with chlorides fractionating into the aqueous fluid while sulfates remain in the melt.
🔒 Contamination of endocytic melts in the system may come from nearby sediments, potentially from both salted group and shallow marine ports.
❓ The presence of phosphorus and fluorine in the system plays a key role in the formation of magnetite apatite crystal systems.
🔍 Magnetite-(apatite) rocks have different origins than periphery-like or silicate rich melts.
🌋 Magnetic hepatite systems are formed from highly oxidized ultramafic melts with low silica content.
🧪 The late stages of crystallization of these melts exhibit a unique assemblage and high field strength elements.
🔑 The El Laco system lacks evaporitic sediments and consists mainly of oceanic sediments with a subducting slab.
💡 There is a variation in the amount of apatite in different ioa deposits, but experimental studies show that the mineral assemblages are similar.
🌋 The formation of ultramafic melts in the El Laco system is related to the interaction of antacidic melts with sediments in a zone of volcanic activity.
🧲 Magnetite-(apatite) rocks show a mass independent fractionation trend of oxygen-17, which is similar to evaporites.
🌍 The El Laco system suggests a mixing between magnetic magmatic magnetite and evaporites.
🔬 The chilean coastal range deposits and El Laco have similarities in the presence of scapelite, but differ in depth and genesis.
Private Sector vs. Public Sector | Short Clips
The Inside Story of ChatGPT’s Astonishing Potential | Greg Brockman | TED
Catherine McAuley
Der Römer-Check | Reportage für Kinder | Checker Tobi
CASCO THOR RAGNAROK PARA NIÑO DIY - Como hacer el Casco de Thor de papel, cartón Fácil (Reciclaje)
Los eventos que arrasarán en el 2021 por la covid | Pablo Foncillas