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Explains the global physical and chemical processes that determine climate on any planet or major planetary satellite. ... Along the way, readers learn the equations that describe how climate processes work, including atmospheric escape, convection, radiative heat transfer, condensation and evaporation, and the dynamics of rotating fluids.
Planetary meteorology --- Climatology --- Planetary meteorology. --- Climatology. --- 551.5 --- Meteorology --- 551.58 Climatology --- 551.5 Meteorology --- Planets --- Climate --- Climate science --- Science of climate --- 551.58 --- Climate sciences --- Atmospheric science --- Earth. --- Great Dark Spot. --- Great Red Spot. --- Hadley cell. --- Jupiter. --- Mars. --- Mercury. --- Neptune. --- Saturn. --- Titan. --- Uranus. --- Venus. --- ancient rivers. --- anti-greenhouse effect. --- atmosphere. --- atmospheric chemistry. --- bulk composition. --- carbon dioxide. --- chaos. --- climate change. --- climate evolution. --- climate. --- clouds. --- condensation. --- convection. --- dust storms. --- eddies. --- energy transfer. --- evaporation. --- exoplanets. --- extrasolar planets. --- extraterrestrial life. --- geostrophic balance. --- giant planets. --- giant storms. --- greenhouse effect. --- greenhouse warming. --- higher hydrocarbons. --- hot air ballooning. --- hydrologic cycle. --- instability. --- lakes. --- lightning. --- methane. --- momentum transfer. --- moon. --- oceans. --- planetary climate. --- planetary rotation. --- planetary satellite. --- planets. --- radial velocity method. --- radiation. --- rotating fluids. --- rotation. --- runaway greenhouse. --- seasonal cycles. --- solar composition. --- solar system. --- superrotation. --- temperature. --- terraforming. --- volatile gases. --- water. --- weather forecasting. --- weather. --- winds. --- zonal jets.
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During the last decade, software developments in Scanning Electron Microscopy (SEM) provoked a notable increase of applications to the study of solid matter. The mineral liberation analysis (MLA) of processed metal ores was an important drive for innovations that led to QEMSCAN, MLA and other software platforms. These combine the assessment of the backscattered electron (BSE) image to the directed steering of the electron beam for energy dispersive spectroscopy (EDS) to automated mineralogy. However, despite a wide distribution of SEM instruments in material research and industry, the potential of SEM automated mineralogy is still under-utilised. The characterisation of primary ores, and the optimisation of comminution, flotation, mineral concentration and metallurgical processes in the mining industry by generating quantified data, is still the major application field of SEM automated mineralogy. However, there is interesting potential beyond these classical fields of geometallurgy and metal ore fingerprinting. Slags, pottery and artefacts can be studied in an archeological context for the recognition of provenance and trade pathways; soil, and solid particles of all kinds, are objects in forensic science. SEM automated mineralogy allows new insight in the fields of process chemistry and recycling technology.
Research & information: general --- Zr-REE-Nb deposits --- alkaline rocks --- automated mineralogy --- Khalzan Buregtei --- automated scanning electron microscopy --- QEMSCAN® --- trace minerals --- gold --- REE minerals --- REE carbonatite ore --- comminution --- multi-stage flotation --- EDX spectra --- MLA --- mineral processing --- iron ore --- Kiruna --- Raman spectroscopy --- magnetite --- hematite --- scanning electron microscopy (SEM) --- automated quantitative analysis (AQM) --- spectrum quantification --- signal deconvolution --- fault gouge --- 200-nm resolution --- grain size distribution --- Ikkattup nunaa --- mineral maps --- submicrometer --- automated quantitative mineralogy (AQM) --- scanning electron microscopy --- ZEISS Mineralogic --- Fiskenæsset complex --- Feret angle --- element concentration map --- visualization --- mineral association --- bulk composition --- grain size --- waste of electrical and electronic equipment --- X-ray computed tomography --- mineral liberation analysis --- indicator minerals --- heavy mineral concentrates --- till sampling --- VMS --- Izok Lake --- sewage sludge ashes (SSA) --- phosphate --- recycling --- recovery --- SEM-automated mineralogy --- mineral liberation analysis (MLA) --- scanning electron microscope --- raw materials --- resource technology --- granular material --- petrology --- n/a
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During the last decade, software developments in Scanning Electron Microscopy (SEM) provoked a notable increase of applications to the study of solid matter. The mineral liberation analysis (MLA) of processed metal ores was an important drive for innovations that led to QEMSCAN, MLA and other software platforms. These combine the assessment of the backscattered electron (BSE) image to the directed steering of the electron beam for energy dispersive spectroscopy (EDS) to automated mineralogy. However, despite a wide distribution of SEM instruments in material research and industry, the potential of SEM automated mineralogy is still under-utilised. The characterisation of primary ores, and the optimisation of comminution, flotation, mineral concentration and metallurgical processes in the mining industry by generating quantified data, is still the major application field of SEM automated mineralogy. However, there is interesting potential beyond these classical fields of geometallurgy and metal ore fingerprinting. Slags, pottery and artefacts can be studied in an archeological context for the recognition of provenance and trade pathways; soil, and solid particles of all kinds, are objects in forensic science. SEM automated mineralogy allows new insight in the fields of process chemistry and recycling technology.
Zr-REE-Nb deposits --- alkaline rocks --- automated mineralogy --- Khalzan Buregtei --- automated scanning electron microscopy --- QEMSCAN® --- trace minerals --- gold --- REE minerals --- REE carbonatite ore --- comminution --- multi-stage flotation --- EDX spectra --- MLA --- mineral processing --- iron ore --- Kiruna --- Raman spectroscopy --- magnetite --- hematite --- scanning electron microscopy (SEM) --- automated quantitative analysis (AQM) --- spectrum quantification --- signal deconvolution --- fault gouge --- 200-nm resolution --- grain size distribution --- Ikkattup nunaa --- mineral maps --- submicrometer --- automated quantitative mineralogy (AQM) --- scanning electron microscopy --- ZEISS Mineralogic --- Fiskenæsset complex --- Feret angle --- element concentration map --- visualization --- mineral association --- bulk composition --- grain size --- waste of electrical and electronic equipment --- X-ray computed tomography --- mineral liberation analysis --- indicator minerals --- heavy mineral concentrates --- till sampling --- VMS --- Izok Lake --- sewage sludge ashes (SSA) --- phosphate --- recycling --- recovery --- SEM-automated mineralogy --- mineral liberation analysis (MLA) --- scanning electron microscope --- raw materials --- resource technology --- granular material --- petrology --- n/a
Choose an application
During the last decade, software developments in Scanning Electron Microscopy (SEM) provoked a notable increase of applications to the study of solid matter. The mineral liberation analysis (MLA) of processed metal ores was an important drive for innovations that led to QEMSCAN, MLA and other software platforms. These combine the assessment of the backscattered electron (BSE) image to the directed steering of the electron beam for energy dispersive spectroscopy (EDS) to automated mineralogy. However, despite a wide distribution of SEM instruments in material research and industry, the potential of SEM automated mineralogy is still under-utilised. The characterisation of primary ores, and the optimisation of comminution, flotation, mineral concentration and metallurgical processes in the mining industry by generating quantified data, is still the major application field of SEM automated mineralogy. However, there is interesting potential beyond these classical fields of geometallurgy and metal ore fingerprinting. Slags, pottery and artefacts can be studied in an archeological context for the recognition of provenance and trade pathways; soil, and solid particles of all kinds, are objects in forensic science. SEM automated mineralogy allows new insight in the fields of process chemistry and recycling technology.
Research & information: general --- Zr-REE-Nb deposits --- alkaline rocks --- automated mineralogy --- Khalzan Buregtei --- automated scanning electron microscopy --- QEMSCAN® --- trace minerals --- gold --- REE minerals --- REE carbonatite ore --- comminution --- multi-stage flotation --- EDX spectra --- MLA --- mineral processing --- iron ore --- Kiruna --- Raman spectroscopy --- magnetite --- hematite --- scanning electron microscopy (SEM) --- automated quantitative analysis (AQM) --- spectrum quantification --- signal deconvolution --- fault gouge --- 200-nm resolution --- grain size distribution --- Ikkattup nunaa --- mineral maps --- submicrometer --- automated quantitative mineralogy (AQM) --- scanning electron microscopy --- ZEISS Mineralogic --- Fiskenæsset complex --- Feret angle --- element concentration map --- visualization --- mineral association --- bulk composition --- grain size --- waste of electrical and electronic equipment --- X-ray computed tomography --- mineral liberation analysis --- indicator minerals --- heavy mineral concentrates --- till sampling --- VMS --- Izok Lake --- sewage sludge ashes (SSA) --- phosphate --- recycling --- recovery --- SEM-automated mineralogy --- mineral liberation analysis (MLA) --- scanning electron microscope --- raw materials --- resource technology --- granular material --- petrology --- Zr-REE-Nb deposits --- alkaline rocks --- automated mineralogy --- Khalzan Buregtei --- automated scanning electron microscopy --- QEMSCAN® --- trace minerals --- gold --- REE minerals --- REE carbonatite ore --- comminution --- multi-stage flotation --- EDX spectra --- MLA --- mineral processing --- iron ore --- Kiruna --- Raman spectroscopy --- magnetite --- hematite --- scanning electron microscopy (SEM) --- automated quantitative analysis (AQM) --- spectrum quantification --- signal deconvolution --- fault gouge --- 200-nm resolution --- grain size distribution --- Ikkattup nunaa --- mineral maps --- submicrometer --- automated quantitative mineralogy (AQM) --- scanning electron microscopy --- ZEISS Mineralogic --- Fiskenæsset complex --- Feret angle --- element concentration map --- visualization --- mineral association --- bulk composition --- grain size --- waste of electrical and electronic equipment --- X-ray computed tomography --- mineral liberation analysis --- indicator minerals --- heavy mineral concentrates --- till sampling --- VMS --- Izok Lake --- sewage sludge ashes (SSA) --- phosphate --- recycling --- recovery --- SEM-automated mineralogy --- mineral liberation analysis (MLA) --- scanning electron microscope --- raw materials --- resource technology --- granular material --- petrology
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