Geological Sciences, Minerals, and Mining Engineering Solutions

Exploration

Exploration is at the heart of geological science research. This research focuses on surveying and prospecting for minerals and materials. Geoscience, also known as Earth science, focuses on exploring and studying how the Earth and its materials work and evolve. Take a look below to find out how our analytical instruments can support you with this!

Exploration	Method	Sample	Application Note Title (Link)
Base metal mineralization - mineral distributions	UV/Vis/NIR/ SWIR	Base metal mineralization in The Great Basin of the Western United States (Seminal paper, basis for our ASD work in mining)	Reflectance Spectroscopy Applied to Exploration for Mineral Deposits and Geothermal Systems
Bauxite - exploration	UV/Vis/NIR/ SWIR	Bauxite, gibbsite Al(OH)3, boehmite γ-AlO(OH), and diaspore α-AlO(OH) with iron oxides goethite and hematite, plus kaolinite clay and small amounts of titanium dioxide	Overview of NIR in Bauxite Exploration and Mining
Chlorite minerals - identification	UV/Vis/NIR/ SWIR	White micas, chlorite group minerals. (Discussion of Halo and scalars from Halo)	Automated reflectance spectroscopy for deposit recovery - SEG 2014 poster
Drill core and cuttings mineralogy - mineral composition	UV/Vis/NIR/ SWIR	Clay Minerals, silicates, Zeolites, opal, calcite, and iron oxide (geothermal project)	Rapid Characterization of Drill Core and Cutting Mineralogy using Infrared Spectroscopy
Geochronology - mineral composition	UV/Vis/NIR/ SWIR	U/Pb geochronological investigations of the western Avalon Zone, Newfoundland	Late Neoproterozoic epithermal alteration and mineralization in the western Avalon Zone: A summary of mineralogical investigations and new U/Pb geochronological results
Mapping mineral deposits - absorption signatures	UV/Vis/NIR/ SWIR	Mineral deposits in Newfoundland and Labrador	Visible/Infrared Spectroscopy (VIRS) as a Research Tool in Economic Geology: Background and Pilot Studies from Newfoundland and Labrador
Mineral mapping – ground-truthing	UV/Vis/NIR/ SWIR	Copper ore, oil shale, and pulp manufacturing	Remote Sensing from 700km: Challenges and Potential
Mineralogy - mineral deposits	UV/Vis/NIR/ SWIR	Mineral deposits	Unveiling Mineralogical Information in Ore Deposits: The Use of Reflectance Spectroscopy for Mineral Exploration in South America
Phyllosilicate minerals - composition	UV/Vis/NIR/ SWIR	The dominant phyllosilicate minerals: smectites, illites, kaolinite, and chlorite in sedimentary systems	Automated reflectance spectroscopy for sedimentary basin characterization

Fossil fuels

Although fossil fuels are a declining resource, surveying and prospecting to find and extract them is still a vital part of our infrastructure and research. Check out our Energy and Power Engineering page to find out more about petrochemical analysis for the recycling of fuels and the reduction of pollutants. Otherwise, check out our application notes below to find out more about our solutions in fossil fuel research!

Fossil Fuels	Method	Sample	Application Note Title (Link)
Coal - elemental composition	XRF	Na2O, MgO, Al2O3, SiO2, P2O5, S, K2O, CaO, TiO2, MnO, Fe2O3, SrO, and BaO in unashed coal samples	Analysis of inorganic major and minor compounds in un-ashed coal samples prepared as pressed powder
Coal - mineralogical composition	XRD	Quartz(SiO2), kaolinite(Al2Si2O5(OH)4), calcite(CaCO3), dolomite(CaMg(CO3)2, Siderite(FeCO3), and anatase(TiO2)	Analysis of coal and related materials by XRD
Coal - sample preparation for ICP-OES elemental analysis	SPE	Thermal coal as fuel, metallurgical coal for steelmaking (lower S and P)	Characterization of Coal and its By-Products Using Borate Fusions and ICP-OES Analyses
Coal - sample preparation for ICP-OES elemental analysis	SPE	Coal, Coal Ash, and Coal Fly Ash	Characterization of Coal, Coal Ash, and Coal Fly Ash using Borate Fusion for ICP Analysis
Crude oil - Sulfur content	XRF	Sulfur in crude oil	Determination of sulfur content in crude oil according to ISO 8754
Drilling mud - particle size	LD	Barite, mud	Particle size analysis of drilling muds and components
Enhanced oil recovery - polymer particle size	DLS	(Surfactant and hydrogel polymers ) Polyacrylamide powder for Enhanced Oil Recovery (EOR)	Optimizing Small Volume DLS-Microrheology Measurements of Block Co-Polymers Used for Enhanced Oil Recovery Applications
Shale - mineral identification	UV/Vis/NIR/ SWIR	Clay mineralogy. Brief comparison of NIR, XRF, XRD, and QEMSCAN.	Use of NIR Spectroscopy in Mineral Identification in Shale

Mineralogy

All materials have their own composition. Mineralogy is the study of how the materials we use are made up and interact with each other – from rocks and ores to meteorites. Below, we’ve put together a few application examples of our mineral research solutions. Take a look to find out more!

Mineralogy	Method	Sample	Application Note Title (website link)
Base metal sulfides - elemental concentration	XRF	Cu, Zn, Pb, Ni, Co, Mo, Bi, Sb, Cd, Ag, Au, Se, and Te in sulfides	Analysis of Base Metal Sulfides using XRF and Fusion
Fluorspar - purity	XRF	CaF2 - Fluorspar	Purity check of fluorite (fluorspar, CaF2) prepared as fused beads
Manganese ore - elemental composition	XRF	Mn, Fe, Mg, Al, Si, P, S, Ca, and Ba in manganese ore	Analysis of manganese ore samples prepared as pressed pellets
Meteorite - crystallographic Phase identification	XRF	Olivine, (Mg, Fe)2SiO4, Ca-poor pyroxene CA) Si, Fe, Ca)Si2O6, Ca-rich pyroxene (diopside), CaMgSi2O6, spinel, MgAl2O4, anorthite, CaAl2Si2O8, and sodalite, Na8(Al6Si6O24)Cl2	Micro X-ray diffraction analysis on a meteorite
Meteorite - elemental composition	XRF	Meteorite: Si, Fe, Ni, Cr, Mn, Mo, Al, P, S, Cl, Na, Mg, K, Ca, Ti, Zn, and Zr	Elemental and phase analysis of a Northwest-Africa 2086 meteorite
Minerals - elemental composition	XRF	Minerals, Na2O2, MgO, Al2O3, SiO2, P2O5, K2O, CaO, TiO2, MnO, Fe2O3, Trace elements Rb, Sr, Y, Zr, and Nb	Analysis of major elements and selected trace elements in geological materials prepared as fused beads
Minerals - elemental composition	XRF	Elements in general geological materials	Analysis of major elements and selected trace elements in geological materials prepared as fused beads
Minerals - elemental composition	XRF	Mineral deposits, wide-range oxides, SiO2, TiO2, Al2O3, Fe2O3, Mn3O4, MgO, CaO, Na2O, K2O, P2O5, and SO3	Zetium - Analysis of iron ores using the WROXI wide-range oxides application
Minerals - elemental composition	XRF	Mineral deposits, wide-range oxides, SiO2, TiO2, Al2O3, Fe2O3, Mn3O4, MgO, CaO, Na2O, K2O, P2O5, and SO3	Zetium - Minerals analysis using WROXI standards
Minerals - elemental composition	XRF	Mineral deposits, wide-range oxides, SiO2, TiO2, Al2O3, Fe2O3, Mn3O4, MgO, CaO, Na2O, K2O, P2O5, SO3	WROXI - synthetic wide-range oxide standards for fused bead major and minor element analysis
Minerals - hydration behavior	XRD	Smectite, vermiculite-like clays, and some hydrous micas	XRD in transmission geometry with controlled temperature and relative humidity
Minerals - trace elements	XRF	Trace elements in minerals	Zetium - Trace element analysis of geological materials using Zetium and Pro-Trace
Olivines - phase identification, crystal structure refinement	XRD	Olivines, Pyroxenes, Multiferroic materials, and LiCrGe₂O₆	Investigation of the crystal structure of the pyroxene LiCrGe₂O₆
Rocks and soils - elemental composition	XRF	Cd, Sn, Sb, Cs, Ba, La, Le, and Nd in rocks and soils	Analysis of Cd, Sn, Sb, Cs, Ba, La, Le, and Nd in rocks and soils - improved detection limits using K-series lines
Sn-W-Pb Ore - mineralogical composition	XRD	Sn-W-Nb Ore	Mineralogical analysis of Sn-W-Nb ore
Sulfide deposits - mineral variations	UV/Vis/NIR/ SWIR	Sulfide deposits, Tulks Volcanic Belt, Central Newfoundland. Very good examples of how to use NIR in an exploration project.	Visible/Infrared Spectroscopy (VIRS) of Volcanogenic Massive Sulphide Hydrothermal Alteration Products, Tulks Volcanic Belt, Central Newfoundland: An Additional Exploration Technique?

Minerals processing

As technology improves and opens up exciting new possibilities, minerals processing has become increasingly automated. At Malvern Panalytical, we’re always coming up with new tools and equipment to do new things with slurries, grains, and sands. Take a look below to find out more about how these tools enable new minerals processing research!

Minerals Processing	Method	Sample	Application Note Title (Link)
Aluminosilicates - sample preparation for XRF	SPE	Sand and Aluminosilicates	Determination of the Composition of Sand and Aluminosilicates Using Borate Fusion for XRF Analysis
Calcium Carbonate - particle size	LD	Calcium carbonate	Using on-line particle size analysis to improve precipitated calcium carbonate production efficiency
Gypsum - particle size and shape	MDRS	Gypsum slurry	Analyzing gypsum slurries using the Morphologi automated image analysis system
Heavy metal sands - mineralogical composition	XRD	Heavy Metal Sands (Titanium, Zirconium, Thorium)	Analysis of heavy mineral sands for industrial process control
Limestone - elemental composition	XRF	Limestone: CaO, Al2O3, SiO2, MgO, and Fe2O3 with traces of Sr, K, Mn, P, S, Ti, and Pb	Quick quantification of major and trace compounds in limestone
Limestone - elemental composition	XRF	Limestone/dolomite	Fingerprinting of mineral mixtures
Limestone - elemental concentration	XRF	Limestone, Al2O3, SiO2, MgO, Fe2O3 with races MnO, P2O5, and Pb	Analysis of limestone prepared as pressed powder pellets
Limestone - sample preparation for XRF	SPE	Limestone, metals in lime and limestone	Determination of metals in lime and limestone using borate fusion for ICP-OES

Mining

As one of our primary industries, mining and extracting metals and fuels is at the heart of everything we do. Research and innovation in this field focuses on finding new ways to make processes such as extraction and refining more efficient. We’ve put together a selection of examples on how our analytical instruments can be part of your mining engineering solutions. Check them out below to discover more!

Mining	Method	Sample	Application Note Title (Link)
Ag and Au ore processing - elemental concentration	XRF	Ag and Au on activated carbons (from the pulp and leach processes in precious metal ore processing)	Analysis of Au and Ag on activated carbon
Ag in ore - elemental concentration	XRF	Ag in Ore	Analysis of Ag in Ore
Base metal sulfides - elemental concentration	XRF	Cu, Zn, Pb, Ni, Co, Mo, Bi, Sb, Cd, Ag, Au, Se, and Te in sulfide ores	Analysis of Base Metal Sulfides using XRF and Fusion
Bauxite - elemental composition	XRF	Ni, Zn, Ca, Cr, Mn, Fe, Co, Mg, Al, Si in Al2O3, Fe2O3 and TiO2	Analysis of major and minor elements in bauxite samples prepared as fused beads
Bauxite - elemental composition	XRF	Bauxite	Zetium - Analysis of bauxite using the WROXI wide-range oxides application
Bauxite - elemental composition	XRF	Bauxite (hydrated alumina, Al2O3, Fe2O3, Si, Fe, Ti + trace metal oxides)	Zetium - Quantification of major and minor elements in bauxite prepared as fused beads
Bauxite - grade control	XRD	Hematite, goethite, and magnetite, as well as the gangue minerals gibbsite Al(OH)3, kaolinite Al2Si2O5(OH)4, and quartz SiO2	Grade control of bauxites using X-ray diffraction (XRD)
Bauxite - sample preparation for XRF	SPE	Bauxite (hydrated alumina, Al2O3, Fe2O3 + trace metal oxides)	Inter-Position Repeatability Study on TheOx® Advanced Instrument Using Bauxite Type Samples Followed by XRF Analysis
Bauxite/Iron Ore - mineralogical composition	XRD	Iron Ore, Bauxite	X-ray diffraction applications for the mining industry
Chromium ores - sample preparation for ICP-OES	SPE	Chromic oxide (Cr2O3), in which the proportions of Mg2+, Fe2+ and Cr3+, Al3+, and Fe3+ may vary	Dissolution made easy using peroxide fusions for ICP-OES analyses for chromite ores, ferrochromes, and chromium slags
Copper Mining - agglomeration optimization	UV/Vis/NIR/ SWIR	Copper, acid, and water	Potential Cost Savings from Agglomeration Optimization in Copper Mining
Copper Ores - mineralogical analysis	UV/Vis/NIR/ SWIR	Copper Ores (good model results on a good-sized data set for quantitative mineralogy)	Rapid Mineralogical Analysis of Copper Ores
Copper ore - mineralogical composition	XRD	23 minerals in copper ore including chalcopyrite CuFeS2, cuprite Cu2O, tenorite CuO, and sulfates such as brochantite Cu4[(OH)6(SO4)] and serpierite Ca(Cu, Zn)4(SO4)2(OH)6•3H2O	Mineralogical analysis of copper ore
Iron ore - elemental composition	XRF	Na, Mg, Al, Si, P, S, K, Ca, Ti, Cr, V, Mn, Fe, Ni, Cu, and Zn ores in iron ore	Analysis of iron samples prepared as fused beads
Iron ore - elemental composition	XRF	Fe2O3 containing Na, Mg, Al, Si, P, S, K, Ca, Ti, V, Cr, Mn, Fe, Cu, Zn, and As	Faster analysis of iron ores with Zetium and SumXcore technology
Iron ore – grading general article (not specific to our product)	UV/Vis/NIR/ SWIR	Iron ore samples from Noamnudi mines, Jharkhand, India (Hematite, Magnetite, Limonite, and Siderite)	Hyperspectral Radiometry to Estimate the Grades of Iron Ores of Noamnudi, India - A Preliminary Study
Iron ore - mineralogical composition	XRD	Iron ore	Mineralogical analysis of iron ore
Iron ore - mineralogical composition	XRD	Iron ore, goethite, hematite, gibbsite-kaolinite-quartz	XRD for grade control of iron ores
Iron ore - oxide content and basicity	XRD	FeO content and basicity	Analysis of iron sinter by X-ray diffraction reduces CO2 emissions
Iron Ore - sample preparation for elemental analysis	SPE	NaT flux to fuse iron ore	Using sodium tetraborate (NaT) flux to prepare iron ores by fusion for XRF analysis
Iron Ore - sample preparation for elemental analysis	SPE	Iron Ore, fused beads using Borate Fusion	ISO 9516-1 Simplified Borate Fusion & WDXRF Analytical Method for Iron Ores Analysis Including Exploration Samples
Nickel ore - elemental composition	XRF	Ni, Co, Mg, Fe, Mn, Zn, Al, Cr, Ca, and Si in nickel ore	Analysis of nickel ore samples prepared as fused beads
Phosphates - elemental and mineralogical composition	XRD	Mining for Phosphates - Yara's Mine in Finland	A tailor-made solution for Yara - customer story
Phosphates - elemental composition	XRF	High phosphate minerals, production of phosphoric acid - including Fe2O3, Al2O3, and SiO2	Zetium - Analysis of phosphates using the WROXI wide-range oxides application
Rock face - mineral libraries	UV/Vis/NIR/ SWIR	Model Mine face (rock face)	On the Development of a Hyperspectral Library for Autonomous Mining Systems

Abkürzungen erklärt

Unsere Produkte und Technologien werden auf den Produktseiten beschrieben. Nachstehend finden Sie eine Kurzübersicht über die von unseren Geräten gemessenen Eigenschaften einschließlich der Messbezeichnung und ihrer Abkürzung. Klicken Sie auf die einzelnen Methoden, um mehr darüber zu erfahren!

Abkürzung	Methodenname	Gerät(e)	Gemessene Eigenschaft
DLS	Dynamische Lichtstreuung	Zetasizer	Molekülgröße, hydrodynamischer Radius R_H, Partikelgröße, Größenverteilung, Stabilität, Konzentration, Agglomeration
ELS	Elektrophoretische Lichtstreuung	Zetasizer	Zetapotenzial, Partikelladung, Suspensionsstabilität, Proteinmobilität
ITC	Isothermische Titrationskalorimetrie	MicroCal ITC	Bindungsaffinität, Thermodynamik molekularer Reaktionen in Lösung
DDK	Dynamische Differenzkalorimetrie	Microcal DSC	Denaturierung (Entfaltung) von großen Molekülen, Stabilität von Makromolekülen
GCI	Gittergekoppelte Interferometrie	Creoptix WAVEsystem	Bindungskinetik und -affinität in Echtzeit, markerfrei mit Fluidik
IMG	Automatisierte Bildanalyse	Morphologi 4	Bildgebung von Partikeln, automatisierte Form- und Größenmessung
MDRS	Morphologically-Directed Raman-Spektroskopie	Morphologi 4-ID	Bildgebung von Partikeln, automatisierte Form- und Größenmessung, chemische Identifizierung und Verunreinigungserkennung
LD	Laserbeugung	Mastersizer Spraytec Insitec Parsum	Partikelgröße, Größenverteilung
NTA	Nanopartikel-Tracking-Analyse (NTA)	NanoSight	Partikelgröße, Größenverteilung und Konzentration
SEC oder GPC	Größenausschluss-Chromatographie/ Gelpermeationschromatographie	OMNISEC	Molekülgröße, Molekulargewicht, oligomerer Zustand, Polymer- oder Proteingröße und Molekularstruktur
SPE	Probenvorbereitung durch Schmelzaufschluss	Le Neo LeDoser Eagon 2 The OxAdvanced M4 rFusion	Schmelztabletten-Probenvorbereitung für RFA, Peroxidlösungszubereitungen für ICP, Flussmittelwägung für die Schmelztablettenherstellung
UV/Vis/NIR/ SWIR	Ultraviolett-/Sichtbares Licht-/Nahinfrarot-/Kurzwellen-Infrarotspektrometrie	LabSpec FieldSpec TerraSpec QualitySpec	Materialerkennung und -analyse, Feuchtigkeit, Mineral- und Kohlenstoffgehalt. Bodenuntersuchungen für luft- und satellitengestützte spektroskopische Verfahren.
PFTNA	Aktivierung mit gepulsten schnellen thermischen Neutronen (Pulsed Fast and Thermal Neutron Activation, PFTNA)	CNA	Inline-Elementaranalyse
XRD-C	Röntgendiffraktion (Kristallographie)	Aeris Empyrean	Verfeinerung der molekularen Kristallstruktur, Identifizierung und Quantifizierung der kristallinen Phase, Verhältnis zwischen kristallin und amorph, Analyse der Kristallitgröße
XRD-M	Röntgendiffraktion (Mikrostruktur)	Empyrean X’Pert³ MRD(XL)	Eigenspannung, Textur
XRD-CT	Röntgenabsorptionsbildgebung durch Computertomographie	Empyrean	3D Bildgebung von Feststoffen, Porosität und Dichte
SAXS	Kleinwinkel-Röntgenstreuung	Empyrean	Nanopartikel, Größe, Form und Struktur
GISAXS	Kleinwinkel-Röntgenstreuung unter streifendem Einfall	Empyrean	Nanostrukturierte Dünnschichten und Oberflächen
HR-XRD	Hochauflösende Röntgenbeugung	Empyrean X’Pert³ MRD(XL)	Dünnschichten und epitaktische Mehrfachschichten, Zusammensetzung, Dehnung, Dicke, Qualität
XRR	Röntgenreflektometrie	Empyrean X’Pert³ MRD(XL)	Dünnschichten und Oberflächen, Schichtdicke, Oberflächen- und Grenzflächenrauheit
RFA	Röntgenfluoreszenz	Epsilon Zetium Axios FAST 2830 ZT	Elementzusammensetzung, Elementkonzentration, Spurenelemente, Verunreinigungserkennung