Interested in improving your materials science research and engineering knowledge with our analytical solutions? Whether you’re a student, a researcher, or a professor, we’ve got a wide range of useful articles on the most relevant application examples of our ceramics, metals, and polymer research solutions.
The materials researched and analytical equipment used often overlaps with Chemistry and Applied Chemistry, Electronic Engineering and Semiconductor Materials, and Physics and Applied Physics, so you can also find useful information on those pages. The method abbreviations are explained at the bottom of this page.
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If you're working on ceramics, paints or inks, smart coatings or polymers, you might like reading about this range of analytical solutions for paints and coatings. It includes an introduction to particle measurement for pigments, elemental and phase analysis, dispersion stability, polymer molecular weight characterization, and more...
Ceramics
Ceramics can have many different structures and compositions, and they may contain any element from the periodic table. Ceramics are also studied in Chemistry and Applied Chemistry for synthesis and chemical characterization. Here are just a few examples of how our instruments are used in ceramics research. Take a look to find out more!
Ceramics | Method | Sample | Application Note Title (Link) |
|---|---|---|---|
Abrasives - particle shape and size | IMG | Diamond and Abrasive grains (A2O3), (SiC), SG, and CBN | Particle shape characterization for abrasive quality control |
Colloidal processing - Zeta potential | ELS | Zirconia (m-ZrO2), Poly(ethylene glycol) (PEG), and ammonium poly(methacrylate) (APMA) in dilute KNO3 | The importance of zeta potential in ceramic processing (2) Zirconia |
Inclusions - elemental analysis | XRF | Mg, Al, Si, P, S, K, Ca, Ti, Fe, Zn, Zr, and Na | Practical small spot mapping. Analysis of a ceramic inclusion using SumXcore technology |
Nanomaterials - elemental analysis, trace elements | XRF | Ceramic nanomaterials (TiO2 and ZnO) with catalyst residues Al, Si, P, S, Cl, Fe, Zr, Nb, and Pb | Easy, cost-effective, and non‑destructive quantification of ceramic nanomaterials |
Polishing slurries - particle shape and size | IMG | Chemical-Mechanical Polishing (CMP) slurries, SiO2 or Al2O3 particles | |
Polishing slurries - Zeta potential | ELS | Chemical-Mechanical Polishing (CMP) slurries, SiO2 or Al2O3 particles | Zeta Potential Measurement of Highly Concentrated CMP Slurry Dispersions |
Processing - Zeta potential | ELS | α-alumina, Poly(ethylene glycol) (PEG), and ammonium poly(methacrylate) (APMA) | The importance of zeta potential in ceramic processing (1) Alumina |
Refractory materials - particle size | LD | Refractory suspensions (alumina, bauxite, chromite, dolomite, magnesite, silicon carbide, and zirconia mixes) | Using particle size distribution measurements to control the properties of refractory materials |
Spray-dried powders - particle shape and size | IMG | Al2O3 and W-/Ni-/Fe-based spray-dried particles | Using the Morphologi to evaluate ceramic granules produced by spray drying |
Metals
Despite its ancient origins, metals research and the study of metals and their refining (Metallurgy) is still advancing today. In particular, additive manufacturing is a hot topic for novel manufacturing of metallic and composite components. Understanding metals also requires an understanding of mining and refining – you can find out more about this on our Geological Sciences, Minerals and Mining page. Below, you can find application notes for our solutions in metals research – enjoy exploring!
Metals | Method | Sample | Application Note Title (Link) |
|---|---|---|---|
Aluminum alloy production - elemental composition | XRF | Aluminum Alloys | |
Aluminum alloys - elemental composition | XRF | Mg, Al, Si, Ti, Mn, Fe, Ni, Cu, Zn, Al-Si, and Al-Mg alloys | |
Cadmium in lead and brass - elemental analysis | XRD | Cd and Pb in Brass | Analysis of Cd and Pb in Brass for RoHS, WEEE and ELV compliance |
Cast iron - carbon content | XRF | C, Si, P, S, Ti, V, Cr, Mn, Ni, Nb, and Mo in cast iron | |
Cast iron - elemental analysis | XRF | Cast Iron: Fe, Si, Mn, P, S, Cr, Mo, Ni, Cu, Ti, V, Al, and Mg | |
Chromium coatings on steel - layer thickness and composition | XRF | Cr coatings on steel | |
Chromium/zinc coatings on steel - layer thickness and composition | XRF | Cr/Zn coatings on steel | |
Copper base alloys - elemental concentration | XRF | Copper Base Alloys: Sn, Zn, Ni, Al, and Pb alloyed in Cu | |
Copper sheet - microstructure, crystallographic texture | XRD-M | Copper sheet (rolled) | Quantification texture analysis. Preferred orientation studies on rolled copper |
Ferrochrome - elemental analysis | XRF | Ferroalloys, Ferrochrome, Fe, and Cr | Analysis of FeCr alloys as fused beads using the Zetium XRF spectrometer |
Ferrosilicon alloys - elemental analysis | XRF | Fe, Si, Mg, Al, P, Ca, Ti, Cr, Mn, Ni, and Cu | Zetium - Analysis of major, minor, and trace elements in ferrosilicon alloys |
Ferrosilicon alloys - elemental analysis | SPE | Ferrosilicon Alloys, Ferroalloys, silicon, and iron | The Preparation of Ferrosilicon Alloys Samples for XRF analysis |
Ferrosilicon manganese - elemental analysis | XRF | Ferroalloys, FeSiMn alloys | Zetium - Analysis of major, minor, and trace elements in FeSiMn alloys |
Granulates - particle size | LD | Metal granulates, foil waste | |
Inconel – additive manufacturing part quality | XRD
| Metal powder and completed 3D additive manufactured components | Additive Manufacturing of Inconel 718: characterizing parts and powders |
Low alloy steel - elemental analysis | XRF | Low-Alloy Steel, high strength | |
Metals sample preparation example - Fusion for XRF | SPE | Ag, Zn, Pb, Cu, and S | |
Ni coatings on steel - layer thickness and composition | XRF | Ni coatings on steel | |
NiFeCo alloys - elemental analysis | XRF | NiFeCo alloys: Ni, Fe, Co, (Al, Si, P, S, Ti, V, Cr, Mn, Cu, Zr, Nb, Mo, Ta, and W) | Zetium - NiFeCo-FP - analysis of steels, high-temperature alloys, and super alloys |
Powder, additive manufacturing - overview | LD | Metal Powders | |
Powder, atomization - particle size and shape | IMG | Atomized stainless steel | Comparing metal powders from different atomization processes using automated image analysis |
Refining Iron (blast furnace slag) - elemental composition | XRF | MgO, Al2O3, SiO2, P2O5, S, K2O, CaO, TiO2, MnO, and Fe in slag samples | Quick and precise analysis of major and minor components of slag samples prepared as pressed pellets |
Refining Iron (direct reduced) - phase identification and quantification | XRD | Iron Ore, Direct Reduced Iron, sponge iron | |
Refining, Alumina bath - phase identification and quantification | XRD | Aluminum, alumina | |
Refining, Alumina powder - particle size | LD | Alumina powder | Using real-time particle size analysis to optimize aluminum smelting |
Refining, Iron sinter - phase identification and quantification | XRD | FeO basicity - oxides | Analysis of iron sinter by X-ray diffraction reduces CO2 emissions |
Refining, Oxides - elemental composition | XRF | Oxides generally | Synthetic standard solution WROXI for the analysis of a wide range of oxides |
Solder particles - particle size and shape | IMG | Solder Particles | QA/QC characterization of solder particles using the Morphologi G3 automated image analysis system |
Stainless Steel production | XRF | Stainless Steel, C, Si, P, S, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, As, and Mo | |
Steel - crystallographic phase quantification | XRD | Steel and alloys of steel | |
Steel - elemental analysis with spatial resolution | XRF | Ni, Cr, Mn, Mo, Si, and Fe | Small spot mapping – In situ elemental analysis of steel using SumXcore technology |
Steel slab - process control, elemental analysis | XRF | Slab steel formed from continuous casting, Fe, Ni, Cr, and Mo as markers for segregation | |
Tin coatings on steel - layer thickness and composition | XRF | Tin (Sn) coatings on Steel | |
Titanium alloys - elemental composition | XRF | Titanium Alloys | |
Titanium/Tin coatings on steel - layer thickness and composition | XRF | Titanium (Ti)/Tin (Sn) coatings on steel | Zetium - Analysis of thin layers of Ti/Sn coatings on steel using Stratos |
Tool steel - crystallographic phase quantification | XRD | Tool steel - retained austenite | Quantitative determination of retained austenite (RA) - ASTM E975 |
Tool steel - elemental analysis | XRF | Tool steel - Cr, Mo, Co, V, and W | |
Weld analysis - elemental analysis | XRF | Fe, Nb, Ni, Mo, and Mn | Small spot mapping - In situ characterization of weld solidification using X-ray fluorescence |
Zirconium alloy sheet - microstructure, crystallographic texture | XRD-M | Zr, Fe, and Ni - sheet used in nuclear reactor construction | |
Zn coatings on steel - layer thickness and composition | XRF | Zn coatings on Steel |
Polymers
Polymers are studied for synthesis and chemical characterization in Chemistry and Applied Chemistry, as well as for recycling along with plastics. Using polymers in Materials Science and Engineering requires an understanding of their structure-property relationships. Below, you can explore how our analytical instruments can help with polymer research. Take a look to find out more!
Polymers | Method | Sample | Application Note Title (Link) |
|---|---|---|---|
Aluminum coatings on polymer film - elemental analysis | XRF | Al coatings on thin polymer films | |
Beads - particle size and shape | MDRS | Polymer beads | |
Catalyst residues - elemental analysis | XRF | Catalyst residues in polymer defects (aluminum, titanium, phosphorus, and calcium) | Fast small spot elemental mapping of defects in polymeric samples |
Flow Injection - molecular weight, intrinsic viscosity | GPC | Polypropylene (pp), ethylene-propylene rubber (EPR), and in xylene | Flow Injection Polymer Analysis for the measurement of Xylene Solubles |
Inclusions in molded polymer - elemental analysis | XRF | Titanium (Ti) in polypropylene (PP) and high-density polyethylene (HDPE) | |
Paper - elemental analysis | XRF | Silicon on paper | Quick and accurate determination of silicon on paper in only 30 seconds |
Paper-making fluids - Zeta potential | ELS | Stocks and additives, pulp, effluent, (Alum, Starch, and ash) | |
Polycaprolactone - molecular weight | GPC | Polycaprolactone (PCL) | |
Polyethylene and polypropylene - elemental analysis | XRF | Polyethylene (PE) and polypropylene (PP) | Rapid and easy identification of polyolefin types using FingerPrint software |
Polyethylene and polypropylene, trace elements - elemental analysis | XRF | Mg, Al, P, Ca, Ti, and Zn in polymers (polyethylene and polypropylene) | Zetium - Trace element analysis of Mg, Al, P, Ca, Ti, and Zn in polymers using Zetium |
Polyethylene stretched - crystal structure analysis | XRD | Polyethylene (PE) stretched | |
Polyethylene, trace elements - elemental analysis | XRF | Cr, Ni, Cu, Zn, As, Br, Cd, Ba, Hg, and Pb in polyethylene | |
Polymers for fire protection - degradation, bromination | GPC | Linear polystyrene and brominated polystyrene | |
Polymers for fire protection - elemental analysis | XRF | Halogenated compounds (for example, tetrabromobisphenol) and antimony trioxide in Acrylonitrile butadiene styrene (ABS) resins | Zetium - Analysis of flame retardants (Sb and Br) in Acrylonitrile Butadiene Styrene (ABS) resins |
Polymers, optimization for end-use – molecular weight, intrinsic viscosity | GPC | Polystyrene (PS), polymethyl methacrylate (PMMA), polycarbonate (PC), and polyvinylchloride (PVC) | |
Polymers, toxins, and safety - elemental analysis | XRF | Lead, cadmium, mercury, chromium, and bromine in polymers | Polymer analysis in accordance with ASTM F2617-15 using TOXEL and RoHS Calibration standards |
Polyolefins, toxins, and safety - elemental analysis | XRF | Cr, Br, Cd, Pb, Hg, As, Sb, Sn, and Zn in polyolefins | RoHS-2 small spot analysis of polyolefins in compliance with ASTM F2617-15 |
Polyolefins, toxins, and safety - elemental analysis | XRF | Cr, Br, Cd, Pb, Hg, As, Sb, Sn, and Zn in polyolefins | ROHS-3/WEEE/ELV analysis of polyolefins in accordance with ASTM F2617-15 |
Polypropylene film - crystal lattice expansion with temperature | XRD | Polypropylene film | |
Polyvinyl chloride, toxins, and safety - elemental analysis | XRF | Cd and Pb in polyvinyl chloride (PVC) | |
Recycling - elemental analysis | XRF | RoHS elements: Cr, Br, Hg, Pb, and Cd in Acrylonitrile-Butadiene-Styrene (ABS) and Polyvinyl Chloride (PVC) | RoHS & WEEE compliance: Analysis of Poly Vinyl Chloride and Acrylonitrile-Butadiene Styrene polymers |
略語解説
当社の製品と技術については、製品ページを参照してください。以下では、当社の装置で測定された特性、測定名とその略称を簡単に参照できます。各メソッドをクリックすると、詳細が表示されます。
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略語 |
メソッド名 |
装置 |
測定された特性 |
|---|---|---|---|
|
DLS |
ゼータサイザー |
分子サイズ、流体力学的半径RH、粒子サイズ、粒度分布、安定性、濃度、凝集 |
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ELS |
ゼータサイザー |
ゼータ電位、粒子電荷、懸濁液の安定性、タンパク質電気泳動移動度 |
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ITC |
MicroCal ITC |
結合親和性、溶液中の分子反応の熱力学 |
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.dsc |
Microcal DSC |
大きな分子の変性(アンフォールド)、高分子の安定性 |
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GCI |
Creoptix WAVEsystem |
リアルタイムの結合反応速度と親和性、流体工学によるラベルフリー |
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IMG |
モフォロギ 4
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粒子の画像処理、形状、サイズの自動測定
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MDRS |
モフォロギ4-ID |
粒子の画像処理、形状、サイズの自動測定、化学的同定、汚染物質の検出 |
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LD |
マスターサイザー スプレーテック インシテック Parsum |
粒子サイズ、粒度分布 |
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NTA |
ナノサイト |
粒子サイズ、粒度分布、濃度 |
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SEC または GPC |
OmniSEC |
分子サイズ、分子量、オリゴマー状態、ポリマーまたはタンパク質のサイズ、分子構造 |
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SPE |
Le Neo LeDoser Eagon 2 The OxAdvanced M4 rFusion |
XRF用溶融ビーズ試料の調製、ICP用過酸化物溶液の調製、ビーズ作製用のフラックス計量 |
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UV/Vis/NIR/ SWIR |
LabSpec FieldSpec TerraSpec QualitySpec |
材料識別と分析、水分、鉱物、炭素の含有量。航空および衛星分光分析技術の地上検証。 |
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PFTNA |
CNA |
インライン元素分析 |
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XRD-C |
Aeris Empyrean |
分子結晶構造の精製、 結晶相の同定と定量化、結晶対非結晶比、結晶子径分析 |
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XRD-M |
Empyrean X’Pert3 MRD(XL) |
残留応力、テクスチャ |
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XRD-CT |
Empyrean |
固体、気孔率、密度の3D画像処理 |
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SAXS |
Empyrean |
ナノ粒子、サイズ、形状、構造 |
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GISAXS |
Empyrean |
ナノ構造の薄膜と表面 |
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HR-XRD |
Empyrean X’Pert3 MRD(XL) |
薄膜およびエピタキシャル多層、組成、ひずみ、厚さ、品質 |
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XRR |
Empyrean X’Pert3 MRD(XL) |
薄膜と表面、膜厚、表面、界面粗さ |
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XRF |
Epsilon Zetium Axios FAST 2830 ZT |
元素組成、元素濃度、微量元素、汚染物質の検出 |