Learn to interpret XRF results: understand qualitative vs. quantitative analysis, matrix effects, and key limitations for accurate material characterization.
Discover how XRF testing provides fast, non-destructive elemental analysis for quality control, compliance, and material verification across industries.
Micro-XRF has no required sample mass. Learn how spot size, surface quality, and sample preparation define analysis success for accurate elemental mapping.
Explore the analytical range of XRF measurement, from ppm to 100%, and learn how element type, sample matrix, and instrument choice affect detection limits.
XRF offers rapid, multi-element analysis of solids, while AAS provides high-sensitivity, single-element measurement in liquids. Learn which is best for your lab.
Explore alternatives to XRF like ICP, OES, and LIBS. Compare sensitivity, sample prep, and cost to find the best elemental analysis method for your needs.
Learn how qualitative XRF analysis identifies elements in a sample using unique X-ray fingerprints. Essential for material science and quality control.
Learn how XRF detects trace elements, its ppm-level limits, and when to choose it over ICP-MS for material analysis. Understand the key factors affecting detection.
Discover the key benefits of handheld XRF analyzers: portability for on-site use, rapid non-destructive testing, and immediate material identification.
Understand the key differences between XRF (elemental analysis) and XRD (crystalline structure analysis) to select the right technique for your material characterization needs.
Learn the key differences between XRF (elemental composition) and XRD (crystalline structure) to choose the right analytical technique for your materials.
Explore how XRF forensics non-destructively analyzes gunshot residue, glass, paint, and soil to link suspects to crime scenes with rapid, on-site elemental analysis.
Learn how XRF thickness measurement works using X-ray fluorescence to analyze coating thickness without contact. Ideal for quality control of metallic platings.
Explore the diverse applications of FTIR spectroscopy for material identification, quality control, and analysis in pharmaceuticals, forensics, and more.
Learn the 3-stage FTIR analysis process: background scan, sample prep, and data acquisition. Master ATR, KBr pellets, and salt plates for accurate molecular identification.
Learn the essential materials for FTIR analysis, from IR-transparent salt plates to ATR crystals, for accurate sample preparation and reliable results.
Learn the best methods for FTIR sample preparation for solids, liquids, and gases. Compare KBr pellets, ATR, and transmission cells to get high-quality results.
Discover how KBr pellets enable transparent sample preparation for FTIR, ensuring accurate chemical fingerprinting of solid materials without interference.
FTIR reads molecular vibrations by measuring infrared light absorption, providing a unique chemical fingerprint for material identification and analysis.
Discover why FTIR replaced traditional IR with superior speed, sensitivity, and accuracy. Learn the key differences in instrumentation and performance.
Explore FTIR microspectroscopy for IR imaging of biological samples. Learn how to overcome water interference and map proteins, lipids, and nucleic acids.
Learn the core IR spectroscopy techniques for solids, liquids, and gases. Choose the right sample prep method for accurate identification and analysis.
Learn the 4 essential components of an IR spectrometer: source, interferometer, sample, and detector. Understand how FTIR works for accurate chemical analysis.
Explore the main IR spectroscopy techniques: Transmission, ATR, Specular & Diffuse Reflectance. Learn how to choose the best method for your sample type.
Explore the key limitations of IR spectroscopy, including dipole moment rules, water interference, and qualitative constraints for effective molecular analysis.
Learn the correct methods for preparing solid, liquid, and gas samples for IR spectroscopy using KBr pellets, salt plates, and gas cells for accurate results.
Discover the key advantages of IR spectrophotometry: fast functional group identification, non-destructive analysis, and versatile sample handling for labs.
Learn how the KBr pellet technique in IR spectroscopy transforms opaque solids into transparent discs for precise transmission measurements and high-quality spectra.
KBR technology refers to licensed industrial processes for ammonia, refining, and olefins production. Learn how KBR's proprietary designs power global industries.
Explore the dual roles of potassium bromide (KBr) as a key material for IR spectroscopy and a veterinary anticonvulsant, and why its use in humans is obsolete.
Learn why KBr is IR transparent due to its symmetrical crystal lattice, making it ideal for sample preparation in mid-IR spectroscopy without interference.
Discover why KBr is the standard for IR spectroscopy. Learn about its IR transparency, pellet-forming properties, and key handling requirements for accurate results.
Step-by-step guide to preparing transparent KBr pellets for FTIR analysis. Learn proper grinding, pressing, and moisture control for clear, reliable spectra.
Learn how the Nujol method simplifies IR analysis of solids by reducing light scattering. Understand its advantages, limitations, and ideal applications.
KBr pellets create transparent IR windows for solids, enabling precise FTIR analysis by dispersing samples in a non-absorbing matrix without interference.
Discover why KBr is the ideal IR spectroscopy matrix due to its IR transparency, enabling accurate analysis of solid samples without spectral interference.
Learn the top causes of IR spectroscopy errors: poor sample prep, atmospheric interference, and background issues. Improve your technique for reliable results.
Discover why Potassium Bromide (KBr) is the ideal matrix for IR spectroscopy - transparent, malleable, and chemically inert for accurate sample analysis.
Learn how the KBr disc method in IR spectroscopy prepares solid samples for analysis by creating transparent pellets for accurate chemical identification.