Technique |
Title |
Fluorescence, SFC |
High Sensitivity Fluorescence Detector for Supercritical Fluid Chromatography |
FTIR |
Overview of the Various Options for Time Course Measurement using FTIR |
FTIR |
Monitoring of Reaction using IR Spectroscopy with Fiber Probe | JASCO |
FTIR Microscopy |
IR Microscope with Heating/Cooling Stage for the Evaluation of the Melting Point or Phase Transition of a Sample at the Molecular Level |
FTIR |
Analysis of the Deterioration of Industrial Grease using ATR |
Circularly Polarized Luminescence |
CPL Measurement of Camphorquinone Using CPL-300 Circularly Polarized Luminescence Spectrometer |
UV-Visible/NIR |
Water Analysis using a UV-Visible Spectrophotometer with a 30 cm Cell |
UV-Visible/NIR |
Haze Measurement using a UV-Visible Spectrophotometer |
Fluorescence |
Internal Quantum Efficiency Measurement of Phosphor Powders |
UV-Visible/NIR |
Quantitative Measurement of Hexavalent Chromium Treatment to Metal Screws |
UV-Visible/NIR |
Color Analysis using a UV-Visible Spectrophotometer |
Fluorescence |
Evaluation of FRET as a Sensitive Biosensor for Explosives |
UV-Visible/NIR |
Luminous Color Measurement by UV-Visible Spectroscopy |
UV-Visible/NIR |
Evaluation of Solar Reflective Paint by UV-Visible/NIR Spectrosopy |
UV-Visible/NIR |
Horizontal Integrating Sphere for Contact Lens Measurement |
UV-Visible/NIR |
Evaluation of Cosmetic Sunscreens using a Spectroscopic SPF/PA Measurement System |
HPLC, Mass Spectroscopy |
Highly Sensitive and Comprehensive Detection for Chiral Separation of Pesticides using HPLC-CD-MS |
Mass Spectroscopy, SFC |
Highly Sensitive and Comprehensive Detection for Chiral Separation of Pesticide using SFC-CD-MS |
Fluorescence, UV-Visible/NIR |
Eliminating Fluorescence Artifacts from the Diffuse Reflectance Measurement of Sodium Salicylate |
Fluorescence |
Remote Measurement using FP-8500 Fluorometer with Optical Fiber |
FTIR, Raman |
Two Dimensional Correlation Spectroscopy using IR and Raman with Time-Course Measurement (Analysis of Cyanoacrylate Adhesive during Curing Process) |
Fluorescence |
Near-Infrared Phosphor Measurement |
Fluorescence |
Absolute Quantum Yields Using an Integrating Sphere |
Fluorescence |
Quantum Efficiency of Phosphorescent Materials using an Integrating Sphere |
Fluorescence |
Quantum Yield Measurement of the Up-Conversion Phosphors |
Fluorescence |
High Sensitivity Coumarin Analysis |
FTIR, Gas Analysis |
Simultaneous Monitoring of Greenhouse Gases with FTIR |
FTIR, Gas Analysis |
Industrial Gas Analysis System – PFC Gas Analysis |
FTIR, Gas Analysis |
Quantitative Analysis of Gases using Multi-Component Analysis and Interval Measurement |
FTIR, Gas Analysis |
Simultaneous Monitoring Analysis of Multicomponent Gases in the Atmosphere using CLS Quantitation |
FTIR, Gas Analysis |
Vacuum FTIR with Long Path Length Cell for the Analysis of Low Concentration Gases |
FTIR, Gas Analysis |
Full Vacuum FTIR Spectrometer for Quantitative Trace Gas Analysis (H2O in N2 Gas) |
Circularly Polarized Luminescence |
High-Resolution CPL Spectrum Measurement of a Europium Complex [Eu(facam)3 ] |
Raman |
The Use of Dual Spatial Filtration to Improve Spatial Resolution in Raman Imaging Micro-spectroscopy |
HPLC |
Anion Analysis using Ion Chromatography with Chemical Suppression |
HPLC |
Analysis of Nylon 6 by Semi-Micro Scale GPC |
HPLC |
Analysis of Polystyrene Oligomers by Semi-micro GPC |
HPLC |
Measurement of Warfarin using Circular Dichroism Coupled with HPLC |
HPLC |
Chiral Analysis of Flurbiprofen using a Circular Dichroism Detector |
HPLC |
Chiral Analysis of Ibuprofen using a Circular Dichroism Detector |
HPLC |
Analysis of Fatty Acids using the LC-4000 Series Rapid Separation HPLC |
FTIR |
MCR Chemometric Modeling for FTIR Imaging Microscopy |
HPLC |
Analysis of Aldehydes using Post-Column Derivatization by High Performance Liquid Chromatography |
HPLC |
Water Analysis for Aldehydes using Post-Column Derivatization by HPLC |
HPLC |
Analysis of Nonionic Surfactants by HPLC-ELSD |
HPLC |
Analysis of Formaldehyde in Air using Post-column Derivatization by HPLC |
HPLC |
Analysis of Anti-Flatulent Compounds using HPLC-ELSD |
FTIR |
Advanced FTIR Imaging System with Linear Array MCT Detector |
FTIR |
FTIR Dynamic Imaging for the Analysis of Chemical Reactions |
UV-Visible/NIR |
Evaluation of Solar Cells using Absolute Reflectance with a UV-Visible/NIR Spectrophotometer |
FTIR |
On-Line FTIR monitoring with a field-rugged spectrometer with fiber-optic cable |
UV-Visible/NIR |
Monitoring of Polysilicon Crystallization Using a Laser |
SFE |
Decomposition of Carbon Tetrachloride (CCI4) with Supercritical Water |
HPLC |
Non-Ionic Surfactant Analysis by Solid-Phase Extraction |
FTIR |
Analysis of Automotive Fluids using FTIR with an ATR Accessory |
Raman |
Confocal Raman Imaging – Using Spectroscopy for Materials Analysis and Chemical Distribution |
Circular Dichroism |
CD Spectra Measurement using a OneDrop Microsampling Disc |
FTIR |
Terahertz ATR Measurement of Liquids by Vacuum FTIR |
FTIR |
Gas analysis by vacuum FTIR – measurement of low concentration gases |
FTIR, Gas Analysis |
Gas Analysis System using Full Vacuum FTIR spectrometer (Trace levels of H2O in N2 gas) |
FTIR |
Quantitative Analysis of Powdered Solids with FTIR-ATR |
Raman |
Raman Quantitative Calibration Stability for a Sample Mixture |
Raman |
Dispersive Raman for the Identification of Contaminant Particles in Ink Jet Cartridges |
Raman |
Gemstone Identification Using Raman Spectroscopy |
Fluorescence |
Determination of Fluorescence Excitation/Emission Maxima |
Polarimetry |
Polarimetry and Optical Rotation of Sucrose and l-menthol |
HPLC |
HPLC of Fatty Acid Methyl Ester (FAME) and Triglyceride in Biodiesel and Diesel |