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Analysis of Toxic Elements in Wastewater and Sewage Sludge by HR-CS AAS
In municipal and industrial treatment plants, many different wastewater samples from various inlets, outlets, and pumping stations must be analyzed regularly.
A Dedicated High-Performance Sample Introduction System for ICP-OES (Oct 2022)
Highlight of the superior performance achieved with a dedicated HF-resistant, high-performance sample introduction system (HP-SIS) from Glass Expansion.
Whole Blood Analysis Using UV-vis Spectroscopy
In this application note, we use an Ocean ST-UV microspectrometer (185-650 nm) to measure the absorbance of whole blood and methemoglobin.
Battery Research Using Raman Spectroscopy
Learn of three real-life examples of using Raman microscopy in battery research, focusing on lithium batteries to better understand the process both ex- and in-situ.
Chemical Imaging of Berry Seed Cross Section
A section of a fruit berry seed was chemically imaged with infrared spectromicroscopy revealing domains of phospholipid-rich regions from the cell walls of the seed’s skin.
Iron Nanoparticles in Semiconductor Organic Solvents
This work demonstrates the ability of the NexION® SP-ICP-MS to detect iron-containing nanoparticles in organic solvents using Reaction mode.
Analyze Compound Semiconductors with the inVia™
The inVia microscope is a non-invasive, non-destructive tool that provides sub-micrometer information on the vibrational, crystal, and electronic structure of materials.
The Agilent Cary 630 FTIR Spectrometer for Material Identification Applications (Oct 2022)
Using Agilent MicroLab software for FT-IR to perform fast, easy, and reliable workflows for the analysis of different sample-types.
Quantification and Chemical Identification of NOx Reduction Agent AdBlue (AUS32) Using ATR-FTIR (Oct 2022)
Agilent Cary 630 FT-IR performs easy, fast, and reliable liquid measurements.
Analysis of selenized yeast cells
This note demonstrates how ICP-MS can be used to assess trace elements in individual yeast cells and display the mass distribution across several hundred cells.
Two for One: Structural + Chemical Composition with ONE Measurement
Maximize Returns and Limit Competition with Optimized Identification
Analysis of Trace Metal Impurities in High Purity Hydrochloric Acid Using ICP-QQQ
Ultra-low level determination of phosphorus, sulfur, silicon and chlorine using the Agilent 8900 ICP-QQQ
Agilent Atomic Spectroscopy Solutions for the Semiconductor Industry (Oct 2022)
Ultrapure Process Chemicals Analysis by ICP-QQQ with Hot Plasma Conditions
Analysis of Ultratrace Impurities in High Silicon Matrix Samples by ICP-QQQ
Automated Analysis of Ultratrace Elemental Impurities in Isopropyl Alcohol
Automated Analysis of Semiconductor Grade Hydrogen Peroxide and DI Water using ICP-QQQ
Multielement Nanoparticle Analysis of Semiconductor Process Chemicals Using spICP-QQQ (Oct 2022)
Food Analysis with Confocal Raman Microscopy (Oct 2022)
This survey shows how Raman imaging can characterize food samples such as honey, chocolate, and fat spreads to help understand the products and production processes.
FTIR Analysis Made Easy. Agilent MicroLab 5.7 Software
Aggregation Analysis of Innovator and Biosimilar Therapeutic Proteins Using FTIR
The Agilent Cary 630 FTIR Spectrometer for Material Identification Applications
Quantification and Chemical Identification of NOx Reduction Agent AdBlue (AUS32) Using ATR-FTIR
As Easy as 1, 2, 3, Makes FTIR Analysis Fast and Simple
Microwave Digestion Cookbook
This reference notebook provides the tools you need to quickly and efficiently develop digestion methods for inorganic sample preparation needs.
AOAC Method 2015.01 for Toxic Elements in Food
In this work, the analysis of toxic elements in various food matrices following AOAC 2015.01 was validated using the NexION® 2000 ICP-MS.
Determination of Toxic and Trace Elements in Baby Foods
Analysis of toxic elements (As, Cd, Hg, and Pb) and other trace elements (Cr, Mn, Ni, Cu, Zn, Se, Mo, and Tl) in baby foods following U.S. FDA EAM 4.7
Analysis of Micronutrients in Fruit Juice Using ICP-OES
This work focuses on the analysis of micronutrients in a variety of commercial juice products using the Avio® 220 Max hybrid simultaneous ICP-OES.
