- Assisted measurement and analysis support: ZSX Guidance
- Automated analysis settings features enhanced third-generation SQX analysis software
- ZSX Guidance software
- Built-in XRF expertise handles sophisticated settings. Available application packages enable turn-key operations.
- Intuitive software programmable for everyday analysis using sample trays
- Sample ID settings for each tray (facilitates easy copy-and-paste for efficient measurement setup).
- Improved accuracy of liquid sample analysis
- Correction of geometry effect caused by geometry of liquid sample cups.
- High-speed, high-precision measurements
- Efficiency of the new drive sequence decreases instrument overhead time
- Unique functionality
- The tube-below optics enables convenient functionality, including new sample film corrections.
In addition to the application notes listed below, these new documents are available for request:
- Standardless FP Analysis of Plant, Animal and Food Samples Applying Correction by Scattering Line
- Lead Analysis in Gasoline — ASTM D5059-14 — Using WDXRF ZSX Primus IVi
- Analysis of S, Fe, Ni and V in Residual Oil According to IP610/13
- Lubricating Oil Analysis by WDXRF According to ASTM D6443-14
- Sulfur Analysis in Petroleum Products by WDXRF According to ASTM D2622-16
- Analysis of Low Concentration Sulfur in Petroleum-based Fuels by WDXRF According to ASTM D2622-16
- Sulfur Analysis in Crude Oil and High-Sulfur Fuels by WDXRF According to ASTM D2622-16
Tube-below sequential wavelength dispersive X-Ray fluorescence spectrometer
Uncompromised X-ray analysis of liquids, alloys, and plated metals
The tube-below high-performance model enables uncompromised analysis of samples such as liquids, alloys, and plated metals. Providing superior performance with the flexibility for analyzing the most complex samples, the ZSX Primus IV? WDXRF spectrometer features a 30 micron Be tube window, the thinnest standard tube window in the industry, for exceptional light element (low-Z) detection limits.
Vacuum (partition) system for analyzing liquids
Because the spectrometer chamber is always under vacuum, the change from vacuum atmosphere to helium atmosphere is completed in less than two minutes. Furthermore, the consumption of helium gas is significantly reduced compared to models where the spectrometer chamber must also be purged.
Improved mechanics minimize the analysis dead time. For example, a 16-element sequential quantitative measurement time improved from 348 seconds to 287 seconds, representing an 18% increase in efficiency.
D-MCA high-speed analysis
The Digital Multi-Channel Analyzer (D-MCA) system facilitates high-speed digital processing for high count rates for improved analytical precision and increased throughput speeds.
Optical system not easily impacted by sample surface height variations
An uneven sample surface causes variations in the distance between the sample and the X-ray tube. These differences can lead to changes in the X-ray intensity. Rigaku optical systems enable suppression of X-ray intensity changes caused by variation in distance. This enables accurate analysis by minimizing the impact of shape differences from fusion molds used in glass bead formulation and the impact of uneven sample surfaces during pressing of powder samples.
Equipped with a high-resolution camera that allows the user to zoom in on small features for proper identification and analysis. Enables accurate analysis by eliminating differences in sensitivity caused by measurement placement. Superior design uses the hot-spot of the tube to maximize intensity/sensitivity.
Refined SQX analysis
SQX analysis is standardless FP analysis software for calculation of accurate elemental composition. Now easier to use than ever.
Automated center wire cleaning mechanism
The F-PC detector center wire gradually becomes contaminated by proportional counter quench gas, which diminishes resolution. The center wire cleaning mechanism enables restoration of performance by eliminating center wire contamination by means of electrical heating, with no need to shut off the power source or to open the cabinet.
|Booth number||Date||Location||Event website|
|Materials Science & Technology (MS&T 2023)||-||Columbus, OH||Website|
|Gulf Coast Conference (GCC 2023)||-||Galveston, TX||Website|
|Geological Society of America 2023||-||Pittsburgh, PA||Website|
|AAPS 2023 PHARMSCI 360||-||Orlando, FL||Website|
|SERMACS 2023||-||Durham, NC||Website|
|Thermal Analysis Webinar: Let's Evaluate Materials With STA||Webinar||Register|
|Lab Innovations 2023||-||Birmingham, UK||Website|
|TOPIQ Webinar: Flow-Xl: A New UK Facility for the Analysis of Crystallisation in Flow Systems||Webinar||Register now|
|Webinar: How to Run in Operando XRD Experiments||Webinar||Register now|
|Webinar: XRF Analytical Considerations for the Oxidation Fusion Methods||Webinar||Register now|
|Rayons X et Matière 2023||-||Bordeaux, France||Website|
|Thermal Analysis Webinar: Let's evaluate materials with DSC||Webinar||Register|
|Materials Research Society (MRS2023)||-||Boston, MA||Website|
|Webinar: Pair Distribution Function (PDF) Analysis for Everyday Battery Analysis||Webinar||Register now|
|Webinar: Non-destructive Elemental Analysis of Batteries Using XRF||Webinar||Register now|
|Webinar: Nondestructive inspection of batteries using X-ray Computed Tomography||Webinar||Register now|