What is WDXRF, and what are its main characteristics?

WDXRF (Wavelength Dispersive X-ray Fluorescence) is an analytical technique that measures fluorescent X-rays emitted from a sample when irradiated by primary X-rays. These fluorescent X-rays are diffracted by an analyzing crystal, allowing separation by wavelength according to Bragg’s law. Because each element emits X-rays with characteristic wavelengths, WDXRF enables reliable qualitative and quantitative analysis. Key characteristics include: High spectral resolution, minimizing peak overlaps and enabling accurate multi-element analysis Excellent light-element sensitivity, made possible by optimized optics and analyzing crystals Outstanding long-term stability and reproducibility, supported by stable X-ray optics and digital signal processing Reference: What XRF Can and Can’t Analyze: A Guide for Beginners

What applications and sample types are suitable for WDXRF?

WDXRF accommodates a broad range of sample forms—including solids, powders, liquids, and thin films—and is used extensively across industries such as: Metals and alloys (ferrous and non-ferrous) Cement, glass, ceramics, and minerals Petroleum products, fuels, and related refinery processes Battery materials and electronic device materials Environmental samples such as soils, sludge, and waste materials The versatility of WDXRF stems from its ability to achieve high accuracy, high sensitivity, and high throughput across diverse matrices, as emphasized in Rigaku’s product and application materials. References: What XRF Can and Can’t Analyze: A Guide for Beginners All industries

How does WDXRF differ from EDXRF and ICP techniques?

Each method possesses distinct strengths. WDXRF Uses a crystal to disperse fluorescent X-rays, giving superior peak separation and high quantitative accuracy Provides high sensitivity for light elements, particularly when measured under vacuum or helium atmosphere Ideal for long-term quantitative analysis in quality control environments EDXRF Uses energy-dispersive detection rather than wavelength dispersive optics Compact and simple architecture Short measurement times suitable for screening or field applications ICP-AES / ICP-MS Requires solution sample preparation, but delivers extremely low detection limits (ppb and below) Enables simultaneous multi-element detection at high sensitivity Needs sample digestion and chemical handling Reference: What XRF Can and Can’t Analyze: A Guide for Beginners

What element range and detection limits can WDXRF achieve?

Depending on the instrument configuration and measurement parameters, WDXRF can quantify elements typically ranging from Be (Z=4) to Cm (Z=96). Concentration ranges: Major components: several mass% to 100% Minor/trace components: several ppm Optimized conditions: sub-ppm detection may be possible for certain elements These performance capabilities align with Rigaku’s demonstrations of high-sensitivity WDXRF systems using optimized crystals, Soller slits, and digital signal processing. Reference: What XRF Can and Can’t Analyze: A Guide for Beginners

What is the difference between sequential and simultaneous WDXRF spectrometers?

Sequential WDXRF spectrometers measure elements one at a time by scanning the diffracted fluorescent X-rays across different optical conditions—such as analyzing crystals, Soller slits, and detectors—to obtain each element’s intensity. This approach provides high spectral resolution, excellent flexibility, and the ability to optimize measurement time and optical settings for each element individually. Simultaneous WDXRF spectrometers, on the other hand, use multiple fixed optical channels, with each channel dedicated to a specific element. Because all elements are measured at the same time, simultaneous systems offer very high throughput, making them ideal for routine, high-volume quality control applications. In summary: Sequential WDXRF: Measures elements sequentially Highly flexible for different applications and matrices Enables optimal selection of analyzing crystals and measurement conditions Simultaneous WDXRF: Measures multiple elements simultaneously Extremely fast and stable for fixed sets of elements Suitable for production and continuous process control Reference: Compare all WDXRF

What are the key measurement parameters for obtaining high-quality WDXRF data?

The quality of WDXRF results is governed by: Measurement Time Longer measurement time improves counting statistics, reducing relative error. Optical Conditions Key settings include: X-ray tube voltage and current Analyzing crystal (e.g., LiF(200), PET, Ge) Collimator/Soller slit Filters to stabilize background and prevent interferences Calibration Models Constructing appropriate calibration curves and applying matrix corrections such as FP (Fundamental Parameters) are essential for accurate quantitative analysis. These considerations match Rigaku’s documentation showing how automatic setting of measurement/correction conditions enhances reliability.

How much sample preparation is required for metals, powders, and liquids?

The level of preparation depends on the required analytical precision and sample characteristics. Metals Surface polishing is typically essential to remove oxidation or contaminants For cast materials, melting or homogenizing chips may be needed Ensuring that the surface condition of both standard and unknown samples is prepared in the same manner is important for consistent results Powders First, grind sufficiently (aim for approximately 50 µm), then either pack directly into the cell or form into pellets. For higher precision, melt it with a flux to form glass beads. Grind to achieve uniform particle size (≤ 50 µm recommended) Measure as loose powder or press into pellets For highest accuracy, prepare fusion beads Liquid Use a dedicated liquid cell and measure under helium atmosphere For trace elements, pipette onto filter paper, dry, and measure in vacuum Reference: Sample Preparation Videos

What is the typical measurement time and throughput?

Measurement time varies based on target elements, required precision, and optical conditions: Routine QA/QC: several tens of seconds to several minutes per element Trace/critical analyses: several minutes to more than ten minutes High-capacity auto-samplers can significantly enhance throughput, enabling continuous unattended operation.

When introducing a WDXRF instrument, what points should be checked regarding introduction and operational costs?

Organizing costs into the following categories facilitates consideration: Cost factors can be viewed in two categories: Initial installation Instrument price (X-ray tube rating, optical components, available options) Required infrastructure: power capacity, cooling (if required), installation space, floor load Running costs Gases such as helium or P-10 Consumables such as sample cups, films, flux, and pellets Replacement intervals for X-ray tubes and detectors Reference: How Much Does an XRF Spectrometer Cost?

WDXRF Frequently Asked Questions

Understanding WDXRF fundamentals

: WDXRF (Wavelength Dispersive X-ray Fluorescence) is an analytical technique that measures fluorescent X-rays emitted from a sample when irradiated by primary X-rays. These fluorescent X-rays are diffracted by an analyzing crystal, allowing separation by wavelength according to Bragg’s law. Because each element emits X-rays with characteristic wavelengths, WDXRF enables reliable qualitative and quantitative analysis.

Key characteristics include:

High spectral resolution, minimizing peak overlaps and enabling accurate multi-element analysis

Excellent light-element sensitivity, made possible by optimized optics and analyzing crystals

Outstanding long-term stability and reproducibility, supported by stable X-ray optics and digital signal processing

Reference: What XRF Can and Can’t Analyze: A Guide for Beginners
: WDXRF accommodates a broad range of sample forms—including solids, powders, liquids, and thin films—and is used extensively across industries such as:

Metals and alloys (ferrous and non-ferrous)

Cement, glass, ceramics, and minerals

Petroleum products, fuels, and related refinery processes

Battery materials and electronic device materials

Environmental samples such as soils, sludge, and waste materials

The versatility of WDXRF stems from its ability to achieve high accuracy, high sensitivity, and high throughput across diverse matrices, as emphasized in Rigaku’s product and application materials.

References:

What XRF Can and Can’t Analyze: A Guide for Beginners

All industries
: Each method possesses distinct strengths.

WDXRF

Uses a crystal to disperse fluorescent X-rays, giving superior peak separation and high quantitative accuracy

Provides high sensitivity for light elements, particularly when measured under vacuum or helium atmosphere

Ideal for long-term quantitative analysis in quality control environments

EDXRF

Uses energy-dispersive detection rather than wavelength dispersive optics

Compact and simple architecture

Short measurement times suitable for screening or field applications

ICP-AES / ICP-MS

Requires solution sample preparation, but delivers extremely low detection limits (ppb and below)

Enables simultaneous multi-element detection at high sensitivity

Needs sample digestion and chemical handling

Reference: What XRF Can and Can’t Analyze: A Guide for Beginners
: Depending on the instrument configuration and measurement parameters, WDXRF can quantify elements typically ranging from Be (Z=4) to Cm (Z=96).

Concentration ranges:

Major components: several mass% to 100%

Minor/trace components: several ppm

Optimized conditions: sub-ppm detection may be possible for certain elements

These performance capabilities align with Rigaku’s demonstrations of high-sensitivity WDXRF systems using optimized crystals, Soller slits, and digital signal processing.

Reference: What XRF Can and Can’t Analyze: A Guide for Beginners
: Sequential WDXRF spectrometers measure elements one at a time by scanning the diffracted fluorescent X-rays across different optical conditions—such as analyzing crystals, Soller slits, and detectors—to obtain each element’s intensity.

This approach provides high spectral resolution, excellent flexibility, and the ability to optimize measurement time and optical settings for each element individually.

Simultaneous WDXRF spectrometers, on the other hand, use multiple fixed optical channels, with each channel dedicated to a specific element. Because all elements are measured at the same time, simultaneous systems offer very high throughput, making them ideal for routine, high-volume quality control applications.

In summary:

Sequential WDXRF:

Measures elements sequentially

Highly flexible for different applications and matrices

Enables optimal selection of analyzing crystals and measurement conditions

Simultaneous WDXRF:

Measures multiple elements simultaneously

Extremely fast and stable for fixed sets of elements

Suitable for production and continuous process control

Reference: Compare all WDXRF

Achieving accurate measurements (Data quality & measurement)

: The quality of WDXRF results is governed by:

Measurement Time

Longer measurement time improves counting statistics, reducing relative error.

Optical Conditions

Key settings include:

X-ray tube voltage and current

Analyzing crystal (e.g., LiF(200), PET, Ge)

Collimator/Soller slit

Filters to stabilize background and prevent interferences

Calibration Models

Constructing appropriate calibration curves and applying matrix corrections such as FP (Fundamental Parameters) are essential for accurate quantitative analysis.

These considerations match Rigaku’s documentation showing how automatic setting of measurement/correction conditions enhances reliability.
: The level of preparation depends on the required analytical precision and sample characteristics.

Metals

Surface polishing is typically essential to remove oxidation or contaminants

For cast materials, melting or homogenizing chips may be needed

Ensuring that the surface condition of both standard and unknown samples is prepared in the same manner is important for consistent results

Powders

First, grind sufficiently (aim for approximately 50 µm), then either pack directly into the cell or form into pellets.

For higher precision, melt it with a flux to form glass beads.

Grind to achieve uniform particle size (≤ 50 µm recommended)

Measure as loose powder or press into pellets

For highest accuracy, prepare fusion beads

Liquid

Use a dedicated liquid cell and measure under helium atmosphere

For trace elements, pipette onto filter paper, dry, and measure in vacuum

Reference: Sample Preparation Videos
: Measurement time varies based on target elements, required precision, and optical conditions:

Routine QA/QC: several tens of seconds to several minutes per element

Trace/critical analyses: several minutes to more than ten minutes

High-capacity auto-samplers can significantly enhance throughput, enabling continuous unattended operation.

Key considerations for installation and operation

: Organizing costs into the following categories facilitates consideration:

Cost factors can be viewed in two categories:

Initial installation

Instrument price (X-ray tube rating, optical components, available options)

Required infrastructure: power capacity, cooling (if required), installation space, floor load

Running costs

Gases such as helium or P-10

Consumables such as sample cups, films, flux, and pellets

Replacement intervals for X-ray tubes and detectors

Reference: How Much Does an XRF Spectrometer Cost?

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