BS ISO 14707:2021 - Surface Chemical Analysis: Glow Discharge Optical Emission Spectrometry (GD-OES)

Unlock the potential of advanced surface chemical analysis with the BS ISO 14707:2021 standard. This comprehensive guide provides an in-depth introduction to the use of Glow Discharge Optical Emission Spectrometry (GD-OES), a powerful technique for analyzing the composition of materials at the surface level.

Overview

The BS ISO 14707:2021 standard is an essential resource for professionals in the field of material science, chemistry, and engineering. Released on March 12, 2021, this standard offers a detailed introduction to GD-OES, a method renowned for its precision and efficiency in surface chemical analysis. With 22 pages of expertly curated content, this standard is designed to enhance your understanding and application of GD-OES in various industrial and research settings.

Key Features

• Standard Number: BS ISO 14707:2021
• Pages: 22
• Release Date: March 12, 2021
• ISBN: 978 0 539 15363 7
• Status: Standard

What is GD-OES?

Glow Discharge Optical Emission Spectrometry (GD-OES) is a sophisticated analytical technique used to determine the elemental composition of materials. It involves the use of a glow discharge to excite atoms in a sample, causing them to emit light at characteristic wavelengths. By analyzing this emitted light, GD-OES provides detailed information about the elements present in the sample, making it an invaluable tool for surface analysis.

Applications of GD-OES

GD-OES is widely used across various industries due to its ability to provide rapid and accurate analysis of surface compositions. Some of the key applications include:

• Metallurgy: Analyze the composition of metal surfaces to ensure quality and performance.
• Semiconductor Manufacturing: Evaluate thin films and coatings for electronic components.
• Coatings and Platings: Assess the thickness and uniformity of protective coatings.
• Corrosion Studies: Investigate the surface composition of materials exposed to corrosive environments.

Benefits of Using BS ISO 14707:2021

Adopting the BS ISO 14707:2021 standard offers numerous benefits for professionals and organizations involved in surface chemical analysis:

• Enhanced Accuracy: Gain insights into the precise elemental composition of surfaces, leading to better quality control and product development.
• Improved Efficiency: Streamline your analysis processes with a standardized approach, saving time and resources.
• Global Recognition: Align with internationally recognized standards, facilitating collaboration and compliance across borders.
• Comprehensive Guidance: Access detailed instructions and best practices for implementing GD-OES in your operations.

Why Choose BS ISO 14707:2021?

Choosing the BS ISO 14707:2021 standard means investing in a reliable and authoritative resource that supports your analytical needs. Whether you are a seasoned professional or new to the field, this standard provides the foundational knowledge and practical insights necessary to leverage GD-OES effectively.

Conclusion

In the ever-evolving landscape of material science and surface analysis, staying ahead requires access to the latest standards and methodologies. The BS ISO 14707:2021 standard is your gateway to mastering Glow Discharge Optical Emission Spectrometry, empowering you to achieve unparalleled accuracy and efficiency in your analyses. Embrace this standard to enhance your capabilities and drive innovation in your field.

BS ISO 14707:2021

This standard BS ISO 14707:2021 Surface chemical analysis. Glow discharge optical emission spectrometry (GD-OES). Introduction to use is classified in these ICS categories:

• 71.040.40 Chemical analysis

This document provides guidelines that are applicable to bulk and depth profiling GD-OES analyses. The guidelines discussed herein are limited to the analysis of rigid solids, and do not cover the analysis of powders, gases or solutions. Combined with specific standard methods which are available now and, in the future, these guidelines are intended to enable the regulation of instruments and the control of measuring conditions.

Although several types of glow discharge optical emission sources have been developed over the years, the Grimm type with a hollow anode accounts for a very large majority of glow discharge optical emission devices currently in use both for dc and rf sources. However, the cathode contact is often located at the back of the sample, in e.g. the Marcus type source, rather than at the front as in the original Grimm design. The guidelines contained herein are equally applicable to both and other source designs and the Grimm type source is used only as an example.