LIBS spectroscopy

The LIBS spectroscopy (Laser-Induced Breakdown Spectroscopy) has established itself as a groundbreaking method for fast and precise elemental analysis. This innovative technology is versatile and plays an increasingly important role in both research and industry. But what exactly is the LIBS spectroscopy, how does it work and what advantages does it offer?

What is LIBS spectroscopy?

The LIBS spectroscopy is therefore an analytical technique based on the analysis of the light emitted by a laser-induced plasma. A powerful laser pulse is focused on the surface of a sample. This pulse causes a tiny part of the material to evaporate and become ionized. The resulting plasma emits light. The specific wavelengths of this light provide information about the chemical composition of the sample. This method therefore enables precise, fast and non-destructive elemental analysis.

How does LIBS technology work?

The LIBS spectroscopy is based on four essential steps:

1. laser ablation: A pulsed laser beam of high energy hits the sample surface and causes the vaporization of a tiny area of material.
2. plasma generation: The vaporized material is further ionized by the laser, creating a hot plasma.
3. light emission: As the plasma cools, the excited atoms and ions emit light at specific wavelengths, a fundamental process in laser-induced plasma spectroscopy.
4. spectral analysis: A spectrometer detects the emitted light and creates a spectrum that reflects the presence and concentration of elements in the sample.

Applications of LIBS Spectroscopy

The versatility of LIBS technology allows its application in a wide range of areas:

• materials science: Analysis of metals, alloys and ceramics for quality control.
• environmental monitoring: Detection of heavy metals and pollutants in soil, water and air by laser-induced plasma spectroscopy.
• Industry: Process control in metallurgy, petrochemicals and pharmaceuticals.
• cultural and art history: Examination of paintings and artifacts without damage.
• Planetary Research: NASA’s Mars rover “Curiosity” uses LIBS to analyze Martian rocks.

Advantages of LIBS technology

LIBS spectroscopy offers numerous advantages. It is characterized by its speed, as results are provided in real time, which is ideal for process controls and enables quick decisions. It is also a non-destructive method with minimal sample preparation, so the samples remain largely intact. Another advantage is the wide range of elements that can be detected. The technique enables the detection of almost all elements, including light elements such as lithium and beryllium, creating a comprehensive analysis profile. In addition, Laser-Induced Plasma Spectroscopy is extremely flexible, as it can be applied to solids, liquids and gases, meaning it can be used in a variety of environments.

challenges and solutions

Although LIBS technology offers many advantages, there are challenges such as matrix effects that can affect the signal. However, these can be minimized through calibration and advanced algorithms. By optimizing the laser parameters and using double-pulse lasers, fluctuations in the plasma signal can be stabilized.

Current research and developments

Research is working intensively to improve the sensitivity and accuracy of LIBS spectroscopy. Advances such as the combination with Raman spectroscopy or laser ablation-inductively coupled plasma mass spectrometry (LA-ICP-MS) are expanding the application possibilities. In addition, portable LIBS systems are being developed to carry out analyses directly on site.

future prospects

As technology advances, LIBS systems are becoming increasingly compact and affordable. This not only encourages their integration into portable devices, but also enables them to be used in remote or hard-to-reach areas. In addition, when combined with artificial intelligence and machine learning, they could become even more powerful by analyzing data faster and more accurately.

Conclusion

The LIBS spectroscopy therefore offers a unique combination of speed, versatility and precision. It is also non-destructive, which makes it particularly gentle to use. Its ability to detect a wide range of elements makes it ideal for a wide range of applications. It therefore represents a first-class solution for modern analytical challenges in research and industry.

Sources

• “Laser-Induced Breakdown Spectroscopy: Principles and Applications” by Andrzej W. Miziolek, Vincenzo Palleschi and Israel Schechter, Cambridge University Press, 2006.
• “Handbook of Laser-Induced Breakdown Spectroscopy” by David A. Cremers and Leon J. Radziemski, Wiley, 2013.
• NASA Mars Science Laboratory – ChemCam Instrument: NASA – ChemCam Instrument