Towards a Hydrogen-Powered Future: Highly Sensitive Hydrogen Detection System
en-GBde-DEes-ESfr-FR

Towards a Hydrogen-Powered Future: Highly Sensitive Hydrogen Detection System

05.11.2024 Chiba University

Hydrogen gas is a promising energy source with several advantages - it is lightweight, storable, energy-dense, and environmentally friendly compared to fossil fuels, producing no pollutants or greenhouse gas emissions. As such, it has extensive applications across different fields, including transportation, architecture, power generation, and industries. However, hydrogen is highly flammable, and therefore its safe and widespread use requires reliable methods for detecting leaks and ensuring its purity. The need for reliable detection methods has necessitated the development of trace-gas sensing techniques. While several methods have been developed for hydrogen sensing, none offer optimal performance.

One promising method is tunable diode laser absorption spectroscopy (TDLAS) technology, which has gained significant attention for detecting various gases. TDLAS offers several key advantages, including non-contact measurement, in situ detection, high selectivity, rapid response, low cost, and multi-component, multi-parameter measurement capabilities. It works on the principle that gases absorb light at a specific wavelength, resulting in a dark line in the absorption spectrum, known as the absorption line. By measuring the amount of laser light that has been absorbed at this wavelength, the concentration of the gas can be determined. However, detecting low concentrations of hydrogen with TDLAS is difficult because hydrogen has weaker absorption in the infrared region compared to other gases.

To address this issue, a research team from Japan led by Associate Professor Tatsuo Shiina from the Graduate School of Engineering, Chiba University, developed an innovative method for precise hydrogen gas measurement using TDLAS. The team comprised Alifu Xiafukaiti and Nofel Lagrosas from the Graduate School of Engineering, Chiba University, Ippei Asahi from the Shikoku Research Institute Inc., and Shigeru Yamaguchi from the School of Science, Tokai University. Their study was made available online on August 13, 2024, and published in Volume 180 of the journal Optics and Laser Technology on January 01, 2025.

In this study, we achieved highly sensitive detection of hydrogen gas through meticulous control of pressure and modulation parameters in the TDLAS setup. Additionally, we introduced a calibration-free technique that ensures the adaptability to a wide range of concentrations,” explains Prof. Shiina.

In TDLAS, laser light is passed through a pressurized gas cell called a Herriott multipass cell (HMPC) containing the target gas. The laser’s wavelength is modulated or oscillated around the target absorption line of the gas at a specific frequency to remove any environmental noise. The pressure in HMPC can significantly influence the absorption line width and consequently the modulation parameters under TDLAS.

The researchers carefully analyzed the width of hydrogen’s strongest absorption line at different pressures. Through simulations, the researchers identified the optimal pressure for a broader absorption line width and the most effective modulation parameters within this line width. Their calibration-free technique involved using the first harmonic of the modulated absorption signal to normalize the second harmonic through their ratio, instead of just relying on the second harmonic signal as in conventional TDLAS systems. Additionally, they employed a high-pressure gas cell containing pure hydrogen as a reference to fine-tune the modulating parameters of the laser signal.

Through this innovative approach, the researchers achieved accurate measurements of hydrogen concentrations in a wide detection range from 0.01% to 100%, where 0.01% equals a concentration of just 100 parts per million (ppm). Moreover, the results improved with longer integration times (the time period during which light is allowed to be absorbed). At 0.1 second integration time, the minimum detection limit was 0.3% or 30,000 ppm, which improved to 0.0055% or 55 ppm at 30 seconds integration time. However, beyond 30 seconds the minimum detection limit increased.

“Our system can significantly improve hydrogen detection systems for safety and quality control, facilitating wider adoption of hydrogen fuel. For example, this system can be reliably used for the detection of leakages in hydrogen fuel cell cars,” remarks Prof. Shiina about the potential applications of the study.

To summarize, this pioneering technique could help pave the way for a sustainable future and boost the implementation of hydrogen as an eco-friendly fuel.


About Associate Professor Tatsuo Shiina
Dr. Tatsuo Shiina is currently an Associate Professor at the Graduate School of Engineering at Chiba University, Japan. He received his Ph.D. degree from Tokyo University of Science in 1998. He has published over 80 articles that have received over 300 citations and an impressive h-index of 11. His research focuses on photoelectric measurement and scattering optics. Prof. Shiina is a member of several academic societies including The Japan Society of Applied Physics, The Institute of Electronics, Information and Communication Engineers, The Institute of Electrical Engineers of Japan, The Illuminating Engineering Institute of Japan, and the Optical Society of Japan.

Funding:
This work is based on results obtained from a project, JPNP18011, commissioned by the New Energy and Industrial Technology Development Organization (NEDO).
Reference:
Title of original paper: Optimization for hydrogen gas quantitative measurement using tunable diode laser absorption spectroscopy
Authors: Alifu Xiafukaitia,b, Nofel Lagrosasa,c, Masakazu Ogitad, Nobuhiko Oid, Yuji Ichikawad, Sachiyo Sugimotod, Ippei Asahid, Shigeru Yamaguchie, Tatsuo Shiinaa
Affiliations: aGraduate School of Engineering, Chiba University, Japan
bInformation Technology R&D Center, Mitsubishi Electric Corporation, Japan
cSchool of Engineering, Kyushu University, Japan
dShikoku Research Institute Inc., Japan
eTokai University, Japan
Journal: Optics and Laser Technology
DOI: 10.1016/j.optlastec.2024.111587
Angehängte Dokumente
  • Image title: Hydrogen detection using tunable diode laser absorption spectroscopy (TDLAS) Image caption: Deviation of measured concentration (in parts per million) over varying integration times resulting from Allan deviation.Image credit: Tatsuo Shiina from Chiba University https://www.sciencedirect.com/science/article/pii/S0030399224010454 Image license: CC BY 4.0Usage restrictions: You are free to share and adapt the material. Attribution is required, with a link to the license, and you must indicate if changes are made to the work.
05.11.2024 Chiba University
Regions: Asia, Japan
Keywords: Applied science, Engineering, Technology, Science, Physics

Disclaimer: AlphaGalileo is not responsible for the accuracy of news releases posted to AlphaGalileo by contributing institutions or for the use of any information through the AlphaGalileo system.

Referenzen

We have used AlphaGalileo since its foundation but frankly we need it more than ever now to ensure our research news is heard across Europe, Asia and North America. As one of the UK’s leading research universities we want to continue to work with other outstanding researchers in Europe. AlphaGalileo helps us to continue to bring our research story to them and the rest of the world.
Peter Dunn, Director of Press and Media Relations at the University of Warwick
AlphaGalileo has helped us more than double our reach at SciDev.Net. The service has enabled our journalists around the world to reach the mainstream media with articles about the impact of science on people in low- and middle-income countries, leading to big increases in the number of SciDev.Net articles that have been republished.
Ben Deighton, SciDevNet
AlphaGalileo is a great source of global research news. I use it regularly.
Robert Lee Hotz, LA Times

Wir arbeiten eng zusammen mit...


  • BBC
  • The Times
  • National Geographic
  • The University of Edinburgh
  • University of Cambridge
  • iesResearch
Copyright 2024 by DNN Corp Terms Of Use Privacy Statement