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As hydrogen emerges as a big player in the global clean energy market, the materials and infrastructure involved in its generation, transportation, distribution, and storage are presenting new challenges to the industry. ºÚÁϲ»´òìÈ has extensive technical expertise in testing materials, coating, and electrochemistry in environmental conditions.  

As an energy carrier, hydrogen (H2) offers numerous advantages: it can be used in internal combustion engines or fuel cells, producing virtually no greenhouse gas emissions when combusted with oxygen.

Hydrogen can be transported, stored, and even blended with other sources such as natural gas to reduce CO2 emissions. So-called "green" hydrogen produced with electricity from renewable sources such as wind power or solar cells instead of fossil fuels allows CO2-free Energy production. 

Testing in a hydrogen environment

Hydrogen-related technologies for production, storage, transportation, and utilization are evolving, and understanding them is an essential part of today's world of energy and sustainability.

The interaction of materials with hydrogen and the associated hazards and failure consequences have made material science and electrochemistry two fundamental areas of research for further development and wider safe application of hydrogen-related technologies. 

With decades of experience in testing and qualification of materials, ºÚÁϲ»´òìÈ is well prepared and actively involved in further development and application of safe hydrogen-related technologies, emphasizing testing, characterization, and qualification of materials, both metals, and polymers, exposed to hydrogen-containing environments. 

ºÚÁϲ»´òìÈ supports customers with their Carbon Capture Usage & Storage projects (CCUS), developing fuel tanks for the aerospace and transportation industry, as well as hydrogen pipeline and storage facilities for the energy sector. 

ºÚÁϲ»´òìÈ's current research and development activities are focused on expanding the facilities and infrastructures for performing mechanical and fracture mechanics testing in H2 environments.

The result of such testing scenarios will be implemented in a fracture mechanics-based design approach for hydrogen containment and transport components such as steel piping systems and pipelines that carry gaseous hydrogen. This will, in turn, significantly reduce concerns about catastrophic failures due to embrittlement and sub-critical crack propagation in structural materials.

Hydrogen testing under cryogenic conditions

Hydrogen can be stored binding it to chemical compounds and as a gas or liquid. Storage of H2 as a gas typically requires high pressures up to 800 bar, while its boiling point of -253°C at one bar requires cryogenic temperatures to keep it liquid.

For the characterization and qualification of materials used for liquid hydrogen storage tanks, ºÚÁϲ»´òìÈ offers a full range of cryogenic testing for mechanical and fracture mechanics in cryogenic environments as low as -268 °C. 

Hydrogen permeation testing on polymers

Because of its small molecular size, hydrogen can permeate through polymeric (non-metallic) materials much faster than methane or other gases traditionally associated with fossil fuels. This needs to be quantified so that, for example, the amount of hydrogen permeating through the walls of a thermoplastic transmission line can be calculated, as well as the losses through seals in compressors etc. 

ºÚÁϲ»´òìÈ is already conducting testing with hydrogen on elastomers and thermoplastics at pressures to 100 bar and has been able to compare permeation rates to previously tested gases.

The ºÚÁϲ»´òìÈ advantage

ºÚÁϲ»´òìÈ offers outstanding knowledge and expertise in the fields of materials science, corrosion, coatings, and electrochemistry. Our engaged experts have state-of-the-art equipment to provide testing, certification, and consulting for many areas of hydrogen-related technologies. 

For more information about our hydrogen testing capabilities or to request a quote, contact us today.