Memberships & Publications
To fight the climate change, hydrogen plays an important role as a transportable carrier of energy. However, in order to make the turnaround happen, a lot of challenges need to be taggled and solved, beginning with producing the amount of hydrogen needed to fulfill the energy demand.
Today, most electrolytic hydrogen is produced via Alkaline Electrolysis. However, one single technology will not be sufficient to cover the complete demand. All technologies need to be employed in the best possible way. That is why Proton Exchange Membrane (PEM) electrolysis will play a particularly important role, especially in terms of production of Green Hydrogen. It is best suited to convert the fluctuating energy output of renewable energies, such as solar, hydro and wind energy.
For the mentioned PEM electrolysis precious metals are required – some of them being very scarce, like iridium – and they will be needed in significant quantities. Also, sequential processes like the purification of hydrogen, or the conversion into other forms for easier storage and transport, require precious metals.
Thus, precious metals are indispensable for the Hydrogen Revolution, and therefore the hydrogen ramp-up requires a raw material strategy. This strategy needs to cover three important aspects:
As a precious metals specialist, Heraeus is a skilled partner with high expertise in all necessary fields and has been investing significantly in R&D and hydrogen recycling. What is more, we are actively engaging in the Hydrogen Community, contributing to make the Hydrogen Revolution happen.
Heraeus is a member of various organizations that engage themselves in the Hydrogen economy, among others in the Hydrogen Council, Global Energy Solutions, Hydrogen Europe, Ammonia Energy Association, European Clean Hydrogen Alliance and The Fuel Cell and Hydrogen Energy Association (FCHEA).
As well, we are actively taking part in several projects to accelerate the development of solutions that enable the hydrogen ramp up.
Project length: five years
On March 13, 2024, the U.S. Department of Energy (DOE) announced $750 million in funding for 52 projects across 24 states to dramatically reduce the cost of clean hydrogen and reinforce American leadership in the growing hydrogen industry. Among the recipients, the American Institute of Chemical Engineers (AIChE) was selected to lead H2CIRC, a new “recovery and recycling” consortium charged with developing innovative and practical approaches to enable the recovery, recycling, and reuse of materials and components for hydrogen fuel cells and electrolyzers. This development will be supported by federal funding to be awarded to AIChE for the Hydrogen Electrolyzer and Fuel Cell Recycling Consortium, which totals $50 million over five years. The funding is being provided by the DOE's Hydrogen and Fuel Cell Technologies Office.
AIChE will lead a consortium that includes national laboratories, universities, and key fuel cell and electrolyzer industry partners. The project will develop and demonstrate recycling technology approaches to address end-of-life and critical supply chain challenges for proton exchange membrane fuel cells and electrolyzers. The goal of the project is to provide a blueprint for the hydrogen industry to efficiently and sustainably recover and recycle materials and components from fuel cells and electrolyzers.
Project Duration: 01.10.2021 - 30.09.2024
Development of an electrochemical seperation technology for Hydrogen from the natural gas grid, aiming towards high purity.
You are interested in deep-diving into Hydrogen related topics? We recommend the following publications.
The Hidden, Precious Key to Hydrogen: Why Hydrogen and Precious Metals Belong Together
Steffen Kitzing in Interview: Black Powder for Green Hydrogen – How Heraeus Precious Metals Enables Sustainable Hydrogen Solutions With Breakthrough Innovations.
Published |
Title |
Topic |
Author |
---|---|---|---|
Jan 2025 | Electrolyser Partnership input for the Clean Industrial Deal |
Call to Actions for Hydrogen in Europe |
European Clean Hydrogen Alliance |
Oct 2024 | Global Hydrogen Review 2024 | Comparison H2 and applications | IEA |
Sep 2024 | Hydrogen Insights 2024 | state of the global hydrogen economy | Hydrogen Council (McK) |
Jan 2024 | Länderanalyse 2023 – Internationale Wasserstoff-Strategien im Vergleich (country analysis 2023 – international strategies for hydrogen in comparision) | Country roadmaps, transportation routes, costs |
Wasserstoff-Kompass DECHEMA, acatech |
Aug 2023 | Site-specific, comparative analysis for suitable Power-to-X pathways and products in developing and emerging countries | Power-to-X comparison, Energy Input sources, costs of products and plants, global view and global transport ways | Fraunhofer ISE, H2Global Stiftung |
Aug 2023 | A Comparative Study on the Activity and Stability of Iridium-Based Co-Catalysts for Cell Reversal Tolerant PEMFC Anodes | Material innovation for PEM fuel cells | Robert Maric et al 2023 J. Electrochem. Soc. |
Jul 2023 | Fortschreibung der Nationalen Wasserstoffstrategie (Continuation of the National Hydrogen Strategy) | National Hydrogen Strategy Germany | Federal Ministry for Education and Research, Germany |
Mar 2023 | Supply chain analysis and material demand forecast in strategic technologies and sectors in the EU – A foresight study | Raw materials and supply chain | Joint Research Centre, EUC |
Feb 2023 | Preiselastische Wasserstoffnachfrage in Deutschland – Methodik und Ergebnisse (Price-elastic hydrogen demand in Germany - Methodology and results) | Market Potential of Green Hydrogen | HYPAT / Fraunhofer ISI |
Dec 2022 | Sufficiency, sustainability and circularity of critical materials for clean hydrogen | Critical Raw Materials for Hydrogen | World Bank / Hydrogen Council |
Jan 2022 | Mineralische Rohstoffe für die Wasserelektrolyse – Themenheft (Mineral raw materials for water electrolysis) | Availability of critical raw materials | DERA |
Jan 2022 | Geopolitics of the Energy Transformation - The Hydrogen Factor | Geopolitical Role of H2 | IRENA |
Nov 2021 | Hydrogen Net-Zero - A critical cost-competitive energy vector | H2 Economy Scale Up | HydrogenCouncil (McK) |
Okt 2021 | Cost forecast for low temperature electrolysis – technology driven bottom-up prognosis for PEM and alkaline water electrolysis systems | Tech-open comparison PEM vs. Alkaline | Clean Air Task Force (FH ISE) |
Sep 2021 | Roadmap towards zero emissions - The complementary role of BEVs and FCEVs | BEVS and FCEVs not or | HydrogenCouncil (McK) |
Jan 2021 | Hydrogen Decarbonization Pathways | Hydrogen and Decarbonization | HydrogenCouncil (McK) |