Our Partners
Let’s Do More—Together
We believe that the true impact of hydrogen energy comes through collaboration.
That’s why we work closely with researchers, governments, and industry leaders to accelerate breakthrough technologies—from early-stage materials to deployable systems.
Whether you’re driving policy, scaling a process, or exploring new use cases—let’s explore hydrogen together.
De Nora and Hydrolite signed (2023) an agreement to jointly develop and introduce to the market a novel AEM technology.
The cooperation agreement involves the development, scale-up, and production of a novel AEM stack device, capable of generating and using hydrogen, by leveraging the knowledge and expertise of both parties.
With support from the Israeli Ministry of Energy, Hydrolite and Mekorot will launch an AEM hydrogen pilot. In Phase 1, Hydrolite’s AEM fuel cell backup system will be tested at a Mekorot beta-site as a green, quiet, low-cost alternative to diesel generators. Phase 2 will explore integrating Hydrolite’s AEM electrolyzer to produce and store hydrogen on-site for refueling the fuel cell, reducing both logistics and operating costs.
Development and demonstration of a commercial-scale AEM electrolyzer for local hydrogen production at a customer's site
Develop & implement innovative AEM Hydrogen fuel cells to secure energy continuity and independence at critical communication site
For over a decade and a half, Hydrolite has served as a national center of knowledge and excellence in the field of energy. With continuous support from the Israeli Ministry of Defense, its mission is to research and develop groundbreaking solutions and infrastructure in the energy sector, with a particular focus on hydrogen technologies.
The ANIONE consortium aimed at developing a solution for efficient and sustainable storage of renewable energy by converting electricity into hydrogen via advanced
anion exchange membrane water electrolysis (AEMWE).
As a key partner, Hydrolite led the development and characterization of innovative AEMs
The ECO2Fuel consortium aims to design, manufacture, operate, and validate the worldwide first low-temperature 1MW direct, electrochemical CO2 conversion system to produce economic and sustainable e-fuels and chemicals.
Hydrolite is focusing on the development and scaling of advanced anion exchange membranes (AEMs) tailored for CO₂ electrolysis. These membranes are crucial for the electrolyser's performance, requiring high ionic conductivity, chemical stability, and resistance to gas crossover under harsh operational conditions.
The Sustainable Product Initiative (SPI) promotes sustainable, recyclable, and durable products in sectors like electronics, textiles, and chemicals. The BIOPYRANIA consortium supports this effort by developing innovative, biobased pyrazine compounds from second-generation woody biomass. These sustainable building blocks are designed for high-performance use in the automotive and green hydrogen industries.
Hydrolite is tasked with integrating these novel bio-based materials into advanced anion exchange membranes (AEMs) for electrolyzers and fuel cells, aiming to replace fossil-based membranes with bio-based alternatives by 2030
SpinCat consortium aims to lower the cost of membrane-based electrolysers by developing efficient, PGM-free catalysts. The project will create a new class of magnetic, earth-abundant catalysts that enhance OER activity via spin polarization—tripling performance over current technologies. Combining theory and experiments, SpinCat will optimize these materials, deepen understanding of magnetic effects in electrocatalysis, and build a general theoretical model. A magnetically enhanced AEM electrolyser prototype will demonstrate these advances, supporting Europe’s leadership in renewable hydrogen production.
Hydrolite is responsible for developing new AEM materials and MEA to test the novel catalysts under laboratory-scale AEM electrolysis conditions
Hydrolite won (2021) a BIRD Energy grant to develop a 5 kW AEM fuel cell system for telecom use, integrating AEM membranes and enabling broader hydrogen-to-power applications.