Building the basis for the green hydrogen economy

Researcher Lira Garcia Barros at hydrogen setup. Photo: Bart van Overbeeke
Researcher Lira Garcia Barros at hydrogen setup. Photo: Bart van Overbeeke
Thanks to a National Growth Fund grant, TU/e researchers will increase knowledge in the Netherlands about generating hydrogen.

Green hydrogen can be a foundation for the energy transition to a sustainable energy supply and chemical industry. That is the vision pursued by the National Growth Fund program Groenvermogen NL. As part of this program, the HyPRO Being one of the 58 partners in this project, TU/e will develop new knowledge in four areas.

/ Sonja Knols

Hydrogen is regarded as an essential component in the energy and resources transition: the light gas can be used to store sustainably generated energy temporarily, and it can act as a building block for a chemical industry that is not based on fossils.

Groenvermogen NL, an innovation program receiving ¤838 million from the National Growth Fund, aims to establish a national ecosystem for green hydrogen and green chemistry in the Netherlands. The overall program includes seven work packages, which, for example, deal with transport, storage, and use of hydrogen.

Making hydrogen

"But it all starts with the hydrogen production," states Niels Deen , Professor of Multiphase and Reactive Flows at the Department of Mechanical Engineering. Deen and several other TU/e colleagues attended the so-called ’sandbox’, a multi-day meeting where universities, knowledge institutions, government, and companies jointly shaped the HyPRO project.

From water to hydrogen

Splitting water into hydrogen and oxygen with electricity generated by solar panels and wind turbines is a logical route when thinking about hydrogen production, says Thijs de Groot , Associate Professor of Electrochemical Process Technology in the Department of Chemical Engineering and Chemistry.

" Large-scale electrolyzers for water splitting have been around for a long time. However, up until now, they have been powered by a continuous source of electricity, such as a hydroelectric plant. When we talk about green hydrogen, we have to switch to renewable electricity from sun and wind. These power sources are variable: at one instant, you might have a large supply of electricity, and later that day, perhaps you have nothing."

Green-generated power sources are erratic - sometimes you have a big supply, and other times, nothing at all.

Thijs de Groot, associate professor of electrochemical process technology
"In the HyPRO project, one of the things we are looking at is how this intermittent supply of electricity influences the operation of the electrolyzer. What processes cause the degradation we witness when we frequently turn an electrolyzer on and off’ And how can we improve the yield of the water splitting process’," says De Groot.

Deen says the HyPRO "There was an open call inviting everyone who thought they could contribute anything to this topic. We sat down with 60 people for a few days to shape the outline of the program."

It was jointly decided that the 17 research institutions and 41 companies would work together within five program lines. Four of these address different technologies for producing hydrogen, and the fifth line focuses on the question of how hydrogen can fit into the future’s energy system and chemical industry.

Added value of EIRES

Deen says that the fact that TU/e has pooled its energy research in EIRES has certainly helped to bring TU/e to the table on the right topics.

"We already had a good idea of who was working on what within our own university. For me, the fact that as a researcher you can break free from your own expertise and really speak on behalf of the entire university is a clear added value of such an interdisciplinary institute."

Within the 50 million euro HyPRO project, TU/e is involved in researching three different ways to produce hydrogen and the system integration aspect.

Who does what

Deen: "It takes a lot of green power to produce green hydrogen. That means you’re going to have a huge grid load somewhere. Colleagues at the Department of Electrical Engineering led by Koen Kok will investigate the most logical way to fit this load to the grid, for example, by combining a hydrogen production site with an offshore wind farm."

"When it comes to the technologies used, there is a project at the Department of Applied Physics and Science Education led by Adriana Creatore on new materials for catalysts that can make the production process more efficient. At the chemistry department, Thijs de Groot will look at alkaline electrolyzers and Toni Forner-Cuenca at porous electrodes."

"Maike Baltussen from the Department of Chemical Engineering and Chemistry and Yali Tang from my own group at Mechanical Engineering will focus on simulating electrolyzers. We can hire two PhD students and four postdocs within HyPRO," Deen summarizes.

Optimizing electrolyzers

"One of the research topics within HyPRO coincides seamlessly with the research within my group," says De Groot.

"We are studying alkaline electrolyzers to increase their lifetime, hydrogen yield, and flexibility. Within HyPRO, among other things, we want to work toward a good protocol to test new designs, materials, and components for electrolyzers in a standard way to enable quick statements about the expected long-term performance of a system."

The perfect membrane

De Groot’s research also looks at the various components that make up the electrolyzer, intending to optimize the system. "For example, we are looking at the membranes that separate the produced hydrogen and oxygen. If such a membrane is too thick, the electrical resistance in the electrolyzer increases."

"As a result, less hydrogen is produced. On the other hand, if it is too thin, it allows hydrogen gas to pass through, which can lead to the formation of an explosive mixture."

The challenge of electrolyzers is that everything is related to everything else.Finding the ultimate optimum is, therefore, difficult.

Thijs de Groot, associate professor of electrochemical process technology
"The challenge of electrolyzers is that everything is related to everything else; finding the ultimate optimum is difficult. So, the first step is to find out which knobs we need to turn in which ways to make the process suitable for large-scale and economically viable production of green hydrogen."

Deen says that is also the goal of the HyPRO research that will be conducted in his group. "In an electrolyzer, hydrogen is created in the form of bubbles. But those bubbles introduce an additional electrical resistance. With simulations, we are going to map how the design and use of the electrolyzer affects this resistance, with the ultimate goal of increasing the efficiency of the process."

Most promising technology

Though there are several ways to make hydrogen, De Groot thinks alkaline electrolysis has the best papers.

"Other technologies rely on rare materials or are significantly more expensive. Therefore, it is quite likely that bulk production will be via alkaline water electrolyzers. I believe in that technology; otherwise, I wouldn’t be working on it. But there is still a lot that can be improved. Green hydrogen is still grossly expensive, which does not help its large-scale implementation."


I believe in electrolysers, otherwise I wouldn’t be working on them.

Thijs de Groot, associate professor of electrochemical process technology
And that large-scale implementation is necessary, De Geroot quickly calculates. "It starts, of course, with the question, ’How big is green hydrogen going to be’’ We’re not going to put that in cars, but mainly use it for the industry for everything that can’t be electrified, to make chemicals and green steel, for example."

"Then you need a lot of hydrogen: we now foresee that we will need terawatts of electrolyzers by 2050. We are now at 1 to 2 gigawatts of capacity. That means we need to scale up by a factor of a thousand."

Fast network-building

To accelerate this development, it is essential to bring academia and industry close together, both Deen and De Groot believe. An initiative like Groenvermogen NL is indispensable for this.

Deen: "The good thing about the sandbox process was that it forced the scientific and business communities to listen to each other and discover together what questions exist and what tools are available to answer them."

Because we came together physically with 58 parties, you immediately have a face with a company.That makes it easier to contact each other with questions. Niels Deen, professor Multiphase and Reactive Flows
"Because we came together physically with 58 parties, we built a network in a very short time. The fact that we can now put a face with a company makes it much easier to contact each other for other questions."


"Though I have worked in the industry and already know many parties, there are also partners involved within HyPRO I hadn’t collaborated with before, such as Battolyser Systems and AVOXT," De Groot adds.

"The consortium is very broad: it includes suppliers of complete electrolyzers and parties that supply membranes and build stacks. You need that to develop a technology that can enter the market quickly and make a real difference."

Hydrogen as a regional competence

As part of Groenvermogen NL, De Groot announces that there will also be a program that invests in human capital in the scope of the hydrogen economy.

"Three million euros will go to the Brainport region within this framework. Nine regional companies are already involved in HyPRO, particularly in the manufacturing industry. Eventually, we hope to launch a hydrogen competence center with the Human Capital program in Eindhoven. It would only be logical to involve the regional companies we already collaborate with within HyPRO."

About the HyPRO consortium

HyPRO is a collaboration of ten universities, five colleges, two research institutes, and more than forty companies.

The partners within HyPRO are: TNO, Utrecht University, Leiden University, TU Delft, Rijksuniversiteit Groningen, Maastricht University, TU Eindhoven, Radboud University, University of Amsterdam, University of Twente, Differ, Wageningen University, Saxion Hogeschool, Avans Hogeschool, Fontys Hogeschool, HAN, Hanzehogeschool Groningen, Total Energies, Shell, LYB, Johnsons Matthey, Braskem, RWE, Vatenfall, Eneco, VS Particle, Ionbond, Hauzer, Powall, SALD, SparkNano, Veco, BASF, Nanao Hybrids, FujiFilm, Teijin, Bosal Group, I-Qatalyst, Vitrite, VDL, NEWES, AVOXT, Circonica, Battolyser Systems, Bosch, Dr Ten, SolydEra, TOPSoe, Hyet, PRODRIVE, Sairem, On2Quest, Adsensys, Fluidwell, Sitech, Total Support, HyStream, FEV energy, ELEXEL.