nOVel low-prEssure cRyogenic Liquid hydrogEn storAge For aviation.

Climate, Energy & MobilityHORIZON-RIAID: 101056818
EC Contribution
€59,517
Consortium Size
13 orgs
Start Year
2022
Summary

In order to meet the objectives of the European Green Deal by 2050 in the aviation sector, the transition towards H2-powered aviation is the solution with the most potential. Although hydrogen-powered aircrafts exist, the current cost of storing and using H2 as a fuel in prolonged flights make their democratization impossible. The main blocking point is the absence of viable storage systems of H2 in aircrafts considering the strict limitations in terms of weight, volume, and cost-efficiency. A sensitivity analysis shows how the economics depend on the tank’s gravimetric index (GI). Today’s technology can barely achieve 20% GI for 500kg of H2, while industry actors need at the very least 35% GI for 500kg of H2 to transition towards H2-powered aviation. OVERLEAF intends to develop a game changer Liquid Hydrogen (LH2) storage tank to enable the transition towards H2-powered aviation. Based on a disruptive design (under patent process) and leveraging innovative materials and technologies, the OVERLEAF solution is expected to boast a GI higher than 60% for 500kg of LH2, with no venting over 24h. Furthermore, the concept is an enabler for using the aircraft’s fuselage as the outer tank, allowing to seamlessly integrate the tank in the aircrafts structure.OVERLEAF will have an interdisciplinary R&D approach focusing on advance materials engineering, testing and combination at lab and at pilot scale, together with appropriate simulation of different design architectures of the hydrogen storage system. The project will be based on three distinctive phases and implemented in 7 Work Packages. The consortium includes multidisciplinary partners from 6 different EU countries and contains all the necessary expertise and know-how to carry-out all tasks needed to achieve OVERLEAF’s ambitious objective.

Consortium (13)

Project Results (13)

Source: CORDIS, the EU research results database.

Publications (8)
A step towards multipoint hydrogen sensing: development of metal hydride-coated FBG hydrogen sensors
29th International Conference on Optical Fiber Sensors· 2025DOI
Kasun Prabuddha Wasantha Dissanayake, H. Sandra Dewi, Ziqing Yuan, Herman Schreuders, Lars J. Bannenberg, Roger M. Groves
Optical Hydrogen Sensing Materials for Applications at SubZero Temperatures
Advanced Functional Materials· 2025DOI
Ziqing Yuan, Herman Schreuders, Robert Dankelman, Bernard Dam, Lars J. Bannenberg
Tantalum-palladium alloy based optical micro-mirror hydrogen sensor
Sensors and Actuators B: Chemical· 2025DOI
D.J. Verhoeff; H. Schreuders; L.J. Bannenberg
Advancing Hydrogen Sensing for Sustainable Aviation: A Metal Hydride Coated TFBG Optical Fibre Hydrogen Sensor
e-Journal of Nondestructive Testing· 2024DOI
Dissanayake, Kasun P.; Dewi, H. Sandra; Schreuders, Herman; Bannenberg, Lars J.; Groves, Roger M.
Advancing Hydrogen Sensing for Sustainable Aviation: A Metal Hydride Coated TFBG Optical Fibre Hydrogen Sensor
e-Journal of Nondestructive Testing· 2024DOI
null null, Kasun P. Dissanayake, null null, H. Sandra Dewi, null null, Herman Schreuders, null null, Lars J. Bannenberg, null null, Roger M. Groves
Damage Classification of a Bolted Connection using Guided Waves and Explainable Artificial Intelligence
Procedia Structural Integrity· 2024DOI
Muping Hu, Nan Yue, Roger M. Groves
Design of a metal hydride-coated tilted fibre Bragg grating (TFBG) based hydrogen sensor
Optical Sensing and Detection VIII· 2024DOI
Kasun Prabuddha Wasantha Dissanayake, H. Sandra Dewi, Herman Schreuders, Lars J. Bannenberg, Roger M. Groves
Metal hydride hydrogen sensing materials from 28 C to 270 C
International Journal of Hydrogen Energy· 2024DOI
H.S. Dewi, K.P. Dissanayake, H. Schreuders, R.M. Groves, L.J. Bannenberg
Deliverables (4)
Other Results (1)
Periodic Reporting for period 1 - OVERLEAF (nOVel low-prEssure cRyogenic Liquid hydrogEn storAge For aviation.)