Hy-MAP 2.0 - Hydrogen mapping in hydrogen storage materials
Find Similar History 13 Claim Ownership Request Data Change Add FavouriteTitle
CoPED ID
Status
Value
Start Date
End Date
Description
The growing environmental challenges have made decarbonisation a global priority. Renewable energy is key for decarbonisation, but their broad deployment requires **sufficient energy storage technologies** to balance the mismatch of intermittent renewable supply with electricity demand. Towards this goal, hydrogen has been rightfully acknowledged as a highly suitable renewable energy carrier.
Hydrogen is **notoriously difficult to store**, as conventional storage methods require extreme conditions (e.g. high pressures or low temperatures). At H2GO we have **developed and deployed** a solid-state hydrogen storage technology that is a **safer, cheaper and denser alternative** to conventional storage technologies. Our technology exploits the reversible chemical bond that hydrogen forms with other molecules, allowing for storing and releasing hydrogen in cycles to be carried out **several thousand times**.
However, while applying these cycles in our patented storage technology, we observed an **oxidation effect** when our storage materials are **exposed to oxygen and water molecules** (e.g. moisture present in air) which can affect their performance and lifetime. As we scale up production, our manual reactor filling process **needs to be upgraded to an automated process** while **mitigating any oxidation effects** during filling. Thus understanding the exact effects of oxidation and when they are most likely to occur will allow a targeted process for filling our reactors, in turn making our product more efficient and competitive.
Using the National Physical Laboratory (NPL) state-of-art facilities and expertise in preparing reference gases, we will carry out **a detailed investigation of these oxidation effects** for our storage materials, providing valuable information on the most suitable automatic filling process to adopt.
We will be using nano-SIMS (Secondary Ions Mass Spectrometry), to define the effects and extent of oxidation caused by a set of specially prepared reference gases. SIMS is **one of the rare techniques that can map the distribution of hydrogen and oxygen isotopes**, at 100 nm spatial resolution. We will use this method to **examine the relation of our hydrogen storage materials with oxygen and water molecules** together with the effects that they may bring to our materials.
There are **few laboratories globally** that have these capabilities and expertise **all under one roof**, and thus NPL is well positioned to undertake these measurement challenges.
| H2GO POWER LTD | LEAD_ORG |
| NPL MANAGEMENT LIMITED | PARTICIPANT_ORG |
| H2GO POWER LTD | PARTICIPANT_ORG |
| Federico Pesci | PM_PER |
Subjects by relevance
- Hydrogen
- Warehousing
- Oxygen
- Renewable energy sources
- Technology
- Oxidation (passive)
Extracted key phrases
- State hydrogen storage technology
- Hydrogen storage material
- Sufficient energy storage technology
- Hydrogen mapping
- Conventional storage technology
- Patented storage technology
- Conventional storage method
- Hy
- Suitable renewable energy carrier
- Oxidation effect
- Suitable automatic filling process
- Manual reactor filling process
- Intermittent renewable supply
- MAP
- Exact effect