Summary
Observing hydrogen (H) in matter is a formidable challenge. Despite being ubiquitous in nature, it is elusive
to scientific scrutiny like no other element. It is often portrayed as either a blessing or a curse. Certainly, it is
a prime candidate for producing low-carbon emission power. But no less important is the effect of hydrogen
embrittlement which has resulted in many catastrophic failures of engineering alloys.
In aid of this, SHINE will realise multiple ambitions. It will facilitate the direct imaging and quantification of
H atoms in candidate metallic alloys and metal-organic frameworks for gaseous storage, allow the discovery
of new solid-state hydrides with controlled release, and help the improvement of fuel cell materials for
energy generation. All these applications have relevance to a ‘low-carbon-emission economy’ that humanity
must develop in the 21st century.
SHINE will exploit a novel and entirely unique infrastructure, designed and currently implemented in the
PI’s group. It will directly provide three-dimensional hydrogen mapping at the near-atomic scale. By
connecting and relating this fundamental knowledge and observed physical properties, we will enable
unprecedented precision in the prediction of material behaviour and so resolve to unlock control over the
behaviour of hydrogen in such materials.
Atom probe tomography will be the principal method of a correlative microscopy and spectroscopy approach
to investigate materials where precise knowledge of the distribution of H is crucial. Informed by
experimental data, modelling and simulations will provide a mechanistic understanding of the behaviour of
H in materials. Novel hardware and data-treatment approaches will be developed to maximise data quality
and provide new insights of the behaviour of H in the complex and dynamic microstructures of engineering
materials, thereby allowing us to devise manufacturing strategies to enhance their performance and
durability.
to scientific scrutiny like no other element. It is often portrayed as either a blessing or a curse. Certainly, it is
a prime candidate for producing low-carbon emission power. But no less important is the effect of hydrogen
embrittlement which has resulted in many catastrophic failures of engineering alloys.
In aid of this, SHINE will realise multiple ambitions. It will facilitate the direct imaging and quantification of
H atoms in candidate metallic alloys and metal-organic frameworks for gaseous storage, allow the discovery
of new solid-state hydrides with controlled release, and help the improvement of fuel cell materials for
energy generation. All these applications have relevance to a ‘low-carbon-emission economy’ that humanity
must develop in the 21st century.
SHINE will exploit a novel and entirely unique infrastructure, designed and currently implemented in the
PI’s group. It will directly provide three-dimensional hydrogen mapping at the near-atomic scale. By
connecting and relating this fundamental knowledge and observed physical properties, we will enable
unprecedented precision in the prediction of material behaviour and so resolve to unlock control over the
behaviour of hydrogen in such materials.
Atom probe tomography will be the principal method of a correlative microscopy and spectroscopy approach
to investigate materials where precise knowledge of the distribution of H is crucial. Informed by
experimental data, modelling and simulations will provide a mechanistic understanding of the behaviour of
H in materials. Novel hardware and data-treatment approaches will be developed to maximise data quality
and provide new insights of the behaviour of H in the complex and dynamic microstructures of engineering
materials, thereby allowing us to devise manufacturing strategies to enhance their performance and
durability.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/771602 |
| Start date: | 01-02-2018 |
| End date: | 31-01-2023 |
| Total budget - Public funding: | 2 000 000,00 Euro - 2 000 000,00 Euro |
Cordis data
Original description
Observing hydrogen (H) in matter is a formidable challenge. Despite being ubiquitous in nature, it is elusiveto scientific scrutiny like no other element. It is often portrayed as either a blessing or a curse. Certainly, it is
a prime candidate for producing low-carbon emission power. But no less important is the effect of hydrogen
embrittlement which has resulted in many catastrophic failures of engineering alloys.
In aid of this, SHINE will realise multiple ambitions. It will facilitate the direct imaging and quantification of
H atoms in candidate metallic alloys and metal-organic frameworks for gaseous storage, allow the discovery
of new solid-state hydrides with controlled release, and help the improvement of fuel cell materials for
energy generation. All these applications have relevance to a ‘low-carbon-emission economy’ that humanity
must develop in the 21st century.
SHINE will exploit a novel and entirely unique infrastructure, designed and currently implemented in the
PI’s group. It will directly provide three-dimensional hydrogen mapping at the near-atomic scale. By
connecting and relating this fundamental knowledge and observed physical properties, we will enable
unprecedented precision in the prediction of material behaviour and so resolve to unlock control over the
behaviour of hydrogen in such materials.
Atom probe tomography will be the principal method of a correlative microscopy and spectroscopy approach
to investigate materials where precise knowledge of the distribution of H is crucial. Informed by
experimental data, modelling and simulations will provide a mechanistic understanding of the behaviour of
H in materials. Novel hardware and data-treatment approaches will be developed to maximise data quality
and provide new insights of the behaviour of H in the complex and dynamic microstructures of engineering
materials, thereby allowing us to devise manufacturing strategies to enhance their performance and
durability.
Status
CLOSEDCall topic
ERC-2017-COGUpdate Date
27-04-2024
Images
No images available.
Geographical location(s)
Search
