Summary
Emerging materials science and nanoscale engineering spawn extraordinary structures. During my ERC-StG, I discovered a new family of internally-ordered 3D atomic laminates that I coined i-MAX. More recently, these phases have been used to derive a new type of 2D solids, MXenes, with ordered vacancies. Here, I consolidate research to establish a world-leading research environment with a mission to understand and exploit yet wider classes of unique functional materials; the next generation of 2D materials, beyond MXenes, from selective etching of recurring layers in 3D precursor solids.
Fundamental investigations of this project have as objectives to:
1) Use a theory-assisted search, including screening of open data bases, for design of new multifunctional 2D materials.
2) Perform precise-controlled synthesis/derivation of novel 3D/2D materials based on chemical exfoliation.
3-4) Explore nanoscale engineering and property tailoring, specifically targeting 2D materials for energy storage, catalysis, and other areas where low-dimensional solids can provide unique and sustainable solutions.
5) Provide proof-of-concept for novel materials in device applications.
Research breakthroughs and corresponding societal impact are envisioned as novel 2D materials provide superior properties in devices made from sustainable elements and processing. Functionalized freestanding sheets of new 2D materials are expected to have a major impact on supercapacitors and batteries, and as a catalytic material, realizing efficient hydrogen evolution. Initial results attest to this. Pioneering a new generation of 2D materials holds exceptional potential for discoveries, for use in applications meeting global challenges pertaining to energy and environment, and beyond. My experience as an international research leader gives me confidence to take on this greater challenge for innovation. Thus, an outstanding research constellation can be constituted, delivering groundbreaking research.
Fundamental investigations of this project have as objectives to:
1) Use a theory-assisted search, including screening of open data bases, for design of new multifunctional 2D materials.
2) Perform precise-controlled synthesis/derivation of novel 3D/2D materials based on chemical exfoliation.
3-4) Explore nanoscale engineering and property tailoring, specifically targeting 2D materials for energy storage, catalysis, and other areas where low-dimensional solids can provide unique and sustainable solutions.
5) Provide proof-of-concept for novel materials in device applications.
Research breakthroughs and corresponding societal impact are envisioned as novel 2D materials provide superior properties in devices made from sustainable elements and processing. Functionalized freestanding sheets of new 2D materials are expected to have a major impact on supercapacitors and batteries, and as a catalytic material, realizing efficient hydrogen evolution. Initial results attest to this. Pioneering a new generation of 2D materials holds exceptional potential for discoveries, for use in applications meeting global challenges pertaining to energy and environment, and beyond. My experience as an international research leader gives me confidence to take on this greater challenge for innovation. Thus, an outstanding research constellation can be constituted, delivering groundbreaking research.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101087713 |
| Start date: | 01-09-2023 |
| End date: | 31-08-2028 |
| Total budget - Public funding: | 1 999 940,00 Euro - 1 999 940,00 Euro |
Cordis data
Original description
Emerging materials science and nanoscale engineering spawn extraordinary structures. During my ERC-StG, I discovered a new family of internally-ordered 3D atomic laminates that I coined i-MAX. More recently, these phases have been used to derive a new type of 2D solids, MXenes, with ordered vacancies. Here, I consolidate research to establish a world-leading research environment with a mission to understand and exploit yet wider classes of unique functional materials; the next generation of 2D materials, beyond MXenes, from selective etching of recurring layers in 3D precursor solids.Fundamental investigations of this project have as objectives to:
1) Use a theory-assisted search, including screening of open data bases, for design of new multifunctional 2D materials.
2) Perform precise-controlled synthesis/derivation of novel 3D/2D materials based on chemical exfoliation.
3-4) Explore nanoscale engineering and property tailoring, specifically targeting 2D materials for energy storage, catalysis, and other areas where low-dimensional solids can provide unique and sustainable solutions.
5) Provide proof-of-concept for novel materials in device applications.
Research breakthroughs and corresponding societal impact are envisioned as novel 2D materials provide superior properties in devices made from sustainable elements and processing. Functionalized freestanding sheets of new 2D materials are expected to have a major impact on supercapacitors and batteries, and as a catalytic material, realizing efficient hydrogen evolution. Initial results attest to this. Pioneering a new generation of 2D materials holds exceptional potential for discoveries, for use in applications meeting global challenges pertaining to energy and environment, and beyond. My experience as an international research leader gives me confidence to take on this greater challenge for innovation. Thus, an outstanding research constellation can be constituted, delivering groundbreaking research.
Status
SIGNEDCall topic
ERC-2022-COGUpdate Date
31-07-2023
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