Summary
AMOS represents a ground-breaking approach to achieve uni-directional motion on well-defined surfaces, realize cooperative motor activity, control flow processes and transport cargo at the atomic scale. It is based on molecule-surface motors that overcome microscopic reversibility via controlled potential energy surface modulation with high potential impact in various fields. Light will be used to excite molecular motion, offering great versatility. Hence, the stimulus is given remotely to many molecules, while characterization is done at the single-molecule level, allowing for statistical analysis of trajectories in two dimensions.
Different motor concepts will be used to controllably modulate the potential energy surfaces and address the key challenges in the field of molecular machines at surfaces. A variety of highly defined surfaces will be employed and novel adsorbate motors, molecules that achieve motor functionality only when joint together with a surface, will be studied. Advanced control of motion will be achieved by multiple motors. Complementary methods in microscopy, spectroscopy and interferometry with extremely high resolution in space, energy and time will be used – a key aspect of this project.
AMOS addresses both fundamental research and technological aspects: it will yield elementary understanding of molecular motors with extremely high spatial (pm) and temporal (fs) resolution and investigate model systems for future applications with insight at the single-molecule level. It will explore collectivity to amplify motor activity by cooperative effects in precisely defined assemblies and will study these systems also under environmental conditions in view of steered flow processes at the solid-liquid interface. Specific chemical interaction will realize transport and delivery of single or few atoms cargo with individual motor molecules, a fundamental step towards bottom-up construction of matter by molecular machines.
Different motor concepts will be used to controllably modulate the potential energy surfaces and address the key challenges in the field of molecular machines at surfaces. A variety of highly defined surfaces will be employed and novel adsorbate motors, molecules that achieve motor functionality only when joint together with a surface, will be studied. Advanced control of motion will be achieved by multiple motors. Complementary methods in microscopy, spectroscopy and interferometry with extremely high resolution in space, energy and time will be used – a key aspect of this project.
AMOS addresses both fundamental research and technological aspects: it will yield elementary understanding of molecular motors with extremely high spatial (pm) and temporal (fs) resolution and investigate model systems for future applications with insight at the single-molecule level. It will explore collectivity to amplify motor activity by cooperative effects in precisely defined assemblies and will study these systems also under environmental conditions in view of steered flow processes at the solid-liquid interface. Specific chemical interaction will realize transport and delivery of single or few atoms cargo with individual motor molecules, a fundamental step towards bottom-up construction of matter by molecular machines.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101097326 |
| Start date: | 01-01-2024 |
| End date: | 31-12-2028 |
| Total budget - Public funding: | 2 499 909,00 Euro - 2 499 909,00 Euro |
Cordis data
Original description
AMOS represents a ground-breaking approach to achieve uni-directional motion on well-defined surfaces, realize cooperative motor activity, control flow processes and transport cargo at the atomic scale. It is based on molecule-surface motors that overcome microscopic reversibility via controlled potential energy surface modulation with high potential impact in various fields. Light will be used to excite molecular motion, offering great versatility. Hence, the stimulus is given remotely to many molecules, while characterization is done at the single-molecule level, allowing for statistical analysis of trajectories in two dimensions.Different motor concepts will be used to controllably modulate the potential energy surfaces and address the key challenges in the field of molecular machines at surfaces. A variety of highly defined surfaces will be employed and novel adsorbate motors, molecules that achieve motor functionality only when joint together with a surface, will be studied. Advanced control of motion will be achieved by multiple motors. Complementary methods in microscopy, spectroscopy and interferometry with extremely high resolution in space, energy and time will be used – a key aspect of this project.
AMOS addresses both fundamental research and technological aspects: it will yield elementary understanding of molecular motors with extremely high spatial (pm) and temporal (fs) resolution and investigate model systems for future applications with insight at the single-molecule level. It will explore collectivity to amplify motor activity by cooperative effects in precisely defined assemblies and will study these systems also under environmental conditions in view of steered flow processes at the solid-liquid interface. Specific chemical interaction will realize transport and delivery of single or few atoms cargo with individual motor molecules, a fundamental step towards bottom-up construction of matter by molecular machines.
Status
SIGNEDCall topic
ERC-2022-ADGUpdate Date
31-07-2023
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