AccelOnChip | Attosecond physics, free electron quantum optics, photon generation and radiation biology with the accelerator on a photonic chip

Summary
Resting on our demonstration of laser-driven nanophotonics-based particle acceleration, we propose to build a miniature particle accelerator on a photonic chip, comprising high gradient acceleration and fully optical field-based electron control. The resulting electron beam has outstanding space-time properties: It is bunched on sub-femtosecond timescales, is nanometres wide and coherent. We aim at utilizing this new form of all-optical free electron control in a broad research program with five exciting objectives:
(1) Build a 5 MeV accelerator on a photonic chip in a shoebox-sized vessel,
(2) Perform ultrafast diffraction with attosecond and even zeptosecond electron pulses,
(3) Generate photons on chip at various wavelengths (IR to x-ray),
(4) Couple quantum-coherently electron wavepackets and light in multiple interaction zones, and
(5) Conduct radiobiological experiments, akin to the new FLASH radiotherapy and Microbeam cell treat-ment.

AccelOnChip will enable five science objectives potentially shifting the horizons of today’s knowledge and capabilities around ultrafast electron imaging, photon generation, (quantum) electron-light coupling, and radiotherapy dramatically. Moreover, AccelOnChip promises to democratize accelerators: the accelerator on a chip will be based on inexpensive nanofabrication technology. We foresee that every university lab can have access to particle and light sources, today only accessible at large facilities. Last, AccelOnChip will take decisive steps towards an ultracompact electron beam radiation device to be put into the tip of a catheter, a potentially disruptive radiation therapy device facilitating new treatment forms. AccelOnChip is a cross-disciplinary high risk/high return project combining and benefiting nanophotonics, accelerator science, ultra-fast physics, materials science, coherent light-matter coupling, light generation, and radiology - and is based on my group’s unique expertise acquired in recent years.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/884217
Start date: 01-10-2020
End date: 30-09-2025
Total budget - Public funding: 2 498 507,50 Euro - 2 498 507,00 Euro
Cordis data

Original description

Resting on our demonstration of laser-driven nanophotonics-based particle acceleration, we propose to build a miniature particle accelerator on a photonic chip, comprising high gradient acceleration and fully optical field-based electron control. The resulting electron beam has outstanding space-time properties: It is bunched on sub-femtosecond timescales, is nanometres wide and coherent. We aim at utilizing this new form of all-optical free electron control in a broad research program with five exciting objectives:
(1) Build a 5 MeV accelerator on a photonic chip in a shoebox-sized vessel,
(2) Perform ultrafast diffraction with attosecond and even zeptosecond electron pulses,
(3) Generate photons on chip at various wavelengths (IR to x-ray),
(4) Couple quantum-coherently electron wavepackets and light in multiple interaction zones, and
(5) Conduct radiobiological experiments, akin to the new FLASH radiotherapy and Microbeam cell treat-ment.

AccelOnChip will enable five science objectives potentially shifting the horizons of today’s knowledge and capabilities around ultrafast electron imaging, photon generation, (quantum) electron-light coupling, and radiotherapy dramatically. Moreover, AccelOnChip promises to democratize accelerators: the accelerator on a chip will be based on inexpensive nanofabrication technology. We foresee that every university lab can have access to particle and light sources, today only accessible at large facilities. Last, AccelOnChip will take decisive steps towards an ultracompact electron beam radiation device to be put into the tip of a catheter, a potentially disruptive radiation therapy device facilitating new treatment forms. AccelOnChip is a cross-disciplinary high risk/high return project combining and benefiting nanophotonics, accelerator science, ultra-fast physics, materials science, coherent light-matter coupling, light generation, and radiology - and is based on my group’s unique expertise acquired in recent years.

Status

SIGNED

Call topic

ERC-2019-ADG

Update Date

27-04-2024
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Horizon 2020
H2020-EU.1. EXCELLENT SCIENCE
H2020-EU.1.1. EXCELLENT SCIENCE - European Research Council (ERC)
ERC-2018
ERC-2019-ADG