TY - JOUR
T1 - Coherent nanophotonic electron accelerator
AU - Chlouba, Tomáš
AU - Shiloh, Roy
AU - Kraus, Stefanie
AU - Brückner, Leon
AU - Litzel, Julian
AU - Hommelhoff, Peter
N1 - Publisher Copyright:
© 2023, The Author(s), under exclusive licence to Springer Nature Limited.
PY - 2023/10/19
Y1 - 2023/10/19
N2 - Particle accelerators are essential tools in a variety of areas of industry, science and medicine 1–4. Typically, the footprint of these machines starts at a few square metres for medical applications and reaches the size of large research centres. Acceleration of electrons with the help of laser light inside of a photonic nanostructure represents a microscopic alternative with potentially orders-of-magnitude decrease in cost and size 5–16. Despite large efforts in research on dielectric laser acceleration 17,18, including complex electron phase space control with optical forces 19–21, noteworthy energy gains have not been shown so far. Here we demonstrate a scalable nanophotonic electron accelerator that coherently combines particle acceleration and transverse beam confinement, and accelerates and guides electrons over a considerable distance of 500 μm in a just 225-nm-wide channel. We observe a maximum coherent energy gain of 12.3 keV, equalling a substantial 43% energy increase of the initial 28.4 keV to 40.7 keV. We expect this work to lead directly to the advent of nanophotonic accelerators offering high acceleration gradients up to the GeV m−1 range utilizing high-damage-threshold dielectric materials 22 at minimal size requirements 14. These on-chip particle accelerators will enable transformative applications in medicine, industry, materials research and science 14,23,24.
AB - Particle accelerators are essential tools in a variety of areas of industry, science and medicine 1–4. Typically, the footprint of these machines starts at a few square metres for medical applications and reaches the size of large research centres. Acceleration of electrons with the help of laser light inside of a photonic nanostructure represents a microscopic alternative with potentially orders-of-magnitude decrease in cost and size 5–16. Despite large efforts in research on dielectric laser acceleration 17,18, including complex electron phase space control with optical forces 19–21, noteworthy energy gains have not been shown so far. Here we demonstrate a scalable nanophotonic electron accelerator that coherently combines particle acceleration and transverse beam confinement, and accelerates and guides electrons over a considerable distance of 500 μm in a just 225-nm-wide channel. We observe a maximum coherent energy gain of 12.3 keV, equalling a substantial 43% energy increase of the initial 28.4 keV to 40.7 keV. We expect this work to lead directly to the advent of nanophotonic accelerators offering high acceleration gradients up to the GeV m−1 range utilizing high-damage-threshold dielectric materials 22 at minimal size requirements 14. These on-chip particle accelerators will enable transformative applications in medicine, industry, materials research and science 14,23,24.
UR - http://www.scopus.com/inward/record.url?scp=85174451774&partnerID=8YFLogxK
U2 - 10.1038/s41586-023-06602-7
DO - 10.1038/s41586-023-06602-7
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C2 - 37853151
AN - SCOPUS:85174451774
SN - 0028-0836
VL - 622
SP - 476
EP - 480
JO - Nature
JF - Nature
IS - 7983
ER -