Design and validation of an accelerator for an ultracold electron source

G. Taban; M.P. Reijnders; S.C. Bell; S.B. Geer, van der; O.J. Luiten; E.J.D. Vredenbregt

doi:10.1103/PhysRevSTAB.11.050102

Design and validation of an accelerator for an ultracold electron source

G. Taban, M.P. Reijnders, S.C. Bell, S.B. Geer, van der, O.J. Luiten, E.J.D. Vredenbregt

Coherence and Quantum Technology

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Abstract

We describe here a specially designed accelerator structure and a pulsed power supply that are essential parts of a high brightness cold atoms-based electron source. The accelerator structure allows a magneto-optical atom trap to be operated inside of it, and also transmits subnanosecond electric field pulses. The power supply produces high voltage pulses up to 30 kV, with a rise time of up to 30 ns. The resulting electric field inside the structure is characterized with an electro-optic measurement and with an ion time-of-flight experiment. Simulations predict that 100 fC electron bunches, generated from trapped atoms inside the structure, reach an emittance of 0.04 mm mrad and a bunch length of 80 ps.

Original language	English
Pages (from-to)	050102-1/8
Journal	Physical Review Special Topics - Accelerators and Beams
Volume	11
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevSTAB.11.050102
Publication status	Published - 2008

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abstract = "We describe here a specially designed accelerator structure and a pulsed power supply that are essential parts of a high brightness cold atoms-based electron source. The accelerator structure allows a magneto-optical atom trap to be operated inside of it, and also transmits subnanosecond electric field pulses. The power supply produces high voltage pulses up to 30 kV, with a rise time of up to 30 ns. The resulting electric field inside the structure is characterized with an electro-optic measurement and with an ion time-of-flight experiment. Simulations predict that 100 fC electron bunches, generated from trapped atoms inside the structure, reach an emittance of 0.04 mm mrad and a bunch length of 80 ps.",

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AU - Reijnders, M.P.

AU - Bell, S.C.

AU - Geer, van der, S.B.

AU - Luiten, O.J.

AU - Vredenbregt, E.J.D.

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AB - We describe here a specially designed accelerator structure and a pulsed power supply that are essential parts of a high brightness cold atoms-based electron source. The accelerator structure allows a magneto-optical atom trap to be operated inside of it, and also transmits subnanosecond electric field pulses. The power supply produces high voltage pulses up to 30 kV, with a rise time of up to 30 ns. The resulting electric field inside the structure is characterized with an electro-optic measurement and with an ion time-of-flight experiment. Simulations predict that 100 fC electron bunches, generated from trapped atoms inside the structure, reach an emittance of 0.04 mm mrad and a bunch length of 80 ps.

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JF - Physical Review Special Topics - Accelerators and Beams

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Design and validation of an accelerator for an ultracold electron source

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