Design and optimization of zone plates for flying focus applications
Authors
Zhengkun Li, Yisong Zhou, Changbo Fu, Yugang Ma
Categories
Abstract
Flying focus laser pulse technology, characterized by programmable velocity profiles and the ability to break the traditional link between focal spot motion and group velocity constraints, holds significant potential for revolutionary advances in high-intensity laser related fields. However,the flying focus generated with conventional approaches suffers from a low maximum intensity, as the energy is spread over a long distance, and the size of the focusing optics is also limited. Here, we propose a zone-plate-based flying focus scheme in which the zone widths are modulated by a sinusoidal random distribution. Numerical simulations show that the high-order foci produced by the modulated zone plate can be suppressed by more than two orders of magnitude. Meanwhile, the scheme sustains a high-intensity focal region extending over more than 100 Rayleigh lengths. Furthermore, the focal speed can be tuned over a wide range, including values exceeding the speed of light in vacuum. Owing to these advantages, the proposed modulated zone-plate scheme offers new possibilities for high-intensity laser physics and holds promise for applications such as laser wakefield acceleration, photon acceleration, and more.
Design and optimization of zone plates for flying focus applications
Categories
Abstract
Flying focus laser pulse technology, characterized by programmable velocity profiles and the ability to break the traditional link between focal spot motion and group velocity constraints, holds significant potential for revolutionary advances in high-intensity laser related fields. However,the flying focus generated with conventional approaches suffers from a low maximum intensity, as the energy is spread over a long distance, and the size of the focusing optics is also limited. Here, we propose a zone-plate-based flying focus scheme in which the zone widths are modulated by a sinusoidal random distribution. Numerical simulations show that the high-order foci produced by the modulated zone plate can be suppressed by more than two orders of magnitude. Meanwhile, the scheme sustains a high-intensity focal region extending over more than 100 Rayleigh lengths. Furthermore, the focal speed can be tuned over a wide range, including values exceeding the speed of light in vacuum. Owing to these advantages, the proposed modulated zone-plate scheme offers new possibilities for high-intensity laser physics and holds promise for applications such as laser wakefield acceleration, photon acceleration, and more.
Authors
Zhengkun Li, Yisong Zhou, Changbo Fu et al. (+1 more)
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