The manipulation of light waves has been a long-standing goal for scientists seeking to enhance the efficiency of energy and information transmission. The phenomenon of light diffraction, where waves spread out as they propagate, has posed a challenge to maintaining the shape and direction of light beams. In recent decades, significant breakthroughs have been made in controlling the structure of light, leading to the emergence of non-diffracting light fields.

In 1979, Berry and colleagues predicted the existence of Airy beams (ABs) that exhibit self-acceleration and self-bending without diffraction. Subsequently, in 1987, J. Durnin introduced Bessel beams (BBs) as a solution to the wave equation that can suppress diffraction. These discoveries have paved the way for advancements in both fundamental optics and practical applications.

Traditionally, devices for modulating non-diffracting light fields have been bulky and limited in resolution. However, the development of metasurfaces has revolutionized optical technology by using nanoscale antenna arrays to achieve precise control of light fields. By leveraging birefringence, metasurfaces enable multidimensional manipulation of light, making them a key enabler for next-generation photonic integrated platforms.

A recent study published in the journal Laser & Photonics Reviews highlights a breakthrough in reconstructing non-diffracting light fields. The research team successfully observed the transformation of circularly Airy beams (CABs) into BBs along the propagation path by implementing a mechanism of joint local-global phase control. This innovative approach allowed for the encoding of complex, non-diffracting optical fields with high precision.

The research team decomposed the 2D problem into 1D phase functions and superposed 2D phase functions to modulate the metasurface. Through theoretical analysis and ray tracing techniques, they illustrated the transformation process, likening it to the “Transformers” of the optical domain. By leveraging triple birefringent nanoantennas, the team introduced novel techniques for structuring light fields, expanding the number of light field types to six.

This research represents a pivotal step in the utilization of non-diffracting light fields and the enhancement of metasurface functionality. The findings lay a solid foundation for the development of advanced on-chip, nano-optical platforms and innovative manufacturing technologies. The implications of this research are profound, as it has the potential to drive optical device performance and functionality to new heights, shaping the future of optical technology.

The evolution of non-diffracting light fields represents a significant breakthrough in optical technology. By harnessing the power of metasurfaces and innovative phase control mechanisms, researchers are paving the way for a new era of optical devices with enhanced capabilities. The implications of this research extend beyond the laboratory, offering promising opportunities for the advancement of optical technologies in various fields.

Science

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