High-NA Achromatic Metalenses by Inverse Design (1905.09213v1)

Abstract: We use inverse design to discover metalens structures that exhibit broadband, achromatic focusing across low, moderate, and high numerical apertures. We show that standard unit-cell approaches cannot achieve high-efficiency high-NA focusing, even at a single frequency, due to the incompleteness of the unit-cell basis, and we provide computational upper bounds on their maximum efficiencies. At low NA, our devices exhibit the highest theoretical efficiencies to date. At high NA -- of 0.9 with translation-invariant films and of 0.99 with "freeform" structures -- our designs are the first to exhibit achromatic high-NA focusing.

High-NA Achromatic Metalenses by Inverse Design

The paper "High-NA Achromatic Metalenses by Inverse Design" presented by Haejun Chung and Owen D. Miller explores the optimization of metalens structures for broadband achromatic focusing across varying numerical apertures (NA) using a computational approach grounded in inverse design. This research explores the limitations of traditional unit-cell approaches and introduces inverse design as a method to achieve superior lens performance.

Summary of Findings

Traditional designs for metasurface lenses, or metalenses, often utilize an overview of wavelength-scale resonators into a larger device. Such approaches have shown promise for focusing but are hindered by inefficiencies related to narrow operational bandwidths, restrictions in numerical aperture, and low focusing efficiencies. This research establishes theoretical constructs demonstrating that unit-cell designs fail to achieve high efficiency at high NAs due to the incomplete representation basis. Alternatively, it presents inverse design as a computational method that optimizes geometrical degrees of freedom to discover metalenses with high numerical apertures that operate over visible bandwidths with optimal focusing efficiencies.

1. Inverse Design Methodology:
   • Inverse design allows for rapid computation of gradients with respect to a large number of geometrical degrees of freedom.
   • By utilizing a minimax formulation of design criteria, this approach identifies designs ready for fabrication that achieve both high NA and broad bandwidth control.
2. Capability Demonstration:
   • The research showcases the ability of inverse design to yield metalens structures exhibiting high NA achromatic focusing, a milestone not achievable through conventional methods.

Technical Insights and Numerical Analysis

• Achievements at Low NA: At low numerical apertures, the devices show the highest theoretical efficiencies recorded thus far.
• High NA Accomplishments: For high NA implementations with translation-invariant as well as freeform structures, the designs achieve unprecedented achromatic focusing capabilities.

Practical and Theoretical Implications

The practical significance of this research is profound. High-efficiency metalenses with high NA are poised to revolutionize optical technology in applications like microscopy, imaging, and integrated optics. Theoretically, the findings challenge conventional design paradigms and signal a shift towards more computationally intensive optimization methods in optical device engineering.

Future research could explore scalability for larger devices, integration with different materials for reduced dispersion, and potential multi-layered metastructures that could further enhance the degree of achievable functionalities. Moreover, advancements in simulation and solver technologies could facilitate the extension of these methods to macroscopic devices, thereby broadening the scope of possible applications.

Conclusion

The paper by Chung and Miller underscores the potential of inverse design to surpass traditional optical design methods, offering a pathway to metalenses characterized by high efficiency, broad bandwidth, and significant numerical aperture, all within the visible spectrum. Through this approach, the design space is more thoroughly explored, and complex trade-offs between bandwidth, numerical aperture, and efficiency are effectively mitigated, illustrating the transformative impact of computational methodologies in photonics.