Full Color 3D Meta-Holography Based on Achromatic Fresnel Near-Field Diffraction Algorithm

Ruo Nan Ji; Xin Ru Zheng; Yi Long Li; Xin Xie; Fan Chuan Lin; Chao Liu; Yi Wei Zheng; Pei Qi Yu; Xin Ru Li; Kun Song; Zhen Fei Li; Wei Lu; Shuang Zhang; Shao Wei Wang; Di Wang; Qiong Hua Wang

doi:10.1002/lpor.202500398

Full Color 3D Meta-Holography Based on Achromatic Fresnel Near-Field Diffraction Algorithm

Ruo Nan Ji, Xin Ru Zheng, Yi Long Li, Xin Xie, Fan Chuan Lin, Chao Liu, Yi Wei Zheng, Pei Qi Yu, Xin Ru Li, Kun Song, Zhen Fei Li, Wei Lu, Shuang Zhang, Shao Wei Wang, Di Wang, Qiong Hua Wang

Institute for Advanced Study in Precision Spectroscopy

Research output: Contribution to journal › Article › peer-review

Abstract

Metasurface, composed of sub-wavelength unit cells, can provide unprecedented control over the wavefront and bring new opportunities for the development of holography. How to realize achromatic color meta-holography has always been an urgent problem in meta-holography. Here, a full-color 3D meta-holography based on an achromatic Fresnel near-field diffraction algorithm is proposed to break through the chromatic aberration limitation inherent in traditional meta-holography. Such a characteristic allows for the achievement of achromatic color holography, without necessitating any adjustments to the optical system or the metasurfaces. Utilizing a Pancharatnam-Berry geometric-phase-based metasurface, an achromatic holography is experimentally demonstrated with a 5000 × 5000 resolution, 17 mm depth, and a 68° viewing angle. This technology significantly increases the degree of freedom in design and application, and it is also expected to be applied to other holographic optical devices such as holographic lenses, thereby avoiding complex achromatic design processes.

Original language	English
Article number	e00398
Journal	Laser and Photonics Reviews
Volume	19
Issue number	18
DOIs	https://doi.org/10.1002/lpor.202500398
State	Published - 18 Sep 2025

Keywords

chromatic aberration
full-color
meta-holography
metasurfaces

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10.1002/lpor.202500398

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Ji, R. N., Zheng, X. R., Li, Y. L., Xie, X., Lin, F. C., Liu, C., Zheng, Y. W., Yu, P. Q., Li, X. R., Song, K., Li, Z. F., Lu, W., Zhang, S., Wang, S. W., Wang, D., & Wang, Q. H. (2025). Full Color 3D Meta-Holography Based on Achromatic Fresnel Near-Field Diffraction Algorithm. Laser and Photonics Reviews, 19(18), Article e00398. https://doi.org/10.1002/lpor.202500398

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title = "Full Color 3D Meta-Holography Based on Achromatic Fresnel Near-Field Diffraction Algorithm",

abstract = "Metasurface, composed of sub-wavelength unit cells, can provide unprecedented control over the wavefront and bring new opportunities for the development of holography. How to realize achromatic color meta-holography has always been an urgent problem in meta-holography. Here, a full-color 3D meta-holography based on an achromatic Fresnel near-field diffraction algorithm is proposed to break through the chromatic aberration limitation inherent in traditional meta-holography. Such a characteristic allows for the achievement of achromatic color holography, without necessitating any adjustments to the optical system or the metasurfaces. Utilizing a Pancharatnam-Berry geometric-phase-based metasurface, an achromatic holography is experimentally demonstrated with a 5000 × 5000 resolution, 17 mm depth, and a 68° viewing angle. This technology significantly increases the degree of freedom in design and application, and it is also expected to be applied to other holographic optical devices such as holographic lenses, thereby avoiding complex achromatic design processes.",

keywords = "chromatic aberration, full-color, meta-holography, metasurfaces",

author = "Ji, \{Ruo Nan\} and Zheng, \{Xin Ru\} and Li, \{Yi Long\} and Xin Xie and Lin, \{Fan Chuan\} and Chao Liu and Zheng, \{Yi Wei\} and Yu, \{Pei Qi\} and Li, \{Xin Ru\} and Kun Song and Li, \{Zhen Fei\} and Wei Lu and Shuang Zhang and Wang, \{Shao Wei\} and Di Wang and Wang, \{Qiong Hua\}",

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doi = "10.1002/lpor.202500398",

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T1 - Full Color 3D Meta-Holography Based on Achromatic Fresnel Near-Field Diffraction Algorithm

AU - Ji, Ruo Nan

AU - Zheng, Xin Ru

AU - Li, Yi Long

AU - Xie, Xin

AU - Lin, Fan Chuan

AU - Liu, Chao

AU - Zheng, Yi Wei

AU - Yu, Pei Qi

AU - Li, Xin Ru

AU - Song, Kun

AU - Li, Zhen Fei

AU - Lu, Wei

AU - Zhang, Shuang

AU - Wang, Shao Wei

AU - Wang, Di

AU - Wang, Qiong Hua

PY - 2025/9/18

Y1 - 2025/9/18

N2 - Metasurface, composed of sub-wavelength unit cells, can provide unprecedented control over the wavefront and bring new opportunities for the development of holography. How to realize achromatic color meta-holography has always been an urgent problem in meta-holography. Here, a full-color 3D meta-holography based on an achromatic Fresnel near-field diffraction algorithm is proposed to break through the chromatic aberration limitation inherent in traditional meta-holography. Such a characteristic allows for the achievement of achromatic color holography, without necessitating any adjustments to the optical system or the metasurfaces. Utilizing a Pancharatnam-Berry geometric-phase-based metasurface, an achromatic holography is experimentally demonstrated with a 5000 × 5000 resolution, 17 mm depth, and a 68° viewing angle. This technology significantly increases the degree of freedom in design and application, and it is also expected to be applied to other holographic optical devices such as holographic lenses, thereby avoiding complex achromatic design processes.

AB - Metasurface, composed of sub-wavelength unit cells, can provide unprecedented control over the wavefront and bring new opportunities for the development of holography. How to realize achromatic color meta-holography has always been an urgent problem in meta-holography. Here, a full-color 3D meta-holography based on an achromatic Fresnel near-field diffraction algorithm is proposed to break through the chromatic aberration limitation inherent in traditional meta-holography. Such a characteristic allows for the achievement of achromatic color holography, without necessitating any adjustments to the optical system or the metasurfaces. Utilizing a Pancharatnam-Berry geometric-phase-based metasurface, an achromatic holography is experimentally demonstrated with a 5000 × 5000 resolution, 17 mm depth, and a 68° viewing angle. This technology significantly increases the degree of freedom in design and application, and it is also expected to be applied to other holographic optical devices such as holographic lenses, thereby avoiding complex achromatic design processes.

KW - chromatic aberration

KW - full-color

KW - meta-holography

KW - metasurfaces

UR - https://www.scopus.com/pages/publications/105011052642

U2 - 10.1002/lpor.202500398

DO - 10.1002/lpor.202500398

M3 - 文章

AN - SCOPUS:105011052642

SN - 1863-8880

VL - 19

JO - Laser and Photonics Reviews

JF - Laser and Photonics Reviews

IS - 18

M1 - e00398

ER -

Full Color 3D Meta-Holography Based on Achromatic Fresnel Near-Field Diffraction Algorithm

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