期刊
LIGHT-SCIENCE & APPLICATIONS
卷 5, 期 -, 页码 -出版社
CHINESE ACAD SCIENCES, CHANGCHUN INST OPTICS FINE MECHANICS AND PHYSICS
DOI: 10.1038/lsa.2016.34
关键词
diffraction; Fourier optics; optical computing; optical information processing; surface plasmon polaritons
类别
资金
- National Natural Science Foundation of China [61427819]
- Ministry of Science and Technology of China under National Basic Research Program of China (973) grant [2015CB352004]
- Discovery Early Career Researcher Award - Australian Research Council [DE120102352, DE130100954]
- La Trobe Research Focus Area (RFA) of Understanding Diseases
- Melbourne Collaboration Grant
- Interdisciplinary Seed Fund through the Melbourne Materials Institute (MMI)
- Defence Science Institute, Australia
- Advanced Optics in Engineering Programme from the Agency for Science, Technology and Research (A*STAR) [122-360-0009]
- Singapore Ministry of Education Academic Research Fund Tier 3 [MOE2011-T3-1-005]
- A*STAR
- Australian Research Council [DE120102352, DE130100954] Funding Source: Australian Research Council
The Fourier transform (FT), a cornerstone of optical processing, enables rapid evaluation of fundamental mathematical operations, such as derivatives and integrals. Conventionally, a converging lens performs an optical FT in free space when light passes through it. The speed of the transformation is limited by the thickness and the focal length of the lens. By using the wave nature of surface plasmon polaritons (SPPs), here we demonstrate that the FT can be implemented in a planar configuration with a minimal propagation distance of around 10 mm, resulting in an increase of speed by four to five orders of magnitude. The photonic FT was tested by synthesizing intricate SPP waves with their Fourier components. The reduced dimensionality in the minuscule device allows the future development of an ultrafast on-chip photonic information processing platform for large-scale optical computing.
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