achieving high holographic image quality. By elaborately arranging the geometries of nanoantennas [3] or orientation angles [4,5] of metaatoms, desired abrupt interfacial phase shift at designated points within subwavelength thickness can be realized. Therefore, metasurface has been applied to versatile applications, including directional radiators, [6] thin-film cloaking, [7,8] planar lenses, [9] optical vortex beam generators, [10,11] and digital holograms. [12][13][14][15][16] Compared to the hologram based on traditional optical devices, metasurface hologram improves imaging efficiency, [17] spatial resolution, [18] and robustness against fabrication tolerances. [19] Hence, metasurface holograms have been widely applied in the terahertz, infrared, and visible frequency bands. Nevertheless, the transmittance efficiency of transmission-phaseonly metasurface hologram is still limited by cross-polarization transformation losses.Huygens metasurface can significantly improve the transmittance efficiency and achieve full phase-shift coverage, since it enables to fully control the phase and amplitude of copolarized transmitted wave without polarization conversion losses by integrating designed electric and magnetic dipoles into each metaatom. [20] On account of its superior wave-manipulating ability, various correlative researches have been reported in beam-refracting, [21] focusing, [22,23] beam-shaping, [24] and holographic imaging. [25] Here, we experimentally realize microwave holographic imaging recorded by Huygens metasurfaces with the modulation of focal intensity distribution. By judiciously designing geometrical parameters of electric and magnetic dipoles, 15 metaatoms which cover a 2π phase range with close-to-unity transmission amplitude are extracted for holographic imaging. Moreover, a new holographic algorithm is presented to divert the incident energy to specified focal positions and adjust the energy allocation among focal points. Three parameters are adopted in this work to evaluate the main aspects of image quality, including transmittance efficiency, imaging efficiency, and root-mean-square error (RMSE) of focal intensity ratio. The numerical simulations and experimental results of holographic images carried out in the microwave regime agree well with theoretical predictions, which verify the feasibility and outstanding image quality of the proposed Huygens metasurface holograms, paving the way toward highly efficient microwave holographic imaging.Huygens metasurface, an implementation of Huygens principle with metasurface, shows great potential in the manipulation of electromagnetic wave by elaborately designed subwavelength scale metaatoms with full phase coverage and high transmission amplitude. Here, a multiphase hologram with Huygens metasurface is demonstrated in microwave regime, and a novel algorithm method is proposed to modulate energy distribution among focal points. The proof-of-concept experiments show superior microwave holographic images with 89% transmittance efficiency, 59% imaging...
