In this paper, we design and simulate a new dual-band ultrathin metasurface energy harvester (EH) in X- and V-bands. One of the significant advantages of the proposed EH is the efficiency, which is more than 70% over 170○ of the TM-polarized oblique incident angles at f = 10 GHz. The full-wave simulation results show that the maximum harvesting efficiencies of 93.4% (in 10.1 GHz) and 84.3% (in 42.86 GHz) are obtained by the TM 75○-polarized and the normal incident waves, respectively. Besides, half-power bandwidths (ratios) are about 1.12 GHz (11.08%) and 2.36 GHz (5.5%), respectively. The designed unit-cell is miniaturized using a C-shaped slot with the dimensions of 0.1λ0× 0.1λ0 × 0.008λ0 at the lowest resonance frequency (λ0 = 30.12 mm). To analyze the physical mechanism of energy harvesting, the full-wave simulation results of the current and electric field distributions at two resonance frequencies are presented. We demonstrate how the rotation of the load around the metallic via can affect the resonance frequency and the other characteristics of the EH at the X-band. We validate the load’s rotation effects using the waveguide measurement method as well. Finally, we show that the location of the metallic via has a greater impact compared to the load’s rotation using the full-wave numerical simulation at the X-band.

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