Abstract
Photonic antennas are critical in applications such as spectroscopy, photovoltaics, optical communications, holography, and sensors. In most of those applications, metallic antennas have been employed due to their reduced sizes. Nevertheless, compact metallic antennas suffer from high dissipative loss, wavelength-dependent radiation pattern, and they are difficult to integrate with CMOS technology. All-dielectric antennas have been proposed to overcome those disadvantages because, in contrast to metallic ones, they are CMOS-compatible, easier to integrate with typical silicon waveguides, and they generally present a broader wavelength range of operation. These advantages are achieved, however, at the expense of larger footprints that prevent dense integration and their use in massive phased arrays. In order to overcome this drawback, we employ topological optimization to design an all-dielectric compact antenna with vertical emission over a broad wavelength range. The fabricated device has a footprint of 1.78 µm × 1.78 µm and shows a shift in the direction of its main radiation lobe of only 4° over wavelengths ranging from 1470 nm to 1550 nm and a coupling efficiency bandwidth broader than 150 nm.
Highlights
Antennas operating at optical frequencies are becoming an essential part in applications from spectroscopy [1,2,3], communications [4,5,6,7], and photovoltaics [8, 9], to optical sensors [10, 11] and holography [12]
Photonic antennas are critical in applications such as spectroscopy, photovoltaics, optical communications, holography, and sensors
Compact metallic antennas suffer from high dissipative loss, wavelength-dependent radiation pattern, and they are difficult to integrate with CMOS technology
Summary
Antennas operating at optical frequencies are becoming an essential part in applications from spectroscopy [1,2,3], communications [4,5,6,7], and photovoltaics [8, 9], to optical sensors [10, 11] and holography [12]. The first nano-antennas were made of metals, usually gold These nano-antennas present a compact footprint because they support plasmonic resonances, but they suffer from high dissipative loss and challenging feeding mechanisms that result in poor radiation efficiency [13, 14]. Another drawback of metallic nano-antennas is that, owing to their resonant nature, their radiation pattern depends significantly on the wavelength and, they operate over a limited bandwidth. Far-field measurements reveal that the optimized design results in an almost vertical emission from 1470 nm to 1550 nm, standing out as an excellent candidate for high data rate communications
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