Abstract
Terahertz integrated platforms with high efficiency are crucial in a broad range of applications including terahertz communications, radar, imaging and sensing. One key enabling technology is wideband interconnection. This work proposes substrate-less all-dielectric waveguides defined by an effective medium with a subwavelength hole array. These self-supporting structures are built solely into a single silicon wafer to minimize significant absorption in metals and dielectrics at terahertz frequencies. In a stark contrast to photonic crystal waveguides, the guiding mechanism is not based on a photonic bandgap but total internal reflections The waveguides are discussed in the context of terahertz communications that imposes stringent demands on performance. Experimental results show that the realized waveguides can cover the entire 260-400 GHz with single dominant modes in both orthogonal polarizations and an average measured attenuation around 0.05 dB/cm. Limited by the measurement setup, the maximum error-free data rate up to 30 Gbit/s is experimentally achieved at 335 GHz on a 3-cm waveguide. We further demonstrate the transmission of uncompressed 4K-resolution video across this waveguide. This waveguide platform promises integration of diverse active and passive components. Thus, we can foresee it as a potential candidate for the future terahertz integrated circuits, in analogy to photonic integrated circuits at optical frequencies. The proposed concept can potentially benefit integrated optics at large.
Highlights
Terahertz communications is a promising modality for future short-range point-topoint wireless data transmission at rates up to terabit per second
To achieve an integrated waveguide platform with low loss and structural simplicity, all-dielectric 2D photonic crystal waveguides built from a single silicon wafer were proposed
Both the simulated and measured transmission levels are lower at the lower frequencies because of the higher coupling losses caused by the slight impedance and mode mismatches between the sample and the feed
Summary
Terahertz communications is a promising modality for future short-range point-topoint wireless data transmission at rates up to terabit per second. The prospective data rate carried by a terahertz channel can reach 1 Tbit/s over the distance of several kilometres.4 Reaching this theoretical capacity calls for solutions to several challenges, including the significant power losses in integrated transmitter and receiver components that compromise signal quality. An alternative is substrate-integrated image guide (SIIG) technology that employs metal-grounded dielectric waveguides.9,10 This type of waveguide could achieve an average transmission loss of 0.45 dB/cm from 85 to 90 GHz, and 0.35 dB/cm from 110 to 170 GHz.. This type of waveguide could achieve an average transmission loss of 0.45 dB/cm from 85 to 90 GHz, and 0.35 dB/cm from 110 to 170 GHz.10 While these metal-based guiding structures are efficient at microwave and millimetre-wave frequencies, they are not suitable to terahertz integrated systems due to the increased losses and bandwidth restrictions. A propagation loss of less than 0.1 dB/cm could be demonstrated from 319 to 337 GHz, while another similar design could yield an enhanced bandwidth of 324– 361 GHz with comparable losses. these photonic crystal waveguides have relatively narrow bandwidths and strong in-band dispersion related to the intrinsic photonic bandgap (PBG) phenomenon
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