NSF Award
1345168
This Small Business Innovation Research (SBIR) Phase I project positions a stepping stone in the chasm between fundamental new physics insights relating to the structure of matter and an aggressive approach to commercializing "Semiconductors of Light" in emerging markets which include photonic integrated circuits (PICs) for high density optical interconnects. Prior assumptions that periodicity was essential to forming the photonic band gaps (PBGs) necessary to create "Semiconductors of Light" have recently been proven false. New structures, characterized by suppressed density fluctuations (hyperuniformity), include disordered structures that exhibit photonic band gaps which are isotropic. This loosens layout constraints and reduces fabrication tolerances for PBG PICs relative to "Semiconductors of Light" based on photonic crystals. Research objectives include the use of hyperuniformly disordered PBGs in the design of PBG-based PIC modulators. This research will leverage entirely new classes of both symmetric and asymmetric resonant light defect structures in a new kind of designer dielectric capable of isotropic light control. Anticipated technical results include higher-performance optical modulators for photonic integrated circuits providing improvements in wavelength density per unity chip area, reduced energy requirements, and improved fabrication tolerance.<br/><br/>The broader impact/commercial potential of this project is to apply a newly-discovered structure of solid matter to the elimination of bandwidth bottlenecks that might otherwise constrain the growth of cloud computing business models and threaten continued free availability to the public of increasingly advanced network services. The $3.3B optical interconnect market projected for 2015 will include a rapidly-growing family of high-density optical transceivers priced for datacenter applications operating at rates of 400 Gb/s and beyond. Market entry will require a disruptive rather than just an incremental technological improvement. Commercialization of photonic integrated circuits based on newly-discovered hyperuniformly disordered structures (HUDS) disrupts the current trend toward photonic integrated circuits (PICs) made with silicon photonics microring resonators (MRRs) because HUDS-enabled PBG resonant structures are ~100x smaller in chip area than MRRs. The smaller volume of PBG resonant structures relative to MRRs has been shown to enable lower energy per bit modulation. Finally, HUDs-enabled PBG PICs are expected to be less sensitive to temperature than MRRs. These advantages of HUDS-enabled PBG PICs, along with the improved fabrication tolerance, layout flexibility, and isotropy of HUDS, promise to provide lower cost, more compact, and more energy-efficient optical transceivers for networking equipment and data center markets.
