New paradigms in materials and devices for hybrid electro-optics and optical rectification

We review recent transformative advances in materials design, synthesis, and processing as well as device engineering for the utilization of organic materials in hybrid electro-optic (EO) and optical rectification (OR) technologies relevant to telecommunications, sensing, and computing. End-to-end (from molecules to systems) modeling methods utilizing multi-scale computation and theory permit prediction of the performance of novel materials in nanoscale device architectures including those involving plasmonic phenomena and architectures in which interfacial effects play a dominant role. Both EO and OR phenomenon require acentric organization of constituent active molecules. The incumbent methodology for achieving such organization is electric field poling, where chromophore shape, dipole moment, and conformational flexibility play dominant roles. Optimized chromophore design and control of the poling process has already led to record-setting advances in electro-optic performance, e.g., voltage-length performance of < 50 volt-micrometer, bandwidths < 500 GHz, and energy efficiency < 70 attojoule/bit. They have also led to increased thermal stability, low insertion loss and high signal quality (BER and SFDR). However, the limits of poling in the smallest nanophotonic devices—in which extraordinary optical field densities can be achieved—has stimulated development of alternatives based on covalent coupling of modern high-performance chromophores into ordered nanostructures. Covalent coupling enables higher performance, greater scalability, and greater stability and is especially suited for the latest nanoscale architectures. Recent developments in materials also facilitate a new technology—transparent photodetection based on optical rectification. OR does not involve electronic excitation, as is the case with conventional photodiodes, and as such represents a novel detection mechanism with a greatly reduced noise floor. OR already dominates at THz frequencies and recent advances will enable superior performance at GHz frequencies as well.

[1]  Bruce H. Robinson,et al.  Ultrahigh Electro-Optic Coefficients, High Index of Refraction, and Long-Term Stability from Diels–Alder Cross-Linkable Binary Molecular Glasses , 2020, Chemistry of Materials.

[2]  S. Randel,et al.  Silicon-organic hybrid (SOH) Mach-Zehnder modulators for 100 GBd PAM4 signaling with sub-1 dB phase-shifter loss. , 2020, Optics express.

[3]  Juerg Leuthold,et al.  A monolithic bipolar CMOS electronic–plasmonic high-speed transmitter , 2020, Nature Electronics.

[4]  Juerg Leuthold,et al.  Plasmonic IQ modulators with attojoule per bit electrical energy consumption , 2019, Nature Communications.

[5]  C. Koos,et al.  Silicon-Organic Hybrid (SOH) and Plasmonic-Organic Hybrid (POH) Integration , 2015, Journal of Lightwave Technology.

[6]  Bruce H. Robinson,et al.  Matrix-Assisted Poling of Monolithic Bridge-Disubstituted Organic NLO Chromophores , 2014 .

[7]  Bruce H. Robinson,et al.  Toward optimal EO response from ONLO chromophores: a statistical mechanics study of optimizing shape , 2016 .

[8]  R Lawson,et al.  Optical modulation and detection in slotted Silicon waveguides. , 2005, Optics express.

[9]  T. Watanabe,et al.  Microwave plasmonic mixer in a transparent fibre-wireless link , 2018, Nature Photonics.

[10]  M. Lauermann,et al.  Ultra-high electro-optic activity demonstrated in a silicon-organic hybrid modulator , 2017, Optica.

[11]  V. Shalaev,et al.  1 Supplementary Information : Low loss Plasmon-assisted electro-optic modulator , 2018 .

[12]  Ruimin Xu,et al.  Benzocyclobutene barrier layer for suppressing conductance in nonlinear optical devices during electric field poling , 2014 .

[13]  P. Winzer,et al.  Integrated lithium niobate electro-optic modulators operating at CMOS-compatible voltages , 2018, Nature.

[14]  Antao Chen,et al.  Theory-guided design and synthesis of multichromophore dendrimers: an analysis of the electro-optic effect. , 2007, Journal of the American Chemical Society.

[15]  M. Burla,et al.  Plasmonic phased array feeder enabling ultra-fast beam steering at millimeter waves. , 2016, Optics express.

[16]  L. Dalton,et al.  Molecular Engineering of Structurally Diverse Dendrimers with Large Electro-Optic Activities. , 2019, ACS applied materials & interfaces.

[17]  J. V. D. van der Tol,et al.  Electro-Optic Slot Waveguide Phase Modulator on the InP Membrane on Silicon Platform , 2021, IEEE Journal of Quantum Electronics.

[18]  Juerg Leuthold,et al.  Large Pockels effect in micro- and nanostructured barium titanate integrated on silicon , 2018, Nature Materials.

[19]  Hermann Massler,et al.  500 GHz plasmonic Mach-Zehnder modulator enabling sub-THz microwave photonics , 2018, APL Photonics.

[20]  D. Hillerkuss,et al.  Optical Interconnect Solution With Plasmonic Modulator and Ge Photodetector Array , 2017, IEEE Photonics Technology Letters.

[21]  J. Faist,et al.  Compact and ultra-efficient broadband plasmonic terahertz field detector , 2019, Nature Communications.

[22]  J. Leuthold,et al.  100 GBd IM/DD transmission over 14 km SMF in the C-band enabled by a plasmonic SSB MZM. , 2020, Optics express.

[23]  K. Clays,et al.  Bis(4-dialkylaminophenyl)heteroarylamino donor chromophores exhibiting exceptional hyperpolarizabilities , 2021 .

[24]  Juerg Leuthold,et al.  Nonlinearities of organic electro-optic materials in nanoscale slots and implications for the optimum modulator design. , 2017, Optics express.

[25]  M. Lauermann,et al.  Hybrid electro-optic modulator combining silicon photonic slot waveguides with high-k radio-frequency slotlines , 2020, Optica.

[26]  E. Kriezis,et al.  Electro-optic modulation in integrated photonics , 2021, Journal of Applied Physics.

[27]  Wolfgang Freude,et al.  Silicon–Organic and Plasmonic–Organic Hybrid Photonics , 2017 .

[28]  Juerg Leuthold,et al.  Effect of Rigid Bridge-Protection Units, Quadrupolar Interactions, and Blending in Organic Electro-Optic Chromophores , 2017 .

[29]  Bart Kuyken,et al.  Taking silicon photonics modulators to a higher performance level: state-of-the-art and a review of new technologies , 2021, Advanced Photonics.

[30]  Wolfgang Freude,et al.  Demonstration of long-term thermally stable silicon-organic hybrid modulators at 85 °C. , 2018, Optics express.

[31]  David Hillerkuss,et al.  All-plasmonic Mach–Zehnder modulator enabling optical high-speed communication at the microscale , 2015, Nature Photonics.

[32]  T. Baehr‐Jones,et al.  Theoretical Study of Optical Rectification at Radio Frequencies in a Slot Waveguide , 2010, IEEE Journal of Quantum Electronics.

[33]  Bruce H. Robinson,et al.  Poling-induced birefringence in OEO materials under nanoscale confinement , 2018, Organic Photonics + Electronics.

[34]  Ronny Henker,et al.  Survey of Photonic and Plasmonic Interconnect Technologies for Intra-Datacenter and High-Performance Computing Communications , 2018, IEEE Communications Surveys & Tutorials.

[35]  Pascal A. Jud,et al.  Broadband Metallic Fiber-to-Chip Couplers and a Low-Complexity Integrated Plasmonic Platform , 2021, Nano letters.

[36]  K. Clays,et al.  Electro‐Optic Activity in Excess of 1000 pm V−1 Achieved via Theory‐Guided Organic Chromophore Design , 2021, Advanced materials.

[37]  L. Dalton,et al.  Optimization of plasmonic-organic hybrid electro-optics , 2018, 2017 IEEE Avionics and Vehicle Fiber-Optics and Photonics Conference (AVFOP).

[38]  Larry R Dalton,et al.  Electric field poled organic electro-optic materials: state of the art and future prospects. , 2010, Chemical reviews.