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The ordinary negative changing refractive index for estimation of optical confinement factor Cover

The ordinary negative changing refractive index for estimation of optical confinement factor

International Journal on Smart Sensing and Intelligent Systems
Volume 15 (2022): Issue 1 (January 2022)
By: Ahmad S. Abdullah and  Sadeq Adnan Hbeeb  
Open Access
|Jun 2022

References

  1. Akhtar, M. B. 2022. The use of a convolutional neural network in detecting soldering faults from a printed circuit board assembly. HighTech and Innovation Journal 3(1): 1–14.
    Search in Google ScholarBack to article
  2. Alexander, K., George, J. P., Verbist, J., Neyts, K., Kuyken, B., Van Thourhout, D. and Beeckman, J. 2018. Nanophotonic Pockels modulators on a silicon nitride platform. Nature communications 9(1): 3444.
    Search in Google ScholarBack to article
  3. Bea, S. and Teich, M. 1991. Fundamentals of photonics, Wiley, New York, p. 313.
    Search in Google ScholarBack to article
  4. Boes, A., Corcoran, B., Chang, L., Bowers, J. and Mitchell, A. 2018. Status and potential of lithium niobate on insulator (LNOI) for photonic integrated circuits. Laser & Photonics Reviews 12(4): 1700256.
    Search in Google ScholarBack to article
  5. Cai, L., Kang, Y. and Hu, H. 2016. Electric-optical property of the proton exchanged phase modulator in single-crystal lithium niobate thin film. Optics Express 24(5): 4640–4647.
    Search in Google ScholarBack to article
  6. Casson, J. L., Gahagan, K. T., Scrymgeour, D. and Jain, R. K. 2004. Electro-optic coefficients of lithium tantalate at near-infrared wavelengths. JOSA B 21(11): 1948–1952.
    Search in Google ScholarBack to article
  7. Chang, L., Pfeiffer, M. H. P., Volet, N., Zervas, M., Peters, J. D., Manganelli, C. L., Stanton, E. J., Li, Y., Kippenberg, T. J. and Bowers, J. E. 2017. Heterogeneous integration of lithium niobate and silicon nitride waveguides for wafer-scale photonic integrated circuits on silicon. Optics Letters 42(4): 803–806.
    Search in Google ScholarBack to article
  8. Chang, L., Li, Y., Volet, N., Wang, L., Peters, J. and Bowers, J. E. 2016. Thin film wavelength converters for photonic integrated circuits. Optica 3(5): 531–535.
    Search in Google ScholarBack to article
  9. Chen, L., Xu, Q., Wood, M. G. and Reano, R. M. 2014. Hybrid silicon and lithium niobate electro-optical ring modulator. Optica 1(2): 112–118.
    Search in Google ScholarBack to article
  10. Deshpande, R., Zenin, V. A., Ding, F., Mortensen, N. A. and Bozhevolnyi, S. I. 2018. Direct characterization of near-field coupling in gap plasmon-based metasurfaces. Nano Letters 18(10): 6265–6270.
    Search in Google ScholarBack to article
  11. DeVault, C. T., Zenin, V. A., Pors, A., Chaudhuri, K., Kim, J., Boltasseva, A., Shalaev, V. M. and Bozhevolnyi, S. I. 2018. Suppression of near-field coupling in plasmonic antennas on epsilon-near-zero substrates. Optica 5(12): 1557–1563.
    Search in Google ScholarBack to article
  12. Figura, C. C. 2000. Second order nonlinear optics in ionically self-assembled thin films. PhD Dissertation, Virginia Tech.
    Search in Google ScholarBack to article
  13. Girouard, P., Chen, P., Jeong, Y. K., Liu, Z., Ho, S. and Wessels, B. W. 2017. X-2 modulator with 40-GHz modulation utilizing BaTiO3 photonic crystal waveguides. IEEE Journal of Quantum Electronics 53(4): 1–10.
    Search in Google ScholarBack to article
  14. Guarino, A., Poberaj, G., Rezzonico, D., Degl’Innocenti, R. and Günter, P. 2007. Electro–optically tunable microring resonators in lithium niobate. Nature Photonics 1(7): 407–410.
    Search in Google ScholarBack to article
  15. Hagn, G. 2001. Electro-optic effects and their application in indium phosphide waveguide devices for fibre optic access networks. PhD dissertation, ETH Zurich.
    Search in Google ScholarBack to article
  16. He, M., Xu, M., Ren, Y., Jian, J., Ruan, Z., Xu, Y., Gao, S., Sun, S., Wen, X., Zhou, L., Liu, L., Guo, C., Chen, H., Yu, S., Liu, L. and Cai, X. 2019. High-performance hybrid silicon and lithium niobate Mach–Zehnder modulators for 100 Gbit s−1 and beyond. Nature Photonics 13(5): 359–364.
    Search in Google ScholarBack to article
  17. Janner, D., Tulli, D., García-Granda, M., Belmonte, M. and Pruneri, V. 2009. Micro-structured integrated electro-optic LiNbO3 modulators. Laser & Photonics Reviews 3(3): 301–313.
    Search in Google ScholarBack to article
  18. Jin, S., Xu, L., Zhang, H. and Li, Y. 2015. LiNbO3 thin-film modulators using silicon nitride surface ridge waveguides. IEEE Photonics Technology Letters 28(7): 736–739.
    Search in Google ScholarBack to article
  19. Korkishko, Y. N., Fedorov, V., De Micheli, M., Baldi, P., El Hadi, K. and Leycuras, A. 1996. Relationships between structural and optical properties of proton-exchanged waveguides on Z-cut lithium niobate. Applied Optics, 35(36): 7056–7060.
    Search in Google ScholarBack to article
  20. Lu, H., Sadani, B., Ulliac, G., Courjal, N., Guyot, C., Merolla, J.-M., Collet, M., Baida, F. I. and Bernal, M.-P. 2012a. 6-micron interaction length electro-optic modulation based on lithium niobate photonic crystal cavity. Optics Express 20(19): 20884–20893.
    Search in Google ScholarBack to article
  21. Lu, H., Sadani, B., Courjal, N., Ulliac, G., Smith, N., Stenger, V., Collet, M., Baida, F. I. and Bernal, M.-P. 2012b. Enhanced electro-optical lithium niobate photonic crystal wire waveguide on a smart-cut thin film. Optics Express 20(3): 2974–2981.
    Search in Google ScholarBack to article
  22. Luff, B. J., Wilkinson, J. S., Piehler, J., Hollenbach, U., Ingenhoff, J. and Fabricius, N. 1998. Integrated optical Mach–Zehnder biosensor, in. Journal of Lightwave Technology 16(4): 583–592.
    Search in Google ScholarBack to article
  23. Maldonado, T. A. 1995. Electro-optic modulators. Handbook of optics 2: 13–11.
    Search in Google ScholarBack to article
  24. Mercante, A. J., Shi, S., Yao, P., Xie, L., Weikle, R. M. and Prather, D. W. 2018. Thin film lithium niobate electro-optic modulator with terahertz operating bandwidth. Optics Express 26(11): 14810–14816.
    Search in Google ScholarBack to article
  25. Poberaj, G., Hu, H., Sohler, W. and Guenter, P. 2012. Lithium niobate on insulator (LNOI) for micro-photonic devices. Laser & photonics reviews 6(4): 488–503.
    Search in Google ScholarBack to article
  26. Priscilla, S. J., Judi, V. A., Daniel, R. and Sivaji, K. 2020. Effects of chromium doping on the electrical properties of ZnO nanoparticles. Emerging Science Journal 4(2): 82–88.
    Search in Google ScholarBack to article
  27. Qi, Y. and Li, Y. 2020. Integrated lithium niobate photonics, Nanophotonics, 9(6): 1287–1320.
    Search in Google ScholarBack to article
  28. Rao, A., Patil, A., Rabiei, P., Honardoost, A., DeSalvo, R., Paolella, A. and Fathpour, S. 2016. High-performance and linear thin-film lithium niobate Mach–Zehnder modulators on silicon up to 50 GHz. Optics Letters 41(24): 5700–5703.
    Search in Google ScholarBack to article
  29. Rao, A. and Fathpour, S. 2017. Compact lithium niobate electrooptic modulators. IEEE Journal of Selected Topics in Quantum Electronics 24(4): 1–14.
    Search in Google ScholarBack to article
  30. Roussey, M., Baida, F. I. and Bernal, M.-P. 2007. Experimental and theoretical observations of the slow-light effect on a tunable photonic crystal. JOSA B 24(6): 1416–1422.
    Search in Google ScholarBack to article
  31. Roussey, M., Bernal, M.-P., Courjal, N., Van Labeke, D., Baida, F. and Salut, R. 2006. Electro-optic effect exaltation on lithium niobate photonic crystals due to slow photons. Applied physics letters 89(24): 241110.
    Search in Google ScholarBack to article
  32. Scharnberg, A. A., de Loreto, A. C. and Alves, A. K. 2020. Optical and structural characterization of Bi2FexNbO7 nanoparticles for environmental applications. Emerging Science Journal 4(1): 11–17.
    Search in Google ScholarBack to article
  33. Sulser, F., Poberaj, G., Koechlin, M. and Günter, P. 2009. Photonic crystal structures in ion-sliced lithium niobate thin films. Optics Express 17(22): 20291–20300.
    Search in Google ScholarBack to article
  34. Tavlykaev, R. F. and Ramaswamy, R. V. 1999. Highly linear Y-fed directional coupler modulator with low intermodulation distortion. Journal of Lightwave Technology 17(2): 282.
    Search in Google ScholarBack to article
  35. Thomaschewski, M., Zenin, V. A., Wolff, C. and Bozhevolnyi, S. I. 2020. Plasmonic monolithic lithium niobate directional coupler switches. Nature Communications 11(1): 1–6.
    Search in Google ScholarBack to article
  36. Wang, C., Zhang, M., Chen, X., Bertrand, M., Shams-Ansari, A., Chandrasekhar, S., Winzer, P. and Lončar, M. 2018. Integrated lithium niobate electro-optic modulators operating at CMOS-compatible voltages. Nature 562(7725): 101–104.
    Search in Google ScholarBack to article
  37. Wang, X., Weigel, P. O., Zhao, J., Ruesing, M. and Mookherjea, S. 2019. Achieving beyond-100-GHz large-signal modulation bandwidth in hybrid silicon photonics Mach Zehnder modulators using thin film lithium niobate. APL Photonics 4(9): 096101.
    Search in Google ScholarBack to article
  38. Weigel, P. O., Zhao, J., Fang, K., Al-Rubaye, H., Trotter, D., Hood, D., Mudrick, J., Dallo, C., Pomerene, A. T., Starbuck, A. L., DeRose, C. T., Lentine, A. L., Rebeiz, G. and Mookherjea, S. 2018. Bonded thin film lithium niobate modulator on a silicon photonics platform exceeding 100 GHz 3-dB electrical modulation bandwidth. Optics Express 26(18): 23728–23739.
    Search in Google ScholarBack to article
  39. Wooten, E. L., Kissa, K. M., Yi-Yan, A., Murphy, E. J., Lafaw, D. A., Hallemeier, P. F., Maack, D., Attanasio, D. V., Fritz, D. J., McBrien, G. J. and Bossi, D. E. 2000. A review of lithium niobate modulators for fiber-optic communications systems. IEEE Journal of Selected Topics in Quantum Electronics 6(1): 69–82.
    Search in Google ScholarBack to article
  40. Xu, M., Chen, W., He, M., Wen, X., Ruan, Z., Xu, J., Chen, L., Liu, L., Yu, S. and Cai, X. 2019. Michelson interferometer modulator based on hybrid silicon and lithium niobate platform. APL Photonics 4(10): 100802.
    Search in Google ScholarBack to article
  41. Xu, M., He, M., Zhang, H., Jian, J., Pan, Y., Liu, X., Chen, L., Meng, X., Chen, X., Li, Z., Xiao, X., Yu, S. and Cai, X. 2020. High-performance coherent optical modulators based on thin-film lithium niobate platform. Nature Communications 11(1): 1–7.
    Search in Google ScholarBack to article
  42. Yi-Yan, A. 1983. Index instabilities in proton-exchanged LiNbO3 waveguides. Applied Physics Letters, 42,(8): 633–635.
    Search in Google ScholarBack to article
  43. Zenin, V. A., Choudhury, S., Saha, S., Shalaev, V. M., Boltasseva, A. and Bozhevolnyi, S. I. 2017. Hybrid plasmonic waveguides formed by metal coating of dielectric ridges. Optics Express 25(11): 12295–12302.
    Search in Google ScholarBack to article
  44. Zenin, V. A., Volkov, V. S., Han, Z., Bozhevolnyi, S. I., Devaux, E. and Ebbesen, T. W. 2012. Directional coupling in channel plasmon-polariton waveguides. Optics Express 20(6): 6124–6134.
    Search in Google ScholarBack to article
DOI: https://doi.org/10.2478/ijssis-2022-0009 | Journal eISSN: 1178-5608
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Language: English
Submitted on: Dec 23, 2021
Published on: Jun 29, 2022
Published by: Professor Subhas Chandra Mukhopadhyay
In partnership with: Paradigm Publishing Services
Publication frequency: 1 issue per year
Keywords:
Electro-optic effect,
Lithium niobate LN,
Mach–Zehnder modulator MZM,
Optical confinement factor
Related subjects:
Engineering,
Introductions and overviews,
Engineering, other

© 2022 Ahmad S. Abdullah, Sadeq Adnan Hbeeb, published by Professor Subhas Chandra Mukhopadhyay
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

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