Y. Zhang, J. Nauriyal, M. Song, M. Granados-Baez, X. He, T. MacDonald, and J. Cardenas, “Engineered second-order nonlinearity in silicon nitride,” Preprint arXiv:2210.09374 (in review at Optics Materials Express).
X. He, L. Cortes-Herrera, K. Opong-Mensah, Y. Zhang, G. P. Agrawal, and J. Cardenas, “Electrically induced adiabatic frequency conversion in an integrated lithium niobate ring resonator,” Opt. Letters, 10.1364/OL.473113 (in press).
J. Sanchez-Juarez, M. Granados-Baez, A. Aguilar-Lasserre, and J. Cardenas, “Intelligent decision support system to optimize 2D materials detection using digital image processing and deep learning,” Opt. Mat. Express 12(5), 1856 – 1868 (2022).
J. Steinmetz, K. Lyons, M. Song, J. Cardenas, and A. N. Jordan, “Enhanced on-chip frequency measurement using weak value amplification,” Opt. Express 30(3), 3700 – 3718 (2022). Preprint: arXiv:2103.15752.
L. Cortes-Herrera, X. He, J. Cardenas, and G.P. Agrawal, “Design of an X-cut thin-film lithium niobate waveguide as a passive polarization rotator,” Opt. Express 29(26), 44174 – 44188 (2021).
M. Song, J. Steinmetz, Y. Zhang, J. Nauriyal, K. Lyons, A. N. Jordan, and J. Cardenas, “Enhanced on-chip phase measurement by inverse weak value amplification,” Nature Comms. 12(1), 1-7 (2021).
J. Guimbao, L. Sanchis, L.M. Weituschat, J. M. Llorens, M. Song, J. Cardenas, and P.A. Postigo, “Machine learning optimization of a nanophotonic cavity for near unity photon indistinguishability at room temperature,” arXiv:2110.15000 (2021)*.
L. Cortes-Herrera, X. He, J. Cardenas, and G. P. Agrawal, “Coupled-mode theory of the polarization dynamics inside a microring resonator with a uniaxial core,” Phys. Rev. A 103 (6), 063517 (2021).
S. Roberts, X. Ji, J. Cardenas, M. Corato-Zanarella, and M. Lipson, “Measurements and modeling of atomic-scale sidewall roughness and losses in integrated photonic devices,” arXiv:2105.11477 (2021)*.
A. Mohanty, Q. Li, A. M. Tadayon, S. P. Roberts, G. R. Bhatt, E. Shim, X. Ji, J. Cardenas, S. A. Miller, A. Kepecs, and M. Lipson, “Reconfigurable nanophotonic silicon probes for sub-millisecond deep-brain optical stimulation,” Nature Biomedical Engineering, 1-9 (2020). Pre-print: arXiv:1805.11663
S. Saini, S. Preble, M. Popović, J. Cardenas, A. Kost, E. Verlage, G. Howland, and L. C. Kimerling. “Integrated photonics and application-specific design on a massive open online course platform,” In Education and Training in Optics and Photonics, p. 11143_151. Optical Society of America, 2019.
J. Nauriyal, M. Song, R. Yu, and J. Cardenas, “Fiber-to-chip fusion splicing for low-loss photonic packaging,” Optica 6, 549 – 552 (2019).
J. Nauriyal, R. Yu, M. Song, and J. Cardenas, “Fiber to chip fusion splicing for robust, low loss photonic packaging,” arXiv:1810.09531 (2018).
Y. Okawachi, M. Yu, J. Cardenas, X. Ji, A. Klenner, M. Lipson, and A. L. Gaeta, “Carrier envelope offset detection via simultaneous supercontinuum and second-harmonic generation in a silicon nitride waveguide,” Opt. Lett., 43(19), 4627-4630 (2018).
A. Dutt, C. Joshi, X. Ji, J. Cardenas, Y. Okawchi, K. Luke, A. L. Gaeta, and M. Lipson, “On-chip dual-comb spectroscopy,” Sci. Adv. 4(3), e1701858 (2018).
A. Mohanty, Q. Li, M. A. Tadayon, G. Bhatt, E. Shim, X. Ji, J. Cardenas, S. A. Miller, A. Kepecs, and M. Lipson, “A reconfigurable nanophotonics platform for sub-millisecond, deep brain neural stimulation,” arXiv:1805.11663 (2018).