Theoretical Development of Polymer-Based Integrated Lossy-Mode Resonance Sensor for Photonic Integrated Circuits

Abstract: A promising phenomenon such as lossy-mode resonance (LMR) is of great interest in sensor applications. Until now, this phenomenon has been shown only in fibers or planar waveguides; however, given the rapid development of such an important technological area as photonic integrated circuits (PICs), it is important to transfer LMR technology specifically to PICs. In this article, we propose the theoretical development of an integrated polymer-based LMR sensor that will also contribute to the development of hybri… Show more

“…Meanwhile, this is the first time that a gain of 1.31 µm in polymer NDWA has been reported. The polymer host materials PMMA and SU-8 have been industrially applied in the field of plastic optical fiber and planar photonic integration [42][43][44] and proven by the market. Under the excitation at the 365 nm LED, the maximum handling power that Nd (TTA) 3 (XPO)-doped PMMA and SU-8 waveguides can withstand is 560 mW.…”

High‐Gain of Nd^III Complex Doped Optical Waveguide Amplifiers at 1.06 and 1.31 µm Wavelengths Based on Intramolecular Energy Transfer Mechanism

“…Meanwhile, this is the first time that a gain of 1.31 µm in polymer NDWA has been reported. The polymer host materials PMMA and SU-8 have been industrially applied in the field of plastic optical fiber and planar photonic integration [42][43][44] and proven by the market. Under the excitation at the 365 nm LED, the maximum handling power that Nd (TTA) 3 (XPO)-doped PMMA and SU-8 waveguides can withstand is 560 mW.…”

High‐Gain of Nd^III Complex Doped Optical Waveguide Amplifiers at 1.06 and 1.31 µm Wavelengths Based on Intramolecular Energy Transfer Mechanism

Detection of biofuel adulterants using an optical fiber-based refractive index sensor

Lossy mode resonance in photonic integrated circuits