Your search keyword '"Xiaoxia Zhao"' showing total 2 results

1. Plasmonic RI Sensor Design Based on Fano Resonance with MIM Waveguide Coupled by the Concentric Annulus Cavity.

Author

Xilong, Li, Zhaoxia, Wu, Xiaoxia, Zhao, Wenfeng, Luo, Junfang, He, Senlin, Yang, and Yuanyuan, Li

Subjects

FANO resonance, FINITE element method, REFRACTIVE index, OPTICAL devices, LIGHT transmission, BAFFLES (Mechanical device)

Abstract

A nano resonator is designed consisting of the metal-insulator-metal (MIM) waveguide coupled with the concentric annulus cavity. The optical transmission characteristics and sensing characteristics of the designed sensor are studied by using finite element method. Experimental results show that the combination of the MIM waveguide and the concentric annulus cavity can produce bright mode and dark mode around the central wavelength of 565 nm. Due to the interaction between these modes, the Fano resonance phenomenon will be produced with a transitional dip around the wavelength of 585 nm. Compared with the impacts of the width of the metal baffle and the coupling gap, the Fano resonance effect is very sensitive to the variation of the radii of the concentric annulus cavity, which is helpful to design the tunable optical devices based on Fano resonance in the future. However the modulation depth is obviously influenced by the width of the metal baffle and the coupling gap. The research also demonstrates the sharp asymmetric Fano transmission spectrum is also sensitive to the surrounding medium. By calculating the shift of the resonant wavelength with the change of the refractive index of the medium in the resonator, the device can achieve the sensitivity of 550 nm/RIU and the figure of merit of 70. [ABSTRACT FROM AUTHOR]

Published

2024

2. Enhancing ecosystem productivity and stability with increasing canopy structural complexity in global forests.

Author

Xiaoqiang Liu, Yuhao Feng, Tianyu Hu, Yue Luo, Xiaoxia Zhao, Jin Wu, Maeda, Eduardo E., Weiming Ju, Lingli Liu, Qinghua Guo, and Yanjun Su

Subjects

*FOREST productivity, *OPTICAL radar, *LIDAR, *CLIMATE change mitigation, *ECOSYSTEMS, *FOREST management

Abstract

Forest canopy structural complexity (CSC) plays a crucial role in shaping forest ecosystem productivity and stability, but the precise nature of their relationships remains controversial. Here, we mapped the global distribution of forest CSC and revealed the factors influencing its distribution using worldwide light detection and ranging data. We find that forest CSC predominantly demonstrates significant positive relationships with forest ecosystem productivity and stability globally, although substantial variations exist among forest ecoregions. The effects of forest CSC on productivity and stability are the balanced results of biodiversity and resource availability, providing valuable insights for comprehending forest ecosystem functions. Managed forests are found to have lower CSC but more potent enhancing effects of forest CSC on ecosystem productivity and stability than intact forests, highlighting the urgent need to integrate forest CSC into the development of forest management plans for effective climate change mitigation.. [ABSTRACT FROM AUTHOR]

Published

2024