Your search keyword '"Yao, Jian"' showing total 4 results

1. Three-Dimensional Thermal Analysis of 18-Core Photonic Crystal Fiber Lasers.

Author

Zheng Yi-Bo, Yao Jian-Quan, Zhang Lei, Wang Yuan, Wen Wu-Qi, Jing Lei, and Di Zhi-Gang

Subjects

*THERMAL analysis, *PHOTONIC crystals, *FIBER lasers, *HEAT convection, *TEMPERATURE effect, *FINITE element method, *BRAGG gratings

Abstract

The three-dimensional thermal properties of 18-core photonic crystal fiber lasers operated under natural convec-tion are investigated. The temperature sensing technique based on a fiber Bragg grating sensor array is proposed to measure the longitudinal temperature distribution of a 1.6-m-long ytterbium-doped 18-core photonic crystal fiber. The results show that the temperature decreases from the pump end to the launch end exponentially. More-over, the radial temperature distribution of the fiber end is investigated by using the full-vector finite-element method. The numerical results match well with the experimental data and the coating temperature reaches 422.7K, approaching the critical value of polymer cladding, when the pumping power is 40 W. Therefore the fiber end cooling is necessary to achieve power scaling. Compared with natural convection methods, the copper cooling scheme is found to be an effective method to reduce the fiber temperature. [ABSTRACT FROM AUTHOR]

Published

2012

2. A Simple Birefringent Terahertz Waveguide Based on Polymer Elliptical Tube.

Author

Wang Jing, Yao Jian, Chen He, Ming and, and Li Zhong

Subjects

*DOUBLE refraction, *TERAHERTZ technology, *WAVEGUIDES, *POLYMERS, *FINITE element method, *SIMULATION methods & models

Abstract

We propose a simple birefringent terahertz (THz) waveguide which is a polymer elliptical tube with a cross section of elliptical ring structure. It can be achieved by stretching a normal circular-tube in one direction. Simulations based on the full-vector finite element method (FEM) show that this kind of waveguides exhibits high birefringence on a level of 10[?]2 over a wide THz frequency range. Moreover, as a majority of modal power is trapped in the air core inside the polymer elliptical tube, the THz waveguide guiding loss caused by material absorption can be reduced effectively. [ABSTRACT FROM AUTHOR]

Published

2011

3. Low Loss Plastic Terahertz Photonic Band-Gap Fibres.

Author

Geng You, Tan Xiao, Zhong Kai, Wang Peng, and Yao Jian

Subjects

*POLYESTER fibers, *TERAHERTZ technology, *PHOTONICS, *ABSORPTION, *NUMERICAL analysis, *FINITE element method

Abstract

We report a numerical investigation on terahertz wave propagation in plastic photonic band-gap fibres which are characterized by a 19-unit-cell air core and hexagonal air holes with rounded corners in cladding. Using the finite element method, the leakage loss and absorption loss are calculated and the transmission properties are analysed. The lowest loss of 0.268 dB/m is obtained. Numerical results show that the fibres could liberate the constraints of background materials beyond the transparency region in terahertz wave band, and efficiently minimize the effect of absorption by background materials, which present great advantage of plastic photonic band-gap fibres in long distance terahertz delivery. [ABSTRACT FROM AUTHOR]

Published

2008

4. Simulation of continuous terahertz wave transient state thermal effects on static water.

Author

Lu Ying, Xu De, Liu Peng, Lu Da, Wen Qi, Zhang Huai, Wu and, and Yao Jian

Subjects

*COMPUTER simulation, *TERAHERTZ technology, *TRANSIENTS (Dynamics), *WATER, *THERMAL analysis, *FINITE element method, *GAUSSIAN beams, *HEAT equation, *THICKNESS measurement

Abstract

We report a numerical simulation of continuous terahertz beam induced transient thermal effects on static water. The terahertz wave used in this paper has a Gaussian beam profile. Based on the transient heat conduction equation, the finite element method (FEM) is utilized to calculate the temperature distribution. The simulation results show the dynamic process of temperature change in water during terahertz irradiation. After about 300 s, the temperature reaches a steady state with a water layer thickness of 5 mm and a beam radius of 0.25 mm. The highest temperature increase is 7 K/mW approximately. This work motivates further study on the interaction between terahertz wave and bio-tissue, which has a high water content. [ABSTRACT FROM AUTHOR]

Published

2011