News Release

Control of temperature dependent viscosity for manufacturing of Bi-doped active fiber

Peer-Reviewed Publication

International Journal of Extreme Manufacturing

Control of temperature dependent viscosity for manufacturing of Bi-doped active fibers

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By controlling the temperature dependent viscosity of the Bi doped materials, the deactivation of the Bi dopants can be suppressed during fiber drawing process.

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Credit: By Rui Duan, Jingfei Chen, Hao Ke, Tianxia Wei, Ke Zhang, Xueliang Li, Xu Feng, Qiuju Zheng, Zhixue He, Jianrong Qiu and Shifeng Zhou.

A novel temperature-dependent viscosity mediated strategy proposed by researchers at South China University of Technology was able to suppress the deactivation of Bi dopants during the fiber drawing process.

The work, published in the International Journal of Extreme Manufacturing, could guide the development of heavily doped Bi active fibers, which exhibit great potential for application in the next-generation optical amplifiers.

Bi-dopants exhibit multi-chemical states and can transform into a deactivated state when the bulk is drawn into fiber at high temperature, which limits the development of high performance Bi-active fibers.

"From the viewpoint of thermodynamics, the deactivation of Bi dopants cannot be prevented during the fiber drawing process, since the Bi-active center is not the thermodynamics stable at such temperatures," said Shifeng Zhou, corresponding author on the paper and professor at the South China University of Technology.

"Thus, a kinetics strategy must be considered to suppress the transformation of the Bi-active center to an inactive state during the fiber drawing process. Controlling the temperature-dependent viscosity of the materials might be one of the effective kinetic approaches to suppress the deactivation of the Bi center.

Bi-active fiber is now regarded as the most promising candidate for next-generation broadband optical amplifiers in high-capacity telecommunication systems. However, due to the easy deactivation of Bi centers, fabricating Bi-active center remains a challenge.

Nowadays, only a few groups worldwide can fabricate the Bi-active fiber using the modified chemical vapor deposition (MCVD) method. The complicated chemical vapor deposition (CVD) technique not only creates a significant technique barrier for the fabrication of Bi-active fiber but also limits the available glass fiber system and the doping concentration of Bi.

The evolution of Bi dopant at different temperatures in glass systems with different viscous characteristics is systematically studied. It is found that the systems with a faster viscosity changing rate in the temperature range from 1.0 to 1.6 Tg exhibit the better anti-deactivation ability for Bi dopants.

Based on this finding, a borate glass system with a faster viscosity changing rate was developed, and a novel heavily-doped Bi-active borate fiber was fabricated via the simple rod-in-tube method. Additionally, the on-off gain based on the developed novel fiber was demonstrated, marking the first demonstration of on-off gain in a Bi doped borate fiber system.

"Although achieving a net gain in heavily doped Bi active fiber remains a long-standing challenge," said Prof. Shifeng Zhou, "I think our work may provide new insights into selecting the glass host systems to develop the high performance Bi-active fibers."

The researchers are continuing the work, aiming to develop the heavily doped Bi-active fibers with net gain and construct the Bi-doped optical amplifiers.

About IJEM:

International Journal of Extreme Manufacturing (IF: 14.7, 1st in the Engineering, Manufacturing category in JCR 2023) is a new multidisciplinary, double-anonymous peer-reviewed and diamond open-access without article processing charge journal uniquely covering the full spectrum of extreme manufacturing.

The journal is devoted to publishing original articles and reviews of the highest quality and impact in the areas related to the science and technology of manufacturing functional devices and systems with extreme dimensions (extremely large or small) and/or extreme functionalities, ranging from fundamental science to cutting-edge technologies that support the manufacturing of high-performance products involving emerging techniques and breaking the limits of currently known theories, methods, scales, environments, and performance.

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