Bacterially synthesized tellurium nanostructures for broadband ultrafast nonlinear optical applications
Loading...
Date
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
Access
openAccess
Embargo end date
Citation
Wang, K. and Zhang, X. and Kislyakov, I.M. and Dong, N. and Zhang, S. and Wang, G. and Fan, J. and Zou, X. and Du, J. and Leng, Y. and Zhao, Q. and Wu, K. and Chen, J. and Baesman, S.M. and Liao, K.-S. and Maharjan, S. and Zhang, H. and Zhang, L. and Curran, S.A. and Oremland, R.S. and Blau, W.J. and Wang, J., Bacterially synthesized tellurium nanostructures for broadband ultrafast nonlinear optical applications, Nature Communications, 10, 1, 2019
Abstract
Elementary tellurium is currently of great interest as an element with potential promise in nano-technology applications because of the recent discovery regarding its three two-dimensional phases and the existence of Weyl nodes around its Femi level. Here, we report on the unique nano-photonic properties of elemental tellurium particles [Te(0)], as harvest from a culture of a tellurium-oxyanion respiring bacteria. The bacterially-formed nano-crystals prove effective in the photonic applications tested compared to the chemically-formed nano-materials, suggesting a unique and environmentally friendly route of synthesis. Nonlinear optical measurements of this material reveal the strong saturable absorption and nonlinear optical extinctions induced by Mie scattering over broad temporal and wavelength ranges. In both cases, Te-nanoparticles exhibit superior optical nonlinearity compared to graphene. We demonstrate that biological tellurium can be used for a variety of photonic applications which include their proof-of-concept for employment as ultrafast mode-lockers and all-optical switches.
Description
PUBLISHED
cited By 0
cited By 0
Collections
Endorsement
Review
Supplemented By
Referenced By
Sponsor: Science Foundation Ireland (SFI)
Grant Number: 12/IA/1306.
Author's Homepage: http://people.tcd.ie/wblau
Type of material: Journal Article

