F
Fang Bian
Researcher at University of New South Wales
Publications - 5
Citations - 83
Fang Bian is an academic researcher from University of New South Wales. The author has contributed to research in topics: Laser-induced breakdown spectroscopy & Calibration curve. The author has an hindex of 4, co-authored 5 publications receiving 60 citations. Previous affiliations of Fang Bian include Sichuan University.
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A hydrogel-based solidification method for the direct analysis of liquid samples by laser-induced breakdown spectroscopy
TL;DR: In this article, a hydrogel-based solidification technique was proposed for the analysis of liquid samples via a liquid-to-reinflated resin. But, the method is limited due to its inherent disadvantages including surface ripples and extinction of emitted intensity.
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Exploration of a 3D nano-channel porous membrane material combined with laser-induced breakdown spectrometry for fast and sensitive heavy metal detection of solution samples
TL;DR: In this paper, a 3D anodic aluminum oxide porous membrane (AAOPM) was selected as a novel substrate for the first time, which showed excellent potential for liquid analysis.
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A single-beam-splitting technique combined with a calibration-free method for field-deployable applications using laser-induced breakdown spectroscopy
Mingjun Xu,Qingyu Lin,Guang Yang,Tao Xu,Tianlong Zhang,Xu Wang,Shuai Wang,Fang Bian,Yixiang Duan +8 more
TL;DR: In this article, a single-beam-splitting laser-induced breakdown spectroscopy (LIBS) technique using one single laser system is demonstrated, where an individual pulse delivered by a laser (1064 nm wavelength) was split into two sub-pulses by a beam splitter.
Journal ArticleDOI
Hydrological and geochemical responses of fire in a shallow cave system.
Fang Bian,Katie Coleborn,I. Flemons,Andy Baker,Pauline C. Treble,Catherine E. Hughes,Andy Baker,Martin S. Andersen,Mark G. Tozer,Wuhui Duan,Christopher J. Fogwill,Ian J. Fairchild +11 more
TL;DR: This first study to understand the hydrological impact from severe fires conducted on a karst system provides new insights on the cave recharge process, with a potential explanation for the decreased d18O in speleothem-based fire study, and utilise the decreased bedrock solutes to assess the wildfire impacts both in short and long time scales.