High-rate lithium storage of anatase TiO2 crystals doped with both nitrogen and sulfur

Jiao, Wei, Li, Na, Wang, Lianzhou, Wen, Lei, Li, Feng, Liu, Gang and Cheng, Hui-Ming (2013) High-rate lithium storage of anatase TiO2 crystals doped with both nitrogen and sulfur. Chemical Communications, 49 33: 3461-3463. doi:10.1039/c3cc40568k


Author Jiao, Wei
Li, Na
Wang, Lianzhou
Wen, Lei
Li, Feng
Liu, Gang
Cheng, Hui-Ming
Title High-rate lithium storage of anatase TiO2 crystals doped with both nitrogen and sulfur
Formatted title
High-rate lithium storage of anatase TiO2 crystals doped with both nitrogen and sulfur
Journal name Chemical Communications   Check publisher's open access policy
ISSN 1359-7345
Publication date 2013-04-28
Sub-type Article (original research)
DOI 10.1039/c3cc40568k
Open Access Status Not yet assessed
Volume 49
Issue 33
Start page 3461
End page 3463
Total pages 3
Place of publication United Kingdom
Publisher R S C Publications
Language eng
Subject 1503 Catalysis
2504 Electronic, Optical and Magnetic Materials
2503 Ceramics and Composites
1600 Chemistry
2508 Surfaces, Coatings and Films
2506 Metals and Alloys
2505 Materials Chemistry
Abstract Anatase TiO nanocrystals doped with nitrogen and sulfur, where substitutional N and S atoms for lattice O, respectively, locate in the bulk and the surface layer of the crystals, were designed and prepared. As a result of remarkably lowered electronic resistance, the N/S doped TiO shows a superior high rate lithium storage capability to that of reference TiO nanocrystals, though the former has a larger particle size.
Formatted abstract
Anatase TiO2 nanocrystals doped with nitrogen and sulfur, where substitutional N and S atoms for lattice O, respectively, locate in the bulk and the surface layer of the crystals, were designed and prepared. As a result of remarkably lowered electronic resistance, the N/S doped TiO2 shows a superior high rate lithium storage capability to that of reference TiO2 nanocrystals, though the former has a larger particle size.
Keyword Visible-light
Electrochemical properties
Titanium-dioxide
Anode material
Ion batteries
Performance
Size
Photocatalysis
Capability
Nanotubes
Q-Index Code C1
Q-Index Status Confirmed Code
Institutional Status UQ

Document type: Journal Article
Sub-type: Article (original research)
Collections: Official 2014 Collection
Australian Institute for Bioengineering and Nanotechnology Publications
 
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