High-surface vanadium oxides with large capacities for lithium-ion batteries: from hydrated aerogel to nanocrystalline VO 2 (B), V 6 O 13 and V 2 O 5
Vanadium pentoxide aerogels with high surface area (196 m2 g− 1) and ultrathin nanofiber
(∼ 10 nm) morphology were prepared through a sol–gel method followed by a freeze-drying …
(∼ 10 nm) morphology were prepared through a sol–gel method followed by a freeze-drying …
[引用][C] High-surface vanadium oxides with large capacities for lithium-ion batteries: from hydrated aerogel to nanocrystalline VO2 (B), V6O13 and V2O5
H Li, P He, Y Wang, E Hosono, H Zhou - Journal of Materials …, 2011 - hero.epa.gov
High-surface vanadium oxides with large capacities for lithium-ion batteries: from hydrated
aerogel to nanocrystalline VO2(B), V6O13 and V2O5 | Health & Environmental Research …
aerogel to nanocrystalline VO2(B), V6O13 and V2O5 | Health & Environmental Research …
[引用][C] High-surface vanadium oxides with large capacities for lithium-ion batteries: from hydrated aerogel to nanocrystalline VO2 (B), V6O13 and V2O5
H Li, P He, Y Wang, E Hosono, H Zhou - Journal of Materials Chemistry, 2011 - cir.nii.ac.jp
High-surface vanadium oxides with large capacities for lithium-ion batteries: from hydrated
aerogel to nanocrystalline VO2(B), V6O13 and V2O5 | CiNii Research CiNii 国立情報学研究所 …
aerogel to nanocrystalline VO2(B), V6O13 and V2O5 | CiNii Research CiNii 国立情報学研究所 …