TY - JOUR
T1 - Reduced surfactant uptake in three dimensional assemblies of VOx Nanotubes Improves Reversible Li+ intercalation and charge capacity
AU - O'Dwyer, Colm
AU - Lavayen, Vladimir
AU - Tanner, David A.
AU - Newcomb, Simon B.
AU - Benavente, Eglantina
AU - González, Guillermo
AU - Torres, Clivia M.Sotomayor
PY - 2009/6/9
Y1 - 2009/6/9
N2 - The relationship between the nanoscale structure of vanadium pentoxide nanotubes and their ability to accommodate Li+ during intercalation/ deintercalation is explored. The nanotubes are synthesized using two different precursors through a surfactant-assisted templating method, resulting in standalone VOx (vanadium oxide) nanotubes and also "nanourchin". Under highly reducing conditions, where the interlaminar uptake of primary alkylamines is maximized, standalone nanotubes exhibit near-perfect scrolled layers and long-range structural order even at the molecular level. Under less reducing conditions, the degree of amine uptake is reduced due to a lower density of V4+ sites and less V2O5 is functionalized with adsorbed alkylammonium cations. This is typical of the nano-urchin structure. Highresolution TEM studies revealed the unique observation of nanometer-scale nanocrystals of pristine unreacted V 2O5 throughout the length of the nanotubes in the nano-urchin. Electrochemical intercalation studies revealed that the very well ordered xerogel-based nanotubes exhibit similar specific capacities (235mA h g-1) to Na+-exchange nanorolls of VOx (200mA h g -1). By comparison, the theoretical maximum value is reported to be 240mA h g-1. The VOTPP-based nanotubes of the nano-urchin 3D assemblies, however, exhibit useful charge capacities exceeding 437mA h g -1, which is a considerable advance for VOx based nanomaterials and one of the highest known capacities for Li+ intercalated laminar vanadates.
AB - The relationship between the nanoscale structure of vanadium pentoxide nanotubes and their ability to accommodate Li+ during intercalation/ deintercalation is explored. The nanotubes are synthesized using two different precursors through a surfactant-assisted templating method, resulting in standalone VOx (vanadium oxide) nanotubes and also "nanourchin". Under highly reducing conditions, where the interlaminar uptake of primary alkylamines is maximized, standalone nanotubes exhibit near-perfect scrolled layers and long-range structural order even at the molecular level. Under less reducing conditions, the degree of amine uptake is reduced due to a lower density of V4+ sites and less V2O5 is functionalized with adsorbed alkylammonium cations. This is typical of the nano-urchin structure. Highresolution TEM studies revealed the unique observation of nanometer-scale nanocrystals of pristine unreacted V 2O5 throughout the length of the nanotubes in the nano-urchin. Electrochemical intercalation studies revealed that the very well ordered xerogel-based nanotubes exhibit similar specific capacities (235mA h g-1) to Na+-exchange nanorolls of VOx (200mA h g -1). By comparison, the theoretical maximum value is reported to be 240mA h g-1. The VOTPP-based nanotubes of the nano-urchin 3D assemblies, however, exhibit useful charge capacities exceeding 437mA h g -1, which is a considerable advance for VOx based nanomaterials and one of the highest known capacities for Li+ intercalated laminar vanadates.
UR - http://www.scopus.com/inward/record.url?scp=67649231119&partnerID=8YFLogxK
U2 - 10.1002/adfm.200801107
DO - 10.1002/adfm.200801107
M3 - Article
AN - SCOPUS:67649231119
SN - 1616-301X
VL - 19
SP - 1736
EP - 1745
JO - Advanced Functional Materials
JF - Advanced Functional Materials
IS - 11
ER -