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Porous hollow carbon@ sulfur composites for high‐power lithium–sulfur batteries
N Jayaprakash, J Shen, SS Moganty, A Corona, LA Archer
Angewandte Chemie-International Edition 50 (26), 5904, 2011
The rechargeable aluminum-ion battery
N Jayaprakash, SK Das, LA Archer
Chemical Communications 47 (47), 12610-12612, 2011
SnO2 Nanoparticles with Controlled Carbon Nanocoating as High-Capacity Anode Materials for Lithium-Ion Batteries
JS Chen, YL Cheah, YT Chen, N Jayaprakash, S Madhavi, YH Yang, ...
The Journal of Physical Chemistry C 113 (47), 20504-20508, 2009
Ionic-liquid-tethered nanoparticles: hybrid electrolytes
SS Moganty, J Jayaprakash, JL Nugent, J Shen, LA Archer
Wiley-Blackwell, 2010
Self-assembled MoS 2–carbon nanostructures: influence of nanostructuring and carbon on lithium battery performance
SK Das, R Mallavajula, N Jayaprakash, LA Archer
Journal of Materials Chemistry 22 (26), 12988-12992, 2012
Electrolytes for high-energy lithium batteries
JL Schaefer, Y Lu, SS Moganty, P Agarwal, N Jayaprakash, LA Archer
Applied Nanoscience 2, 91-109, 2012
Mesoporous TiO2 nano networks: Anode for high power lithium battery applications
HG Jung, SW Oh, J Ce, N Jayaprakash, YK Sun
Electrochemistry communications 11 (4), 756-759, 2009
Composite lithium battery anodes based on carbon@ Co3O4 nanostructures: synthesis and characterization
N Jayaprakash, WD Jones, SS Moganty, LA Archer
Journal of Power Sources 200, 53-58, 2012
CAM sol–gel synthesized LiMPO4 (M=Co, Ni) cathodes for rechargeable lithium batteries
Gangulibabu, D Bhuvaneswari, N Kalaiselvi, N Jayaprakash, ...
Journal of sol-gel science and technology 49, 137-144, 2009
On the electrochemical behavior of LiMXFe1− XPO4 [M= Cu, Sn; X= 0.02] anodes–An approach to enhance the anode performance of LiFePO4 material
N Jayaprakash, N Kalaiselvi
Electrochemistry communications 9 (4), 620-628, 2007
Synthesis of organic–inorganic hybrids by miniemulsion polymerization and their application for electrochemical energy storage
Z Yang, J Shen, N Jayaprakash, LA Archer
Energy & Environmental Science 5 (5), 7025-7032, 2012
Synthesis and characterization of LiMXFe1-XPO4 (M= Cu, Sn; X= 0.02) cathodes-A study on the effect of cation substitution in LiFePO4 material
N Jayaprakash, N Kalaiselvi, P Periasamy
International Journal of Electrochemical Science 3 (4), 476-488, 2008
Effect of mono- (Cr) and bication (Cr, V) substitution on LiMn2O4 spinel cathodes
N Jayaprakash, N Kalaiselvi, Gangulibabu, D Bhuvaneswari
Journal of Solid State Electrochemistry 15, 1243-1251, 2011
Influence of phosphoric acid on the grid alloys of positive plates in the lead acid battery system: A comparative study
K Saminathan, N Jayaprakash, B Rajeswari, T Vasudevan
Journal of power sources 160 (2), 1410-1413, 2006
A new class of tailor-made Fe0. 92Mn0. 08Si2 lithium battery anodes: Effect of composite and carbon coated Fe0. 92Mn0. 08Si2 anodes
N Jayaprakash, N Kalaiselvi, CH Doh
Intermetallics 15 (3), 442-450, 2007
Combustion synthesized LiMnSnO4 cathode for lithium batteries
N Jayaprakash, N Kalaiselvi, YK Sun
Electrochemistry communications 10 (3), 455-460, 2008
A preliminary investigation into the new class of lithium intercalating LiNiSiO4 cathode material
N Jayaprakash, N Kalaiselvi, P Periasamy
Nanotechnology 19 (2), 025603, 2007
A novel approach to explore Zn based anodes for lithium-ion battery applications
N Jayaprakash, K Sathiyanarayanan, N Kalaiselvi
Electrochimica acta 52 (7), 2453-2460, 2007
Synthesis and electrochemical evaluation of carbon coated Cu6Sn5 alloy-graphite composite lithium battery anodes
N Jayaprakash, N Kalaiselvi, CH Doh
Journal of applied electrochemistry 37, 567-573, 2007
Mesoporous carbon-coated Li4Ti5O12 spheres for fast Li+ ion insertion/deinsertion in lithium battery anodes
N Jayaprakash, SS Moganty, XW Lou, LA Archer
Applied Nanoscience 1, 7-11, 2011
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