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Excess lithium salt functions more than compensating for lithium loss when synthesizing Li6.5La3Ta0.5Zr1.5O12 in alumina crucible Liu K, Ma JT, Wang CA Journal of Power Sources, 260, 109, 2014 |
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Hierarchical meso-macro structure porous carbon black as electrode materials in Li-air battery Kang J, Li OL, Saito N Journal of Power Sources, 261, 156, 2014 |
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Humidity effect on electrochemical performance of Li-O-2 batteries Guo ZY, Dong XL, Yuan SY, Wang YG, Xia YY Journal of Power Sources, 264, 1, 2014 |
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Electrocatalytic performances of LaNi1-xMgxO3 perovskite oxides as bi-functional catalysts for lithium air batteries Du ZZ, Yang P, Wang L, Lu YH, Goodenough JB, Zhang J, Zhang DW Journal of Power Sources, 265, 91, 2014 |
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Mechanism of Co3O4/graphene catalytic activity in Li-O-2 batteries using carbonate based electrolytes Lim HD, Gwon H, Kim H, Kim SW, Yoon T, Choi JW, Oh SM, Kang K Electrochimica Acta, 90, 63, 2013 |
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Increasing round trip efficiency of hybrid Li-air battery with bifunctional catalysts Huang K, Li YF, Xing YC Electrochimica Acta, 103, 44, 2013 |
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Synthesis and electrocatalytic properties of various metals supported on carbon for lithium-air battery Ko BK, Kim MK, Kim SH, Lee MA, Shim SE, Baeck SH Journal of Molecular Catalysis A-Chemical, 379, 9, 2013 |
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The SEI layer formed on lithium metal in the presence of oxygen: A seldom considered component in the development of the Li-O-2 battery Younesi R, Hahlin M, Roberts M, Edstrom K Journal of Power Sources, 225, 40, 2013 |
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Modelling the micro-macro homogeneous cycling behaviour of a lithium-air battery Sahapatsombut U, Cheng H, Scott K Journal of Power Sources, 227, 243, 2013 |
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Cathode reaction mechanism of non-aqueous Li-O-2 batteries with highly oxygen radical stable electrolyte solvent Mizuno F, Takechi K, Higashi S, Shiga T, Shiotsuki T, Takazawa N, Sakurabayashi Y, Okazaki S, Nitta I, Kodama T, Nakamoto H, Nishikoori H, Nakanishi S, Kotani Y, Iba H Journal of Power Sources, 228, 47, 2013 |