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High‐Temperature Treatment of Li‐Rich Cathode Materials with Ammonia: Improved Capacity and Mean Voltage Stability during Cycling
Authors:Evan M. Erickson  Hadar Sclar  Florian Schipper  Jing Liu  Ruiyuan Tian  Chandan Ghanty  Larisa Burstein  Nicole Leifer  Judith Grinblat  Michael Talianker  Ji‐Yong Shin  Jordan K. Lampert  Boris Markovsky  Anatoly I. Frenkel  Doron Aurbach
Affiliation:1. Department of Chemistry, Faculty of Exact Sciences, Bar‐Ilan University, Ramat‐Gan, Israel;2. Department of Materials Science and Chemical Engineering, Stony Brook University, Stony Brook, NY, USA;3. Wolfson Applied Materials Research Center, Tel‐Aviv University, Tel‐Aviv, Israel;4. Department of Materials Engineering, Ben Gurion University of the Negev, Beer‐Sheva, Israel;5. BASF SE, Rheinland‐Pfalz, Germany
Abstract:Li‐rich electrode materials of the family x Li2MnO3·(1?x )LiNia Cob Mnc O2 (a + b + c = 1) suffer a voltage fade upon cycling that limits their utilization in commercial batteries despite their extremely high discharge capacity, ≈250 mA h g?1. Li‐rich, 0.35Li2MnO3·0.65LiNi0.35Mn0.45Co0.20O2, is exposed to NH3 at 400 °C, producing materials with improved characteristics: enhanced electrode capacity and a limited average voltage fade during 100 cycles in half cells versus Li. Three main changes caused by NH3 treatment are established. First, a general bulk reduction of Co and Mn is observed via X‐ray photoelectron spectroscopy and X‐ray absorption near edge structure. Next, a structural rearrangement lowers the coordination number of Co? O and Mn? O bonds, as well as formation of a surface spinel‐like structure. Additionally, Li+ removal from the bulk causes the formation of surface LiOH, Li2CO3, and Li2O. These structural and surface changes can enhance the voltage and capacity stability of the Li‐rich material electrodes after moderate NH3 treatment times of 1–2 h.
Keywords:ammonia treatment  cathodes  lithium‐ion batteries  lithium‐rich materials  stabilization  voltage fade
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