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Understanding the Effects of Tetrahedral Site Occupancy by the Zn Dopant in Li-NMCs toward High-Voltage Compositional–Structural–Mechanical Stability via Operando and 3D Atom Probe Tomography Studies

Ankur Sharma, Adityanarayan H. Pandey, Manoj K. Jangid, Velaga Srihari, H. K. Poswal, Amartya Mukhopadhyay

2023ACS Applied Materials & Interfaces15 citationsDOI

Abstract

Ni-containing “layered”/cation-ordered LiT M O 2 s (T M = transition metal) suffer from Ni-migration to the Li-layer at the unit cell level, concomitant transformation to a spinel/rock salt structure, hindrance toward Li-transport, and, thus, fading in Li-storage capacity during electrochemical cycling (i.e., repeated delithiation/lithiation), especially upon deep delithiation (i.e., going to high states-of-charge). Against this backdrop, our previously reported work [ ACS Appl. Mater. Interfaces 2021, 13, 25836–25849] revealed a new concept toward blocking the Ni-migration pathway by placing Zn 2+ (which lacks octahedral site preference) in the tetrahedral site of the Li-layer, which, otherwise, serves as an intermediate site for the Ni-migration to the Li-layer. This, nearly completely, suppressed the Ni-migration, despite being deep delithiated up to a potential of 4.7 V (vs Li/Li + ) and, thus, resulted in significant improvement in the high-voltage cyclic stability. In this regard, by way of conducting operando synchrotron X-ray diffraction, operando stress measurements, and 3D atom probe tomography, the present work throws deeper insights into the effects of such Zn-doping toward enhancing the structural–mechanical–compositional integrity of Li-NMCs upon being subjected to deep delithiation. These studies, as reported here, have provided direct lines of evidence toward notable suppression of the variations of lattice parameters of Li-NMCs, including complete prevention of the detrimental “ c -axis collapse” at high states-of-charges and concomitant slower-cum-lower electrode stress development, in the presence of the Zn-dopant. Furthermore, the Zn-dopant has been found to also prevent the formation of Ni-enriched regions at the nanoscaled levels in Li-NMCs (i.e., Li/Ni-segregation or “structural densification”) even upon being subjected to 100 charge/discharge cycles involving deep delithiation (i.e., up to 4.7 V). Such detailed insights based on direct/real-time lines of evidence, which reveal important correlations between the suppression of Ni-migration and high-voltage compositional–structural–mechanical stability, hold immense significance toward the development of high capacity and stable “layered” Li-T M -oxide based cathode materials for the next-generation Li-ion batteries.

Topics & Concepts

Materials scienceDopantTetrahedronAtom probeAtom (system on chip)OccupancyChemical physicsCrystallographyNanotechnologyMolecular physicsOptoelectronicsDopingChemistryEcologyComputer scienceEmbedded systemTransmission electron microscopyBiologyAdvancements in Battery MaterialsSemiconductor materials and devicesSemiconductor materials and interfaces
Understanding the Effects of Tetrahedral Site Occupancy by the Zn Dopant in Li-NMCs toward High-Voltage Compositional–Structural–Mechanical Stability via Operando and 3D Atom Probe Tomography Studies | Litcius