Abhishek Sarkar scite author profile

Interfacial reaction mechanisms at the anode/separator interface play a central role in the performance and safety of lithium-ion batteries during fast charging. We report a mechanistic study on the evolution and interactions of the aging mechanisms at the anode/separator interface in lithium cobalt oxide/graphite pouch cells charged with variable charging rates (1–6C) over 10 cycles. In situ electrochemical measurements, including voltage relaxation, Coulombic efficiency, and direct current internal resistance, indicated an incremental lithium loss until the C rates were ≤5C. A substantial capacity fade is observed in the first few cycles of fast charging, but the magnitude of capacity fade progressively diminishes with the number of cycles, indicating a suppression in the lithium deposition mechanism. Post-mortem film thickness, X-ray photoelectron spectroscopy (XPS), and scanning electron microscopy (SEM) analyses were performed to elucidate the evolution of electrolyte decomposition, the solid–electrolyte interface (SEI), lithium plating, and film fracture mechanisms with C rate. XPS measurements confirmed an increasing lithium concentration in an SEI film with an increase in the C rate. SEM images showed a growth of dendritic lithium on the anode surface from 1C to 3C. Precrack formation leading to an interfacial film fracture was observed at higher C rates. A differential analysis of the discharge capacity indicated a possible two-phase delithiation from the anode and reduced cathodic lithiation due to lithium loss at high C rates.

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Modeling of separator failure in lithium-ion pouch cells under compression

Sarkar

Shrotriya

Chandra

2019

Journal of Power Sources

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Functionalizing magnet additive manufacturing with in-situ magnetic field source

Sarkar

Somashekara

Paranthaman

et al. 2020

Additive Manufacturing

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Additive manufacturing via 3-D printing technologies have become a frontier in materials research, including its application in the development and recycling of permanent magnets. This work addresses the opportunity to integrate magnetic field sources into 3-D printing process in order to enable printing, alignment of anisotropic permanent magnets or magnetizing of magnetic filler materials, without requiring further processing. A non-axisymmetric electromagnet-type field source architecture was designed, modelled, constructed, and installed to a fused filament commercial 3-D printer and tested. The testing was performed by applying magnetic field while printing composite anisotropic Nd-Fe-B+Sm-Fe-N powders bonded in Nylon12 (65vol.%) and recycled Sm-Co powder bonded in PLA (15vol.%). Magnetic characterization indicated that the degree-of-alignment of the magnet powders increased both with alignment field strength (controlled by the current applied to the magnetizing system) and the printing temperature. Both coercivity and remanence were found to be strongly dependent on the degree-of-alignment except for printing performed below but near the Curie temperature of Nd-Fe-B (310°C). Under applied field of 0.15 kOe, Sm-Co and hybrid Nd-Fe-B/Sm-Fe-N printed samples showed degrees-of-alignment of 83% and 65%, respectively. The variations in coercivity were consistent with previous observations in bonded magnet materials. This work verifies that integration of magnetic field sources into 3-D printing processes will result in magnetic alignment of particles while ensuring that other advantages of 3-D printing are retained.

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Abhishek Sarkar

Performance degradation due to anodic failure mechanisms in lithium-ion batteries

Correlating capacity fade with film resistance loss in fast charging of lithium-ion battery

Anodic Interfacial Evolution in Extremely Fast Charged Lithium-Ion Batteries

Modeling of separator failure in lithium-ion pouch cells under compression

Functionalizing magnet additive manufacturing with in-situ magnetic field source

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