TY - JOUR AU - Bin Xiang AU - Lei Wang AU - Gao Liu AU - Andrew M Minor AB -

We provide a detailed electromechanical study of individual core/shell structure – Li metal/Li2CO3 particles by utilizing an in-situ probing technique in the transmission electron microscope (TEM). This technique allows us to concurrently monitor the mechanical and electrical response of single Li/Li2CO3 core/shell structures in real time. The pressure on the Li/Li2CO3 core/shell particle was measured to be ∼15 MPa at the initiation of fracture and the conductivity of the Li2CO3 shell is estimated to be ∼10−6 S/cm. To simulate the application of the core-shell particles in a real battery, we assembled coin cells with Li metal as a counter electrode. Prior to the cell assembly, the electrode was compressed in order to break the Li2CO3 shells to expose the fresh lithium metal to the graphite. When the electrolyte is added to wet the electrode, an electrochemical reaction spontaneously occurs between the exposed Li and graphite particles to produce a partially lithiated graphite anode. This lithiation occurs prior to the initial charging process, therefore compensating for the irreversible capacity loss due to the lithium consummation events during standard formation. Our results demonstrate a new pathway for the utilization of non-lithiated cathode material in future Li-ion batteries

BT - Journal of the Electrochemical Society DA - 01/2013 DO - 10.1149/2.018303jes IS - 3 LA - eng N2 -

We provide a detailed electromechanical study of individual core/shell structure – Li metal/Li2CO3 particles by utilizing an in-situ probing technique in the transmission electron microscope (TEM). This technique allows us to concurrently monitor the mechanical and electrical response of single Li/Li2CO3 core/shell structures in real time. The pressure on the Li/Li2CO3 core/shell particle was measured to be ∼15 MPa at the initiation of fracture and the conductivity of the Li2CO3 shell is estimated to be ∼10−6 S/cm. To simulate the application of the core-shell particles in a real battery, we assembled coin cells with Li metal as a counter electrode. Prior to the cell assembly, the electrode was compressed in order to break the Li2CO3 shells to expose the fresh lithium metal to the graphite. When the electrolyte is added to wet the electrode, an electrochemical reaction spontaneously occurs between the exposed Li and graphite particles to produce a partially lithiated graphite anode. This lithiation occurs prior to the initial charging process, therefore compensating for the irreversible capacity loss due to the lithium consummation events during standard formation. Our results demonstrate a new pathway for the utilization of non-lithiated cathode material in future Li-ion batteries

PY - 2013 SN - 0013-4651 SP - A415 EP - A419 T2 - Journal of the Electrochemical Society TI - Electromechanical Probing of Li/Li2CO3 Core/Shell Particles in a TEM VL - 160 ER -