Lee Jun Ho, Cho Yoon-Gyo, Gu Dongeun, Kim Suk Jun
School of Energy, Materials and Chemical Engineering, Korea University of Technology and Education (KOREATECH), Cheonan 31253, South Korea.
Battery R&D, R&D Campus, LG Energy Solution, Daejeon 34122, South Korea.
ACS Appl Mater Interfaces. 2022 Apr 6;14(13):15080-15089. doi: 10.1021/acsami.1c21183. Epub 2022 Feb 28.
The practical implementation of anode-free batteries is limited by factors such as lithium dendrite growth and low cycling Coulombic efficiency (CE). In this study, the improvement in the electrochemical performance of anode-free rechargeable lithium batteries bearing a Cu current collector (CC) coated with PdTe thin films is reported. The optimized thickness and sputtering heating conditions of the PdTe layer are 15 nm and 473.15 K, respectively. Upon deposition on a CC, PdTe works as a seed layer that considerably improves the CE in half-cells, owing to its unique 2D structure that reduces the nucleation overpotential. A further contribution to the high performance is brought about by a CuTe interphase between the coating layer and Cu CC formed during heating. Such an interphase contributes to the high CE by improving the uniformity of the current density distribution on the CC that suppresses lithium dendrite growth. A low nucleation overpotential and uniform current density distribution, in turn, result in a smooth morphology of the plated Li. The full cell obtained with the PdTe-coated CC exhibits a capacity retention of 70.7% after the 100th cycle, with an average CE of 99.65% at a 0.2C rate─an outstanding result in view of the rapid development of lithium-ion batteries.
无阳极电池的实际应用受到锂枝晶生长和低循环库仑效率(CE)等因素的限制。在本研究中,报道了带有涂覆有PdTe薄膜的铜集流体(CC)的无阳极可充电锂电池的电化学性能的改善。PdTe层的优化厚度和溅射加热条件分别为15 nm和473.15 K。沉积在CC上时,PdTe作为种子层,由于其独特的二维结构降低了成核过电位,从而显著提高了半电池中的CE。加热过程中在涂层和铜CC之间形成的CuTe界面相也对高性能有进一步贡献。这种界面相通过改善CC上电流密度分布的均匀性来抑制锂枝晶生长,从而有助于实现高CE。低成核过电位和均匀的电流密度分布进而导致镀锂的形态平滑。使用涂覆有PdTe的CC获得的全电池在第100次循环后容量保持率为70.7%,在0.2C倍率下平均CE为99.65% —— 鉴于锂离子电池的快速发展,这是一个出色的结果。
