Addressing the Low Solubility of a Solid Electrolyte Interphase Stabilizer in an Electrolyte by Composite Battery Anode Design

摘要

Metallic sodium (Na) has been regarded as one of the most attractive anodes for Na-based rechargeable batteries due to its high specific capacity, low working potential, and high natural abundance. However, several important issues hinder the practical application of the metallic Na anode, including its high reactivity with electrolytes, uncontrolled dendrite growth, and poor processability. Metal nitrates are common electrolyte additives used to stabilize the solid electrolyte interphase (SEI) on Na anodes, though they typically suffer from poor solubility in electrolyte solvents. To address these issues, a Na/NaNO_(3) composite foil electrode was fabricated through a mechanical kneading approach, which featured uniform embedment of NaNO_(3) in a metallic Na matrix. During the battery cycling, NaNO_(3) was reduced by metallic Na sustainably, which addressed the issue of low solubility of an SEI stabilizer. Due to the supplemental effect of NaNO_(3), a stable SEI with NaN_(x )O_(y ) and Na_(3)N species was produced, which allowed fast ion transport. As a result, stable electrochemical performance for 600 h was achieved for Na/NaNO_(3)||Na/NaNO_(3) symmetric cells at a current density of 0.5 mA cm~(–2) and an areal capacity of 0.5 mAh cm~(–2). A Na/NaNO_(3)||Na_(3)V_(2)(PO_(4))_(2)O_(2)F cell with active metallic Na of ～5 mAh cm~(–2) at the anode showed stable cycling for 180 cycles. In contrast, a Na||Na_(3)V_(2)(PO_(4))_(2)O_(2)F cell only displayed less than 80 cycles under the same conditions. Moreover, the processability of the Na/NaNO_(3) composite foil was also significantly improved due to the introduction of NaNO_(3), in contrast to the soft and sticky pure metallic Na. Mechanical kneading of soft alkali metals and their corresponding nitrates provides a new strategy for the utilization of anode stabilizers (besides direct addition into electrolytes) to improve their electrochemical performance.