Building Near‐Unity Stacked (002) Texture for High‐Stable Zinc Anode

Dendrite-free Zn anode is the key to avoiding battery failure, which is largely determined by the crystal growth during the electrodeposition process. Therefore, controlling the specific crystal orientation growth of Zn is imperative for high-performing aqueous zinc ion batteries. Herein, an electrocrystallization orientation regulation strategy is proposed to achieve near-unity stacked Zn (002) texture growth. Featuring the zincophilic nature and high electronegative carboxylate radical, disodium maleate molecules tend to selectively adsorb on the Zn (002) crystal plane, forming a dynamic protection layer. This adsorption layer regulates Zn2+ diffusion along [100] and [101] orientations with the lowest deposition rate on the (002) plane, homogenizes Zn2+ flux, and keeps away water from Zn surface, constructing the flattened and horizontally arranged Zn deposition layer with dominantly Zn (002) texture and inhibited side-reaction. Consequently, the Zn anode with near-unity stacked (002) texture exhibits a 40-fold enhancement in running lifetime beyond 3200 h and improved coulombic efficiency of 99.81% over 3000 cycles than that with bare ZnSO4 electrolyte. Even at harsh plating/stripping conditions of 30 and 30 mAh cm-2, the Zn anode still sustains state-of-the-art stability over 120 h, enabling a substantial advance in the long-term stability of the battery. A dendrite-free Zn anode is fabricated by forming a near-unity stacked Zn (002) texture with the adsorption regulation of Disodium maleate (DMA). Featuring the zincophilic nature and high electronegative carboxylate radical, DMA molecules are prone to adsorb on the Zn surface and restrain the Zn deposition along the (002) orientation, leading to the dominant Zn (002) texture exposure.image