Flexible Zn‐Ion Batteries: Recent Progresses and Challenges

Abstract: the developing trend of modern electronic technologies, [6] and significant efforts have been devoted to transforming these energy storage systems to their light, flexible, small, and thin counterparts. [7] The flexible battery market is forecast to increase rapidly from $69.6 million in 2015 to $958.4 million in 2022. [8] Lithium-ion batteries (LIBs) historically and presently dominant the markets of rechargeablebattery for portable devices because of the lightness of lithium and high energy density of the ba… Show more

“…Dissolved ions in hydrogels substantially modify the structure and dynamics of water molecules due to the hydration. As a result, the addition of commonly used electrolyte, 2 mol L −1 ZnSO 4 , into the PAAm hydrogel (referred to as Z-PAAm hereafter) significantly reduces the contribution from intermolecular hydrogen bonding due to two strongly hydrated ions (Zn 2+ and SO 4 2− ). [30] We identify two main contributions to the water vibration band of the pure PAAm: intermolecular hydrogen bonds at 3220 cm −1 and asymmetric stretching at 3420 cm −1 .…”

“…The structure of the water molecules is revealed by the Raman spectra in Figure 1b. However, the strong ion pairing between Zn 2+ and SO 4 2− that induces the aggregation of ions alleviates the hydration. [31,32] In general, hydrated ions in water diminish the intermolecular hydrogen bonds and elevate the asymmetric stretching.…”

“…As a result, the addition of commonly used electrolyte, 2 mol L −1 ZnSO 4 , into the PAAm hydrogel (referred to as Z-PAAm hereafter) significantly reduces the contribution from intermolecular hydrogen bonding due to two strongly hydrated ions (Zn 2+ and SO 4 2− ). Therefore, LiCl (4 mol L −1 ), a highly soluble salt containing highly hydrated Li + ion, is introduced, forming a mixture solution containing Li + , Zn 2− , Cl − , and SO 4 2− ions. [33][34][35] This is supported by the fact that the reduction of intermolecular hydrogen bonds and enhancement of asymmetric stretching of Z-PAAm is less obvious than PAAm containing 2 mol L −1 ZnCl 2 ( Figure S2a, Supporting Information), even though the hydration number of Cl − is negligible in water.…”

“…However, the strong ion pairing between Zn 2+ and SO 4 2− that induces the aggregation of ions alleviates the hydration. The high solubility of chlorides can effectively prevent ion aggregation, thus ensuring hydration of Li + , Zn 2− , and SO 4 2− even at a high concentration. [36] Therefore, in order to further intensify the hydration of water in hydrogels, adding alternative ions with high hydration number is a more efficient strategy than pushing the concentration of ZnSO 4 .…”

“…The former attribute gives rise to an excellent capacity retention (98%) achieved by the flexible aqueous battery based on LiFePO 4 and Zn upon cooling down to −20 °C from room temperature, as well as the outstanding durability under various mechanical deformations over a wide temperature range. Highly hydrated cations not only lower the freezing temperature of the hydrogel but also improve the reversibility of the zinc anode cycled in the hydrogel.…”

Antifreezing Hydrogel with High Zinc Reversibility for Flexible and Durable Aqueous Batteries by Cooperative Hydrated Cations

“…Dissolved ions in hydrogels substantially modify the structure and dynamics of water molecules due to the hydration. As a result, the addition of commonly used electrolyte, 2 mol L −1 ZnSO 4 , into the PAAm hydrogel (referred to as Z-PAAm hereafter) significantly reduces the contribution from intermolecular hydrogen bonding due to two strongly hydrated ions (Zn 2+ and SO 4 2− ). [30] We identify two main contributions to the water vibration band of the pure PAAm: intermolecular hydrogen bonds at 3220 cm −1 and asymmetric stretching at 3420 cm −1 .…”

“…The structure of the water molecules is revealed by the Raman spectra in Figure 1b. However, the strong ion pairing between Zn 2+ and SO 4 2− that induces the aggregation of ions alleviates the hydration. [31,32] In general, hydrated ions in water diminish the intermolecular hydrogen bonds and elevate the asymmetric stretching.…”

“…As a result, the addition of commonly used electrolyte, 2 mol L −1 ZnSO 4 , into the PAAm hydrogel (referred to as Z-PAAm hereafter) significantly reduces the contribution from intermolecular hydrogen bonding due to two strongly hydrated ions (Zn 2+ and SO 4 2− ). Therefore, LiCl (4 mol L −1 ), a highly soluble salt containing highly hydrated Li + ion, is introduced, forming a mixture solution containing Li + , Zn 2− , Cl − , and SO 4 2− ions. [33][34][35] This is supported by the fact that the reduction of intermolecular hydrogen bonds and enhancement of asymmetric stretching of Z-PAAm is less obvious than PAAm containing 2 mol L −1 ZnCl 2 ( Figure S2a, Supporting Information), even though the hydration number of Cl − is negligible in water.…”

“…However, the strong ion pairing between Zn 2+ and SO 4 2− that induces the aggregation of ions alleviates the hydration. The high solubility of chlorides can effectively prevent ion aggregation, thus ensuring hydration of Li + , Zn 2− , and SO 4 2− even at a high concentration. [36] Therefore, in order to further intensify the hydration of water in hydrogels, adding alternative ions with high hydration number is a more efficient strategy than pushing the concentration of ZnSO 4 .…”

“…The former attribute gives rise to an excellent capacity retention (98%) achieved by the flexible aqueous battery based on LiFePO 4 and Zn upon cooling down to −20 °C from room temperature, as well as the outstanding durability under various mechanical deformations over a wide temperature range. Highly hydrated cations not only lower the freezing temperature of the hydrogel but also improve the reversibility of the zinc anode cycled in the hydrogel.…”

Antifreezing Hydrogel with High Zinc Reversibility for Flexible and Durable Aqueous Batteries by Cooperative Hydrated Cations

Development of Full Zinc‐Ion Batteries

A Sieve‐Functional and Uniform‐Porous Kaolin Layer toward Stable Zinc Metal Anode