Towards an advanced electrochemical horizon: ion selectivity and energy harnessing through hybrid capacitive deionization with carbon-coated NaTi2(PO4)3 and N-rich carbon nests†

IF 10.7 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Journal of Materials Chemistry A Pub Date : 2024-10-14 DOI:10.1039/D4TA04413D
Hanieh Sharifpour, Farzaneh Hekmat, Saeed Shahrokhian and Likun Pan
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Abstract

For both water softening and energy storage, to date, a variety of capacitive devices have been developed; however, their dual functionality has been rarely investigated. An enhanced selective sodium-ion removal along with charge-storage was achieved by combining sodium-ion capture and release through sorption and regeneration steps of a capacitive deionization (CDI) process, respectively. Leveraging their unique and reversible Na+-removal capability, sodium superionic conductors (NASICONs) hold immense promise for hybrid capacitive deionization (HCDI). Despite the great desalination ability of HCDI systems, the unbalanced ion-capture and the possibility of co-ion expulsion have led to a real bottleneck that can effectively be tackled by placing an ion exchange membrane (IEM) between the electrolyte and the electrode. Herein, the state-of-the-art Na+ selective technology has been engineered using well-matched carbon-coated NaTi2(PO4)3 (NTP-C) and N-rich carbon nests (NCNs) as negative and positive electrodes, respectively. The fabricated HCDI cells benefit from a commendable salt adsorption capacity (SAC) of 96.8 mg g−1, a salt adsorption rate (SAR) of 2.42 mg g−1 min−1, and a specific energy consumption (Es) of 18.5 j mgNaCl−1 in the sorption step. These devices also achieve a remarkable energy storage capacity (Q) of 46.52 C g−1 at a low concentration of NaCl (500 ppm) in the regeneration step. The NTP-C//NCN HCDI systems achieved remarkable cycle stability with almost 92.3 and 91.3% retention of their salt adsorption and charge storage capacities, respectively, after 30 continuous cycles. The Na+ selective removal capability of the fabricated HCDI systems was evaluated by comparing their Na+ removal capacity in the absence and presence of Mg2+, Ca2+, and K+ ions (SNa+/X > 2.5) which resulted in a superior sodium removal efficiency (SRE%) of almost over 50% from both pure and contaminated mixtures. As a direct consequence of high charge storage capacity, the fabricated HCDI is well-suited for energy applications, so it marks the beginning of a pioneer horizon towards the commercialization of HCDI technologies.

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迈向先进的电化学地平线:通过碳涂层 NaTi2(PO4)3 和富含 N 的碳巢混合电容式去离子技术实现离子选择性和能量利用
盐水软化覆盖了地球表面三分之二的面积,听起来似乎是弥合饮用水生产与日益增长的需求之间差距的最可行方法。目前已开发出许多电容式装置,用于软化水或从资源回收中存储电荷,但很少有人研究它们的双重功效。通过 CDI 工艺,利用吸附步骤中的钠捕获和再生步骤中的钠释放相结合的方法,增强了选择性钠去除和电荷存储能力。钠超离子导体(NASICON)具有独特的可逆钠去除特性,尤其是那些使用碳元素改变的钠超离子导体,因此有望成为混合电容式去离子技术(HCDI)的候选材料。尽管混合电容式去离子技术具有很强的脱盐能力,但其不平衡的离子捕获能力和共离子驱逐可能性的上升导致了一个真正的瓶颈,而在电解质和电极之间放置离子交换膜(IEM)则可以显著解决这一问题。在此,我们采用了最先进的 Na+ 选择性技术,将匹配良好的碳涂层 NaTi2(PO4)3 (NTP-C) 和富含 N 的碳巢 (NCN) 分别作为负极和正极。所制备的 HCDI 性能优异,其盐吸附容量(SAC)为 96.8 mg g-1,盐吸附速率(SAR)为 2.42 mg g-1 min-1,吸附步骤中的比能量消耗(Es)为 18.5 j mg-1NaCl,同时在再生步骤中,在 500 ppm 的极低浓度 NaCl 下具有 46.52 C g-1 的完美储能容量(Q)。NTP-C//NCN HCDI 系统具有显著的循环稳定性,在连续循环 30 次后,盐吸附和电荷存储容量的保持率分别达到 92.3% 和 91.3%。通过比较其在无 Mg2+、Ca2+ 和 K+ 离子(S Na+/X > 2.5)和有 Mg2+、Ca2+ 和 K+ 离子(S Na+/X >2.5)情况下的 Na+ 清除能力,探索了所制造的 HCDI 的 Na+ 选择性清除能力。总之,我们开发出了具有显著 Na+ 选择性的高产能高效 HCDI 设备,即使在背景离子共存的情况下,也有望实现选择性离子去除。高电荷存储容量的直接结果是,所制造的 HCDI 在能源应用方面值得称赞,因此为 HCDI 技术的商业化开创了先河。
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来源期刊
Journal of Materials Chemistry A
Journal of Materials Chemistry A CHEMISTRY, PHYSICAL-ENERGY & FUELS
CiteScore
19.50
自引率
5.00%
发文量
1892
审稿时长
1.5 months
期刊介绍: The Journal of Materials Chemistry A, B & C covers a wide range of high-quality studies in the field of materials chemistry, with each section focusing on specific applications of the materials studied. Journal of Materials Chemistry A emphasizes applications in energy and sustainability, including topics such as artificial photosynthesis, batteries, and fuel cells. Journal of Materials Chemistry B focuses on applications in biology and medicine, while Journal of Materials Chemistry C covers applications in optical, magnetic, and electronic devices. Example topic areas within the scope of Journal of Materials Chemistry A include catalysis, green/sustainable materials, sensors, and water treatment, among others.
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