Colloidal route towards sodium ionic conductor (NASICON) 3D complex solid electrolyte structures fabricated by direct ink writing (DIW)

IF 2.9 Q1 MATERIALS SCIENCE, CERAMICS Open Ceramics Pub Date : 2024-09-19 DOI:10.1016/j.oceram.2024.100683
Oxel Urra , B. Ferrari , A.J. Sanchez-Herencia , Giorgia Franchin , Paolo Colombo
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Abstract

Progressing towards a sustainable energy model, safer new generation high-performance energy storage devices with large energy density and power are needed. In this sense, the improvement in terms of efficiency and sustainability has led to the interest in solid-state batteries (SSBs). Lately, sodium-ion batteries (SIBs) have become an emerging alternative due to the abundance of raw materials, low cost, and improvements in terms of fast sodium-ion conductor solid electrolytes (SCSEs). Among all the SCSEs, the sodium superionic conductor (NASICON) type electrolyte is one of the most well-known electrolytes, being widely developed in terms of synthesis and materials. However, the processing and manufacturing of these electrolytes have gone almost unnoticed, without considering that well-designed structures of electrodes/electrolytes are the bridge toward turning advanced energy materials into high-performance devices. This work presents the fabrication of 3D complex structures based on NASICON sodium solid electrolytes, obtained for the first time by direct ink writing (DIW). Through a colloidal route, fine NASICON phase powder with high pureness was prepared, enabling the manufacturing of intricate NASICON-printed electrolytes in a one-step fabrication process. By optimizing the ink, a dense electrolyte layer, acting as an ionic conductor and separator, was inserted between two complex porous pattern layers obtaining a device with a total height below 1.15 mm. Further, the densification of the 3D electrolyte was enhanced, reaching high ionic conductivities at room temperature (3.10−4 S cm−1). Thus, a high-performance sodium ion conductor NASICON solid electrolyte with shorter diffusion pathways and larger interfacial surface areas between electrode/electrolyte was obtained, improving the overall electrochemical performance of the device by a 3D layer-by-layer design.

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通过直接墨水写入(DIW)制造钠离子导体(NASICON)三维复合固体电解质结构的胶体路线
为实现可持续能源模式,需要更安全、能量密度更大、功率更强的新一代高性能储能设备。从这个意义上说,固态电池(SSBs)在效率和可持续性方面的改进引起了人们的兴趣。最近,钠离子电池(SIB)由于原材料丰富、成本低廉以及钠离子导体固体电解质(SCSE)的改进而成为一种新兴的替代品。在所有 SCSE 中,钠超离子导体(NASICON)型电解质是最著名的电解质之一,在合成和材料方面得到了广泛开发。然而,这些电解质的加工和制造几乎没有引起人们的注意,没有考虑到精心设计的电极/电解质结构是将先进能源材料转化为高性能设备的桥梁。这项工作展示了基于 NASICON 固态钠电解质的三维复杂结构的制造,这是首次通过直接墨水写入(DIW)技术获得的。通过胶体路线,制备出了高纯度的精细 NASICON 相粉末,从而实现了一步法制造复杂的 NASICON 印刷电解质。通过优化油墨,在两个复杂的多孔图案层之间插入了致密的电解质层,该电解质层既是离子导体,又是隔离层,从而获得了总高度低于 1.15 毫米的装置。此外,三维电解质的致密性也得到了提高,在室温下达到了很高的离子电导率(3.10-4 S cm-1)。因此,通过三维逐层设计,获得了一种具有更短扩散途径和更大电极/电解质界面表面积的高性能钠离子导体 NASICON 固体电解质,提高了器件的整体电化学性能。
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来源期刊
Open Ceramics
Open Ceramics Materials Science-Materials Chemistry
CiteScore
4.20
自引率
0.00%
发文量
102
审稿时长
67 days
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