Manufacturing Strategies for Solid Electrolyte in Batteries

Chen, Annan; Qu, Conghang; Shi, Yusheng; Shi, Feifei

doi:10.3389/fenrg.2020.571440

Cited by 49 publications

(35 citation statements)

References 146 publications

(136 reference statements)

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“…However, there are notable challenges to producing high-ionic conductivity SSEs using current methods such as vacuum-based radio frequency (RF), atomic-layer deposition (ALD), chemical-vapor deposition (CVD), and pulsed-layer deposition (PLD). 28,80 These traditional approaches are either cost-prohibitive, time-consuming, or less scalable. The long sintering time at high temperatures during these processes will inevitably cause severe Li and Na loss in ISEs, leading to low ionic conductivities ($10 À8 to 10 À4 S cm À1 ) and poor electrochemical performance.…”

Section: Printing Strategies For Ssesmentioning

confidence: 99%

Challenge-driven printing strategies toward high-performance solid-state lithium batteries

2022

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Section: Printing Strategies For Ssesmentioning

confidence: 99%

Challenge-driven printing strategies toward high-performance solid-state lithium batteries

2022

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“…For instance, liquid electrolytes can be flammable, volatile, and prone to form unstable interfaces and electrolyte passivation layers [54]. To mitigate such challenges, solid-state electrolytes emerge as viable candidates which provide more chemical stability, are inherently safer, and can contribute towards maximizing the energy density [55]. Nevertheless, as with liquid electrolytes, there are a few challenges associated with solid-state electrolytes which hinder their exploitation to their maximum potential.…”

Section: D Printed Electrolyte Materials and Their Propertiesmentioning

confidence: 99%

Advances in 3D Printing for Electrochemical Energy Storage Systems

Menon

Khan²,

Balakrishnan

et al. 2021

J. Mater. Sci. Technol. Res.

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In the current scenario, energy generation is relied on the portable gadgets with more efficiency paving a way for new versatile and smart techniques for device fabrication. 3D printing is one of the most adaptable fabrication techniques based on designed architecture. The fabrication of 3D printed energy storage devices minimizes the manual labor enhancing the perfection of fabrication and reducing the risk of hazards. The perfection in fabrication technique enhances the performance of the device. The idea has been built upon by industry as well as academic research to print a variety of battery components such as cathode, anode, separator, etc. The main attraction of 3D printing is its cost-efficiency. There are tremendous savings in not having to manufacture battery cells separately and then assemble them into modules. This review highlights recent and important advances made in 3D printing of energy storage devices. The present review explains the common 3D printing techniques that have been used for the printing of electrode materials, separators, battery casings, etc. Also highlights the challenges present in the technique during the energy storage device fabrication in order to overcome the same to develop the process of 3D printing of the batteries to have comparable performance to, or even better performance than, conventional batteries.

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“…Furthermore, Dupont and coworkers recently used an additive manufacturing technology to prepare a printable polyethylene oxide/lithium bis(trifluoromethanesulfonyl)imide (PEO/LiTFSI) filament which can be subsequently fed into an FDM 3D printer [ 26 ]. Thus, development of novel materials is needed to make current 3D-techniques capable to fulfill requirements for battery production [ 27 ].…”

Section: Introductionmentioning

confidence: 99%

3D Printable Composite Polymer Electrolytes: Influence of SiO2 Nanoparticles on 3D-Printability

et al. 2022

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We here demonstrate the preparation of composite polymer electrolytes (CPEs) for Li-ion batteries, applicable for 3D printing process via fused deposition modeling. The prepared composites consist of modified poly(ethylene glycol) (PEG), lithium bis(trifluoromethylsulfonyl)imide (LiTFSI) and SiO2-based nanofillers. PEG was successfully end group modified yielding telechelic PEG containing either ureidopyrimidone (UPy) or barbiturate moieties, capable to form supramolecular networks via hydrogen bonds, thus introducing self-healing to the electrolyte system. Silica nanoparticles (NPs) were used as a filler for further adjustment of mechanical properties of the electrolyte to enable 3D-printability. The surface functionalization of the NPs with either ionic liquid (IL) or hydrophobic alkyl chains is expected to lead to an improved dispersion of the NPs within the polymer matrix. Composites with different content of NPs (5%, 10%, 15%) and LiTFSI salt (EO/Li+ = 5, 10, 20) were analyzed via rheology for a better understanding of 3D printability, and via Broadband Dielectric Spectroscopy (BDS) for checking their ionic conductivity. The composite electrolyte PEG 1500 UPy2/LiTFSI (EO:Li 5:1) mixed with 15% NP-IL was successfully 3D printed, revealing its suitability for application as printable composite electrolytes.

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Manufacturing Strategies for Solid Electrolyte in Batteries

Cited by 49 publications

References 146 publications

Challenge-driven printing strategies toward high-performance solid-state lithium batteries

Challenge-driven printing strategies toward high-performance solid-state lithium batteries

Advances in 3D Printing for Electrochemical Energy Storage Systems

3D Printable Composite Polymer Electrolytes: Influence of SiO2 Nanoparticles on 3D-Printability

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