3D Printable Ceramic–Polymer Electrolytes for Flexible High‐Performance Li‐Ion Batteries with Enhanced Thermal Stability

Blake, Aaron J.; Kohlmeyer, Ryan R.; Hardin, James O.; Carmona, Eric A; Maruyama, Benji; Berrigan, John D.; Huang, Hong; Durstock, Michael F.

doi:10.1002/aenm.201602920

Cited by 168 publications

(135 citation statements)

References 38 publications

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“…The wet 3D structures are subsequently freeze‐dried to give freestanding Ti 3 C 2 T x architectures without the necessity of any further thermal or chemical treatments as are normally required when using additives or GO . Freeze‐drying protects the internal integrity and the external shape of the structures with low shrinkage resulting in Ti 3 C 2 T x 3D architectures of well‐defined shapes ( Figure a–d) and filaments in the micrometer range.…”

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confidence: 99%

3D Printing of Freestanding MXene Architectures for Current‐Collector‐Free Supercapacitors

et al. 2019

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formulations that can maximize surface area accessibility and ion transport within electrodes while minimizing space and environmental impact. Consequently, Additive Manufacturing (AM) technologies, which are capable of printing 3D objects and complex structures, offer unique possibilities to bring novel electrode materials into highperformance EES devices. Among the AM technologies, continuous extrusion-based 3D printing (also called direct ink writing or robocasting) is a versatile and costeffective processing route where the formulation and properties of colloidal inks directly control the printability and architecture of printed parts. It further offers the ability to integrate functional materials of different surface chemistry and dimensionality into EES devices [1] such as Li-ion batteries, [2][3][4] micro-supercapacitors (MSCs), [5,6] and wearable electronics. [7,8] Recently, 2D transition metal carbides, called MXenes (M n+1 X n T x , with M representing an early transition metal, X representing C and/or N and, and T x representing the terminal functional groups), [9,10] have shown huge potential as electrode materials for supercapacitors. [11,12] Their combination of metallic conductivity, high density (3.8 ± 0.3 g cm −3 ), and redox active, negatively charged surfaces can lead to superior charge storage and transfer capabilities when compared to other 2D materials. Their surface functional groups (O, OH, and F) further render them hydrophilic allowing them to be easily dispersed into aqueous suspensions and inks for processing electrodes using different approaches such as vacuum filtration, [10,13] spin coating, [14,15] screen printing, [16,17] stamping, [18] and spraying. [19][20][21] While these approaches show the potential of MXene for water-based processing of EES devices, limitations remain with respect to architectural control, scalability, or cost-effectiveness that could be addressed by employing 3D printing technologies. Although MXene aqueous inks have been recently employed in commercial pens for direct writing functional films, [22] the development of 3D printable MXene inks and their integration into customized 3D device architectures is still unexplored. In order to realize this challenge, these materials need to be integrated into inks with very specific rheological properties that allow smooth flow through narrow nozzles while still enabling the extruded filaments to retain their shape even after multiple layers are Additive manufacturing (AM) technologies appear as a paradigm for scalable manufacture of electrochemical energy storage (EES) devices, where complex 3D architectures are typically required but are hard to achieve using conventional techniques. The combination of these technologies and innovative material formulations that maximize surface area accessibility and ion transport within electrodes while minimizing space are of growing interest. Herein, aqueous inks composed of atomically thin (1-3 nm) 2D Ti 3 C 2 T x with large lateral size of about 8 µm possessing ideal vis...

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3D Printing of Freestanding MXene Architectures for Current‐Collector‐Free Supercapacitors

et al. 2019

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“…Besides electrode materials, 3D printing of solid‐state electrolytes have also been reported over the past few years. Blake et al demonstrated a porous polymer based separator with a good thermal stability and electrolyte wetting ability . McOwen et al reported Li 7 La 3 Zr 2 O 12 based inks with two binder systems that could be built into thin and intricate architectures after sintering .…”

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confidence: 99%

“…Second, it is necessary to avoid shrinkage of the structure during solidification. Generally, solvent‐evaporation and solidification are achieved by postprocessing heat treatments, which would change the shape of the electrolyte layer, leading to its shrinkage and eventual distortion . This shrinkage could potentially be minimized by printing the electrolyte directly onto the electrode.…”

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Elevated‐Temperature 3D Printing of Hybrid Solid‐State Electrolyte for Li‐Ion Batteries

et al. 2018

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While 3D printing of rechargeable batteries has received immense interest in advancing the next generation of 3D energy storage devices, challenges with the 3D printing of electrolytes still remain. Additional processing steps such as solvent evaporation were required for earlier studies of electrolyte fabrication, which hindered the simultaneous production of electrode and electrolyte in an all-3D-printed battery. Here, a novel method is demonstrated to fabricate hybrid solid-state electrolytes using an elevated-temperature direct ink writing technique without any additional processing steps. The hybrid solid-state electrolyte consists of solid poly(vinylidene fluoride-hexafluoropropylene) matrices and a Li -conducting ionic-liquid electrolyte. The ink is modified by adding nanosized ceramic fillers to achieve the desired rheological properties. The ionic conductivity of the inks is 0.78 × 10 S cm . Interestingly, a continuous, thin, and dense layer is discovered to form between the porous electrolyte layer and the electrode, which effectively reduces the interfacial resistance of the solid-state battery. Compared to the traditional methods of solid-state battery assembly, the directly printed electrolyte helps to achieve higher capacities and a better rate performance. The direct fabrication of electrolyte from printable inks at an elevated temperature will shed new light on the design of all-3D-printed batteries for next-generation electronic devices.

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Section: Electrolyte Materials For 3d‐printed Batteriesmentioning

confidence: 99%

“…However, it is challenging to fabricate a high‐performance membrane with a controlled pore size using the traditional methods. Recently, Blake et al developed a new method to 3D print high‐performance and flexible ceramic–polymer electrolytes (CPEs) . In their work, PVDF and glycerol were dissolved by NMP, and then mixed with a high loading of Al 2 O 3 .…”

Section: Electrolyte Materials For 3d‐printed Batteriesmentioning

confidence: 99%

Additive Manufacturing of Batteries

Pang

Cao

Chu

et al. 2019

Adv Funct Materials

196

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Additive manufacturing, i.e., 3D printing, is being increasingly utilized to fabricate a variety of complex-shaped electronics and energy devices (e.g., batteries, supercapacitors, and solar cells) due to its excellent process flexibility, good geometry controllability, as well as cost and material waste reduction. In this review, the recent advances in 3D printing of emerging batteries are emphasized and discussed. The recent progress in fabricating 3D-printed batteries through the major 3D-printing methods, including lithographybased 3D printing, template-assisted electrodeposition-based 3D printing, inkjet printing, direct ink writing, fused deposition modeling, and aerosol jet printing, are first summarized. Then, the significant achievements made in the development and printing of battery electrodes and electrolytes are highlighted. Finally, major challenges are discussed and potential research frontiers in developing 3D-printed batteries are proposed. It is expected that with the continuous development of printing techniques and materials, 3D-printed batteries with long-term durability, favorable safety as well as high energy and power density will eventually be widely used in many fields.

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3D Printable Ceramic–Polymer Electrolytes for Flexible High‐Performance Li‐Ion Batteries with Enhanced Thermal Stability

Cited by 168 publications

References 38 publications

3D Printing of Freestanding MXene Architectures for Current‐Collector‐Free Supercapacitors

3D Printing of Freestanding MXene Architectures for Current‐Collector‐Free Supercapacitors

Elevated‐Temperature 3D Printing of Hybrid Solid‐State Electrolyte for Li‐Ion Batteries

Additive Manufacturing of Batteries

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