Towards smart free form-factor 3D printable batteries

Friman, Hen; Menkin, Svetlana; Kamir, Yosef; Gladkikh, Alex; Mukra, Tzach; Kósa, Gábor; Golodnitsky, Diana

doi:10.1039/c8se00122g

Cited by 71 publications

(68 citation statements)

References 25 publications

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“…Solidification of each layer is principally based on crystallization and chain entanglement of the polymer, however, addition of additive materials can affect the properties and solidification process of the matrix polymer. Common additives used in polymer matrix for EESDs are various conductive materials like ABS/graphene [26], ABS/carbon [27], PLA/graphene [28] and even PLA/LTO/carbon and PLA/LFP/carbon [29]* which are essential for electrode fabrication in lithium ion batteries. A good example is a recent study [30]** where three conductive agents (Super-P, MWCNTs, graphene) and two active materials (Lithium titanate, lithium manganese oxide) were blended with PLA to test the printability, conductivity and charge storage capacity of the new composite.…”

Section: Materials and Methods Considerationmentioning

confidence: 99%

Additive manufacturing for energy storage: Methods, designs and material selection for customizable 3D printed batteries and supercapacitors

Gulzar

Glynn

O’Dwyer

2020

Current Opinion in Electrochemistry

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Additive manufacturing and 3D printing in particular have the potential to revolutionize existing fabrication processes where objects with complex structures and shapes can be built with multifunctional material systems. For electrochemical energy storage devices such as batteries and supercapacitors, 3D printing methods allows alternative form factors to be conceived based on the end use application need in mind at the design stage. Additively manufactured energy storage devices require active materials and composites that are printable and this is influenced by performance requirements and the basic electrochemistry. The interplay between electrochemical response, stability, material type, object complexity and end use application are key to realising 3D printing for electrochemical energy storage. Here, we summarise recent advances and highlight the important role of methods, designs and material selection for energy storage devices made by 3D printing, which is general to the majority of methods in use currently.

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Section: Materials and Methods Considerationmentioning

confidence: 99%

Additive manufacturing for energy storage: Methods, designs and material selection for customizable 3D printed batteries and supercapacitors

Gulzar

Glynn

O’Dwyer

2020

Current Opinion in Electrochemistry

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“…[83] Most frequently used anode active materials in 3D printed Li-ion batteries are graphite, graphene, and lithium titanate (Li 4 Ti 5 O 12 , LTO). [46,52,64,70,108,109] Polymer binders and matrices used for preparation of printable compositions can be thermoplastic polymers (e.g., PLA and ABS), functionalized cellulose, PVDF or aqueous GO. [64,70,108,110] A representative work describing the preparation of highly loaded (up to 62.5 wt%) graphite-PLA conductive composites used as filaments for FDM 3D printing of Li-ion battery negative electrodes was published by Maurel et al [70] Such a high graphite content naturally caused brittleness of produced samples and required the addition of plasticizers (at least 20 wt% and less than 60 wt%) in order to be printable by FDM method.…”

Section: D Printed Active Materialsmentioning

confidence: 99%

“…As in the case of anode materials, polymer binders and conductive additives can also be included in the printable composition to achieve the required conductivity, mechanical and rheological properties of the cathode material. [46,52,[108][109][110][111] Most of the considerations previously discussed for 3D printing of metal oxides and LIB anode materials are also true for LIB cathode materials. The difference between theoretical capacity of active materials and the obtained values along with the poor C-rate performance, commonly reported in connection with polymer-based composites and material extrusion 3D printing techniques, can be explained by insufficient electronic and ionic conductivity of the printed materials due to complete isolation of some amount of conductive materials within polymer matrix.…”

Section: D Printed Active Materialsmentioning

confidence: 99%

“…The initial reports using ME, MJ, and VAT-P, commonly referred to as FDM, IJP and stereolithographic apparatus (SLA), respectively, have been used to fabricate substrates, thin film electrodes and electrolytes in half-cell and full-cell Li-batteries. As shown in Figure 7, the majority of systems reported so far are half-cell Li-batteries using electrodes mainly involving graphene, [115][116][117] Li 4 Ti 5 O 12 , [118] SnO 2 , [119] MnO 2 , [120] Si [121] as anodes, as well as LiFePO 4 [118,122,123] and LiCoO 2 cathodes; [124,125] the handful of full-cell 3D printed Li-electrodes focused on lithium iron phosphate cathode and lithium titanate anode. [31,126,127] Compared to ME and MJ methods, we are aware of just one report (at the time of writing) using the VAT-P method to print Li-battery electrodes.…”

Section: Extrusion Inkjetting and Stereolithographic Printing Of LImentioning

confidence: 99%

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Evolution of 3D Printing Methods and Materials for Electrochemical Energy Storage

et al. 2020

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Additive manufacturing has revolutionized the building of materials, and 3D‐printing has become a useful tool for complex electrode assembly for batteries and supercapacitors. The field initially grew from extrusion‐based methods and quickly evolved to photopolymerization printing, while supercapacitor technologies less sensitive to solvents more often involved material jetting processes. The need to develop higher‐resolution multimaterial printers is borne out in the performance data of recent 3D printed electrochemical energy storage devices. Underpinning every part of a 3D‐printable battery are the printing method and the feed material. These influence material purity, printing fidelity, accuracy, complexity, and the ability to form conductive, ceramic, or solvent‐stable materials. The future of 3D‐printable batteries and electrochemical energy storage devices is reliant on materials and printing methods that are co‐operatively informed by device design. Herein, the material and method requirements in 3D‐printable batteries and supercapacitors are addressed and requirements for the future of the field are outlined by linking existing performance limitations to requirements for printable energy‐storage materials, casings, and direct printing of electrodes and electrolytes. A guide to materials and printing method choice best suited for alternative‐form‐factor energy‐storage devices to be designed and integrated into the devices they power is thus provided.

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“…Li 4 Ti 5 O 12 and LiFePO 4 are the most commonly used anode and cathode materials in 3D‐printed batteries, exhibiting a minimal volumetric expansion, high rate capability, high stability, and security. In recent years, an increasing number of studies on the 3D printing of LTO/LFP‐based electrodes have been reported . The first 3D‐interdigitated microbattery architectures (3D‐IMA) with LTO/LFP materials were developed by the Lewis Group .…”

Section: Electrode Materials For 3d‐printed Batteriesmentioning

confidence: 99%

Additive Manufacturing of Batteries

Pang

Cao

Chu

et al. 2019

Adv Funct Materials

190

123

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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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Towards smart free form-factor 3D printable batteries

Cited by 71 publications

References 25 publications

Additive manufacturing for energy storage: Methods, designs and material selection for customizable 3D printed batteries and supercapacitors

Additive manufacturing for energy storage: Methods, designs and material selection for customizable 3D printed batteries and supercapacitors

Evolution of 3D Printing Methods and Materials for Electrochemical Energy Storage

Additive Manufacturing of Batteries

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