Recent Advances and Perspectives of Carbon-Based Nanostructures as Anode Materials for Li-ion Batteries

Roselin, L. Selva; Juang, Ruey‐Shin; Hsieh, Chien‐Te; Sagadevan, Suresh; Umar, Ahmad; Selvin, Rosilda; Hegazy, H.H.

doi:10.3390/ma12081229

Cited by 112 publications

(76 citation statements)

References 239 publications

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“…Some of these materials are also capable of reversible Li ion intercalation and have appreciable intrinsic specific capacitance. [56,68] They have been utilized in various 3D printing techniques (extrusion-based, inkjet printing, IJP; selective laser sintering (SLS)) in the form of polymer-based conductive composites used for fabrication of electrically conductive structures, supercapacitor electrodes, Li-ion battery electrodes. [68][69][70][71][72] Carbon nanotubes are promising candidates for current collector and electrode 3D printing due to high carrier mobility, superior mechanical strength and large specific surface area that can be functionalized for improved energy storage performance.…”

Section: Conductive Materials and Cell Casingmentioning

confidence: 99%

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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Section: Conductive Materials and Cell Casingmentioning

confidence: 99%

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

et al. 2020

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“…Consequently, the present LIBs have been successfully incorporated into portable consumer electronic devices, electric vehicles (EVs), and defense applications . In LIBs, different types of carbon (graphite, amorphous/hard carbon, porous carbons), alloys matrix (containing Si, Sn, Sb, Ni, Ti metals), composite alloys (a combination of carbon and an alloy), and metal oxides (Li 4 Ti 5 O 12 , TiO 2 , SnO 2 , SiO 2 ) have been extensively studied in the past three decades as anode materials. The developed anodes have been combined with high‐voltage cathodes, mainly LiCoO 2 , LiFePO 4 , LiNi 1/3 Mn 1/3 Co 1/3 O 2 , (LNMC), LiMn 2 O 4 , and LiMn 1.5 Ni 0.5 O 4 materials, demonstrating a prolonged cycling stability while maintaining a high Coulombic efficiency during charge–discharge cycles .…”

Section: Introductionmentioning

confidence: 99%

Lithium Metal Battery Pouch Cell Assembly and Prototype Demonstration Using Tailored Polypropylene Separator

et al. 2020

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The development of realistic lithium metal batteries (LMBs) is highly desirable to address the steady increase in the energy‐storage demand for high‐power applications. Consequently, the polydopamine‐tailored polypropylene separator enables scale up with ≈8 μm‐thick graphene nanosheets coating on the polypropylene separator. A layered LiNi1/3Mn1/3Co1/3O2 (LNMC) cathode is characterized by X‐ray diffraction analysis (XRD) and scanning electron microscopy (SEM) analysis, which exhibits single phase purity with a hexagonal structure, R3¯m space group, and a homogenized spherical shape morphology with secondary particles comprising primary particles. Lithium metal battery pouch cells (LMBPCs) are fabricated based on the proposed design strategies, containing a lithium metal anode, LNMC cathode, and tailored polypropylene separator without any internal short circuit, wherein polydopamine and graphene nanosheets layers are positioned toward the LNMC cathode in the pouch cell stacking order. The assembled pouch cell is cycled between 3.0 and 4.2 V and delivers a cell capacity of ≈500 mAh. Then the charged LMBPCs are connected to the prototype electronic truck and demonstrated on various surfaces at 25 °C and < −5 °C. From the prototype truck demonstration results, LMBPCs are useful for practical high‐power applications, including electric vehicles, hybrid electric vehicles, and grid energy storage.

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“…New materials must deliver better than existing ones on certain important parameters such as cyclic stability, voltage hysteresis, operating potential, current stability and capacity . The key anode materials researched thus far fall into three broad categories of conversion, alloying and intercalation types and are limited in one way or another to stake the claim of perfection in terms of desirable performance parameters . Silicon is the most notable of the anode materials that is researched with great interest.…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3][4] The key anode materials researchedt hus far fallinto three broad categories of conversion, alloyinga nd intercalation types and are limited in one way or another to stake the claim of perfection in terms of desirable performance parameters. [5][6][7][8][9] Silicon is the most notable of the anode materials that is researched with great interest. Although it promises the highest achievable capacity,i tf alls short in terms of cyclinga nd current stabilityb ecause of very high volume expansion andr elated pulverisation.…”

Section: Introductionmentioning

confidence: 99%

Fe₃SnC@CNF: A 3 D Antiperovskite Intermetallic Carbide System as a New Robust High‐Capacity Lithium‐Ion Battery Anode

et al. 2019

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A 3 D intermetallic anti‐perovskite carbide, Fe3SnC, is reported as a Li‐ion battery anode. Single‐phase Fe3SnC showed a reversible Li‐ion capacity of 426 mAh g−1 that increased significantly (600 mAh g−1) upon its in situ synthesis by electrospinning and pyrolysis to render a conducting carbon nanofibre (CNF) based composite. Importantly, the Fe3SnC@CNF composite showed excellent stability in up to 1000 cycles with a remarkable 96 % retention of capacity. The rate performance was equally impressive with a high capacity of 500 mAh g−1 delivered at a high current density of 2 A g−1. An estimation of Li ion diffusion from the electrochemical impedance data showed a major enhancement of the rate by a factor of 2 in the case of Fe3SnC@CNF compared to the single‐phase Fe3SnC sample. Post‐cyclic characterisation revealed that the unit cell was retained despite a volume expansion upon the inclusion of four Li atoms per unit cell, as calculated from the capacity value. The cyclic voltammogram shows four distinctive peaks that could be identified as the sequential incorporation of up to four Li atoms. First‐principles DFT calculations were performed to elucidate the favourable sites for the inclusion of 1–4 Li atoms inside the Fe3SnC unit cell along with the associated strain.

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Recent Advances and Perspectives of Carbon-Based Nanostructures as Anode Materials for Li-ion Batteries

Cited by 112 publications

References 239 publications

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

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

Lithium Metal Battery Pouch Cell Assembly and Prototype Demonstration Using Tailored Polypropylene Separator

Fe₃SnC@CNF: A 3 D Antiperovskite Intermetallic Carbide System as a New Robust High‐Capacity Lithium‐Ion Battery Anode

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Recent Advances and Perspectives of Carbon-Based Nanostructures as Anode Materials for Li-ion Batteries

Cited by 112 publications

References 239 publications

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

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

Lithium Metal Battery Pouch Cell Assembly and Prototype Demonstration Using Tailored Polypropylene Separator

Fe3SnC@CNF: A 3 D Antiperovskite Intermetallic Carbide System as a New Robust High‐Capacity Lithium‐Ion Battery Anode

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Product

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Fe₃SnC@CNF: A 3 D Antiperovskite Intermetallic Carbide System as a New Robust High‐Capacity Lithium‐Ion Battery Anode