Directional Freezing Assisted 3D Printing to Solve a Flexible Battery Dilemma: Ultrahigh Energy/Power Density and Uncompromised Mechanical Compliance

Li, Xiaolong; Ling, Shangwen; Zeng, Li; He, Hanna; Liu, Xingang; Zhang, Chuhong

doi:10.1002/aenm.202200233

Cited by 40 publications

(38 citation statements)

References 50 publications

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“…Herein, we develop an innovative 3D periodic MXene/Zn-P aerogel anode with high shape fidelity and excellent directional alignment via a novel 3D cold-trap environment printing (3DCEP) technology. Different from conventional 3D printing direct ink writing (DIW) and 3D cold plate printing (3DCPP) technologies, [17][18][19] the 3DCEP technology is implemented in a wholly cold environment, and the instantaneous freezing of inks eliminates the influence of temperature gradient on the flow of inks. In addition, the MXene nanosheets are ordered alignment spontaneously owing to the laminar flow effect of inks with low Reynolds number in the microchannel.…”

Section: Introductionmentioning

confidence: 99%

3D Cold‐Trap Environment Printing for Long‐Cycle Aqueous Zn‐Ion Batteries

Zhang

et al. 2022

Advanced Materials

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excellent rate performance, and fast reaction kinetics. [1][2][3][4] However, the inadequate cycling performance of Zn metal anode (mainly including Zn foil) originates from the growth of Zn dendrites and other side reactions have impeded its further development and extensive commercialization. [5] To date, many efforts have been devoted to regulate the surface structure and characteristics of Zn foil to induce Zn nucleation and growth on the surface of Zn foil via various strategies such as surface coating of Zn foil and modification of electrolyte, [6][7][8] which have greatly enhanced the electrochemical performances of Zn foil. The inherent defects of planar Zn foil are always affecting its practical application, and there are three major factors involved: i) the 2D plane structure of Zn foil can cause spontaneous dendrite formation along the vertical direction on the surface of the Zn foil, which can easily penetrate the separator and cause short circuit of battery; ii) severe pulverization of Zn foil can occur during the charge/ discharge cycles at high current density, resulting in electric contact failure; and iii) the redundant thickness of Zn foil results in its poor utilization in application. [9,10] Compared with Zn foil, Zn powder (Zn-P) is a valuable substitute for Zn foil owing to its low cost and easily available. More importantly, the content of Zn-P can be accurately controlled, Zn powder (Zn-P)-based anodes are always regarded as ideal anode candidates for zinc ion batteries owing to their low cost and ease of processing. However, the intrinsic negative properties of Zn-P-based anodes such as easy corrosion and uncontrolled dendrite growth have limited their further applications. Herein, a novel 3D cold-trap environment printing (3DCEP) technology is proposed to achieve the MXene and Zn-P (3DCEP-MXene/Zn-P) anode with highly ordered arrangement. Benefitting from the unique inhibition mechanism of high lattice matching and physical confinement effects within the 3DCEP-MXene/Zn-P anode, it can effectively homogenize the Zn 2+ flux and alleviate the Zn deposition rate of the 3DCEP-MXene/Zn-P anode during Zn plating-stripping. Consequently, the 3DCEP-MXene/Zn-P anode exhibits a superior cycling lifespan of 1400 h with high coulombic efficiency of ≈9.2% in symmetric batteries. More encouragingly, paired with MXene and Co doped MnHCF cathode via 3D cold-trap environment printing (3 DCEP-MXene/Co-MnHCF), the 3DCEP-MXene/Zn-P//3DCEP-MXene/Co-MnHCF full battery delivers high cyclic durability with the capacity retention of 95.7% after 1600 cycles. This study brings an inspired universal pathway to rapidly fabricate a reversible Zn anode with highly ordered arrangement in a cold environment for micro-zinc storage systems.

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Section: Introductionmentioning

confidence: 99%

3D Cold‐Trap Environment Printing for Long‐Cycle Aqueous Zn‐Ion Batteries

Zhang

et al. 2022

Advanced Materials

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“…The electrodes were wet with an excess of 1 m LiPF 6 in EC:DMC 50/50 v/v and a polypropylene separator (Celgard) was used between electrodes. Full cells and LTO:Li half-cells were tested between 1-2.5 V, while LFP:Li half-cells were tested between 2.5 -3.8/4.0 V. [32,46,47] Within these voltage windows the carbon portion of the HIPI-composite contributed limited to no capacity, as demonstrated by a HIPI-architected pure carbon electrode cycled as a half-cell (Carbon:Li) shown in Figure S22 (Supporting Information). Currents below 1 mA were tested on an MTI BST8-WA battery tester, and currents above 1 mA were tested on either a Gamry Interface 1010 potentiostat/galvanostat or an MTI BST8-A6V0 battery tester.…”

Section: Methodsmentioning

confidence: 99%

Architected Low‐Tortuosity Electrodes with Tunable Porosity from Nonequilibrium Soft‐Matter Processing

2022

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Mass transport is performance‐defining across energy storage devices, often causing limitations at high current rates. To optimize and balance the device‐scale energy and power density for a given energy storage demand, tailored electrode architectures with precisely controllable phase dimensions are needed in combination with low‐tortuosity channels that maximize the geometric component of diffusion and species flux. A material‐agnostic nonequilibrium soft‐matter process is reported to fabricate free‐standing inorganic composite electrodes with adjustable thicknesses of 100s of µm, featuring straight and accessible channels ranging in diameter from 5–30 µm, coupled with tunable material‐to‐pore ratios. Such architected anode and cathode electrodes exhibit electrochemical and architectural stability over extended cycling in a full‐cell battery. Further, mass‐transport constraints appear at high current densities, and the lithiation step is identified as rate‐performance limiting, a result of insufficient lithium‐ion supply and concentration polarization. The results demonstrate the need for and feasibility of tailored electrode architectures where dimensional ratios between low‐tortuosity channels, the charge‐storing matrix, and electrode thickness are tunable to meet coupled power and energy‐storage requirements.

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“…As schematically illustrated in Figure 2A, the types of thin film are the most commonly available architectures for both electrode and electrolyte modules, which can be manufactured into custom-designed dimension and shapes by multiple diverse 3D printing techniques (Maurel et al, 2021;Li et al, 2022). These planar modules can be easily applied for 2D sandwichedstructural batteries and microbatteries.…”

Section: Construction Strategies Of Modulesmentioning

confidence: 99%

Additive manufacturing for advanced rechargeable lithium batteries: A mini review

Guo

Liu

et al. 2022

Front. Energy Res.

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Additive manufacturing techniques have shown great promise in changing the way batteries can be designed due to their excellent geometry controllability, process flexibility and high sustainability in manufacturing complex-shaped structures, which have been progressively applied in design of high-performance lithium batteries. In this review, the latest advances in 3D printed lithium batteries have been summarized with a focus on the fundamentals of representative additive manufacturing techniques involving the operation mechanisms, manufacturing accuracy, respective advantages and challenges. In addition, the general 3D printing design principles in module architectures, materials selection and battery configurations for developing high performance lithium batteries are also systematically discussed. Finally, pertinent insights into the future perspectives of 3D printed lithium batteries have been emphasized, expecting to enlighten the research directions of practical applications of 3D printed batteries.

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Directional Freezing Assisted 3D Printing to Solve a Flexible Battery Dilemma: Ultrahigh Energy/Power Density and Uncompromised Mechanical Compliance

Cited by 40 publications

References 50 publications

3D Cold‐Trap Environment Printing for Long‐Cycle Aqueous Zn‐Ion Batteries

3D Cold‐Trap Environment Printing for Long‐Cycle Aqueous Zn‐Ion Batteries

Architected Low‐Tortuosity Electrodes with Tunable Porosity from Nonequilibrium Soft‐Matter Processing

Additive manufacturing for advanced rechargeable lithium batteries: A mini review

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