ZnO–Plasma Polymer Fluorocarbon Thin Films for Stable Battery Anodes and High-Output Triboelectric Nanogenerators

Song, Aeran; Kim, Jong Heon; Yong, Hyungseok; Rho, Yecheol; Song, Dong-Sup; Cho, Eunmi; Kim, Min Jung; Chung, Kwun‐Bum; Kim, Hyun Suk; Lee, Sang‐Jin

doi:10.1021/acsanm.2c02892

Cited by 3 publications

(4 citation statements)

References 61 publications

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“…Ring-shaped light scattering patterns were observed depending on the orientation of the scatterers, suggesting that individual SiO x species are well scattered at regular spacing without formation of agglomerates in the thin-film. [33][34][35] In-plane scattering profiles were also observed from the inset image at the Yoneda wing position. The scattering angles are reported as the scattering vector q, which incorporates the wavelength of the Xray source 𝜆.…”

Section: Resultsmentioning

confidence: 99%

“…The TF-SiO x 60/PPFC developed in this study is one of the best of all papers reported for using Si-based anodes in terms of cycle life and capacity retention. The fabrication method using these mixed targets had the advantage of depositing various materials (Cu, [33] Ag, [34] and ZnO [35] ), suggesting that high-quality thinfilms for TF-LIBs can be deposited using materials other than SiO x . Figure 5d schematically shows the operating mechanism for the proposed TF-SiO x 60/PPFC TF-SiO x 100 thin-films based on the above results and discussions.…”

Section: Resultsmentioning

confidence: 99%

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Analogous Design of a Microlayered Silicon Oxide‐Based Electrode to the General Electrode Structure for Thin‐Film Lithium‐Ion Batteries

Kim,

Song,

Park

et al. 2024

Advanced Materials

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Development of miniaturized thin‐film lithium‐ion batteries (TF‐LIBs) using vacuum deposition techniques are crucial for low‐scale applications, but addressing low energy density remains a challenge. In this work, we designed structures analogous to SiOx‐based thin‐film electrodes with close resemblance to traditional LIB slurry formulations including active material, conductive agent, and binder. The thin‐film was produced using mid‐frequency (MF) sputtering with a single hybrid target consisting of SiOx nanoparticles, carbon nanotubes, and polytetrafluoroethylene (PTFE). The thin‐film SiOx/PPFC involved a combination of SiOx and conductive carbon within the plasma‐polymerized fluorocarbon (PPFC) matrix. This resulted in enhanced electronic conductivity and superior elasticity and hardness in comparison to a conventional pure SiOx‐based thin‐film. The electrochemical performance of the half‐cell consisting of thin‐film SiOx/PPFC demonstrated remarkable cycling stability, with a capacity retention of 74.8% up to the 1000th cycle at 0.5 C. In addition, a full cell using the LiNi0.6Co0.2Mn0.2O2 thin‐film as the cathode material exhibited an exceptional initial capacity of ∼120 mAh g–1 at 0.1 C and cycle performance, marked by a capacity retention of 90.8% from the first cycle to the 500th cycle at a 1 C rate. This work will be a steppingstone for the AM/CB/B composite electrodes in TF‐LIBs.This article is protected by copyright. All rights reserved

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Analogous Design of a Microlayered Silicon Oxide‐Based Electrode to the General Electrode Structure for Thin‐Film Lithium‐Ion Batteries

Kim,

Song,

Park

et al. 2024

Advanced Materials

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“…The lithium storage capacity of all thin films was assessed using galvanostatic charge-discharge profiles within a voltage range of 0-2 V Li versus Li/Li + at a current rate of 0.05C (the theoretical capacity at 1C is 987 mAh g À1 , and the theoretical mass density is 5.61 g cm À3 ). [35] Figure 4a-d presents the initial five charge-discharge curves for both the ZnO and ZnO/PTFE thin films. Notably, at the slow current rate of 0.05C, the ZnO and ZnO/PTFE (5,10,15) thin films demonstrated high initial discharge capacities of 2741, 2654, 2577, and 1946 mAh g À1 , corresponding to volumetric capacities of 15 079, 14 867, 14 434, and 10 786 mAh cm À3 and areal capacities of 0.18, 0.178, 0.173, and 0.129 mAh cm À2 , respectively.…”

Section: Electrochemical Evaluation Of Zno and Zno/ptfe Thin-film Anodesmentioning

confidence: 99%

Confluence of ZnO and PTFE Binder for Enhancing Performance of Thin‐Film Lithium‐Ion Batteries

Behera,

Ippili,

Jella

et al. 2024

Energy & Environ Materials

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Developing anode materials with high specific capacity and cycling stability is vital for improving thin‐film lithium‐ion batteries. Thin‐film zinc oxide (ZnO) holds promise due to its high specific capacity, but it suffers from volume changes and structural stress during cycling, leading to poor battery performance. In this research, we ingeniously combined polytetrafluoroethylene (PTFE) with ZnO using a radio frequency (RF) magnetron co‐sputtering method, ensuring a strong bond in the thin‐film composite electrode. PTFE effectively reduced stress on the active material and mitigated volume change effects during Li+ ion intercalation and deintercalation. The composite thin films are thoroughly characterized using advanced techniques such as X‐ray diffraction, scanning electron microscopy, and X‐ray photoelectron spectroscopy for investigating correlations between material properties and electrochemical behaviors. Notably, the ZnO/PTFE thin‐film electrode demonstrated an impressive specific capacity of 1305 mAh g−1 (=7116 mAh cm−3) at a 0.5C rate and a remarkable capacity retention of 82% from the 1st to the 100th cycle, surpassing the bare ZnO thin film (50%). This study provides valuable insights into using binders to stabilize active materials in thin‐film batteries, enhancing battery performance.

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“…This aspect is diversified to further enhance performance. Consequently, ZnO metal oxide performs with a high specific capacity of approximately 978 mAh•g −1 , exceptionally well as a supercapacitor electrode material [17][18][19]. In this context, Zhang et al conducted the synthesis of ZnO with nano-rod geometry on a silicon wafer and found a specific capacitance (Cs) of 43 mF•cm −2 at a current density of 1 mA•cm −2 [20].…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Zinc Oxide Nanorods from Zinc Borate Precursor and Characterization of Supercapacitor Properties

Lefdhil,

Polat,

Zengin

2023

Nanomaterials

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The synthesis of zinc oxide (ZnO) was accomplished from zinc borate (Zn3B2O6) minerals to be used as electrodes in supercapacitor applications. The concentrations of obtained zinc (Zn) metal after treatment with hydrochloric acid (HCl) were determined by atomic absorption spectroscopy (AAS). Direct synthesis of ZnO on a nickel (Ni) foam surface was conducted by employing the hydrothermal technique using a solution with the highest Zn content. The results showed the successful synthesis of ZnO nanorods on the surface of Ni foam with an average wall size of approximately 358 nm. Cyclic voltammetry (CV) and galvanostatic charge–discharge (GCD) measurements revealed that the synthesized electrode exhibited battery-type charge storage characteristics, reaching a maximum specific capacitance of approximately 867 mF·cm−² at a current density of 2 mA·cm−². Additionally, the energy and power densities of the electrode at a current density of 2 mA·cm−² were calculated as 19.3 mWh·cm−² and 200 mW·cm−², respectively. These results exhibited promising performance of the single-component electrode, outperforming the existing counterparts reported in the literature.

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ZnO–Plasma Polymer Fluorocarbon Thin Films for Stable Battery Anodes and High-Output Triboelectric Nanogenerators

Cited by 3 publications

References 61 publications

Analogous Design of a Microlayered Silicon Oxide‐Based Electrode to the General Electrode Structure for Thin‐Film Lithium‐Ion Batteries

Analogous Design of a Microlayered Silicon Oxide‐Based Electrode to the General Electrode Structure for Thin‐Film Lithium‐Ion Batteries

Confluence of ZnO and PTFE Binder for Enhancing Performance of Thin‐Film Lithium‐Ion Batteries

Synthesis of Zinc Oxide Nanorods from Zinc Borate Precursor and Characterization of Supercapacitor Properties

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