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Journal articles on the topic 'Lithium deposition'

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Author: Grafiati
Published: 28 June 2022

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1

Tuttle, B. A., and R. W. Schwartz. "Solution Deposition of Ferroelectric Thin Films." MRS Bulletin 21, no. 6 (June 1996): 49–54. http://dx.doi.org/10.1557/s088376940004608x.

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Solution deposition has been used by almost every electroceramic research-and-development organization throughout the world to evaluate thin films. Ferrite, high-temperature-superconductor, dielectric, and antireflection coatings are among the electroceramics for which solution deposition has had a significant impact. Lithium niobate, lithium tantalate, potassium niobate, lead scandium tantalate, lead magnesium niobate, and bismuth strontium tantalate are among the ferroelectric thin films processed by solution deposition. However, lead zir-conate titanate (PZT) thin films have received the most intensive study and will be emphasized in this article.Solution deposition facilitates stoichiometric control of complex mixed oxides better than other techniques such as sputter deposition and metalorganic chemical vapor deposition (MOCVD). Solution deposition is a fast, cost-efficient method to survey extensive ranges of film composition. Further it is a process compatible with many semiconductor-fabrication technologies, and it may be the deposition method of choice for applications that do not require conformal depositions and that have device dimensions of 2 μm or greater. Specific applications for which solution deposition is commercially viable include decoupling capacitors, uncooled pyroelectric infrared detectors, piezoelectric micromotors, and chemical microsensors based on surface-acoustic-wave technology. Reviews of some of the more fundamental aspects of solution-deposition processing may be found in the scientific literature.
2

Kühnle, Hannes, Edwin Knobbe, and Egbert Figgemeier. "In Situ Optical and Electrochemical Investigations of Lithium Depositions as a Function of Current Densities." Journal of The Electrochemical Society 169, no. 4 (April 1, 2022): 040528. http://dx.doi.org/10.1149/1945-7111/ac644e.

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The electrodeposition behavior of lithium metal as a function of the current density at room temperature was investigated in a symmetrical face‑to‑face in‑situ optical cell. After a defined initial contact time between electrode and electrolyte, various current densities in the range of 0.05 mA cm−2 to 10 mA cm−2 were tested. Constant current phases, electrochemical impedance spectroscopy measurements and in situ images of the working electrode were recorded and results were compared. Two regimes of lithium deposition with different optical and electrochemical characteristics were identified as a function of current density. The first regime, at low current densities (0.05 mA cm−2–0.5 mA cm−2), showed none to tiny lithium depositions with sporadic large lithium structures at the higher end of this range. The second regime, at high current densities (2 mA cm−2–10 mA cm−2), showed many smaller, deposited lithium structures. The experimental results are discussed in the context of the formation and presence of metal-electrolyte interfaces presumably by chemical reactions between lithium and electrolyte , current density and their interactions with each other. The correlation of fundamental parameters of lithium metal deposition with current density must be taken into account for the development of lithium metal-based energy storage devices.
3

Assegie, Addisu Alemayehu, Cheng-Chu Chung, Meng-Che Tsai, Wei-Nien Su, Chun-Wei Chen, and Bing-Joe Hwang. "Multilayer-graphene-stabilized lithium deposition for anode-Free lithium-metal batteries." Nanoscale 11, no. 6 (2019): 2710–20. http://dx.doi.org/10.1039/c8nr06980h.

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4

Takeuchi, Esther S., and William C. Thiebolt. "Lithium Deposition in Prismatic Lithium Cells during Intermittent Discharge." Journal of The Electrochemical Society 138, no. 9 (September 1, 1991): L44—L45. http://dx.doi.org/10.1149/1.2086072.

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5

Angarita-Gomez, Stefany, and Perla B. Balbuena. "Insights into lithium ion deposition on lithium metal surfaces." Physical Chemistry Chemical Physics 22, no. 37 (2020): 21369–82. http://dx.doi.org/10.1039/d0cp03399e.

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6

Huang, Zhijia, Guangmin Zhou, Wei Lv, Yaqian Deng, Yunbo Zhang, Chen Zhang, Feiyu Kang, and Quan-Hong Yang. "Seeding lithium seeds towards uniform lithium deposition for stable lithium metal anodes." Nano Energy 61 (July 2019): 47–53. http://dx.doi.org/10.1016/j.nanoen.2019.04.036.

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7

Fan, Lei, Houlong L. Zhuang, Lina Gao, Yingying Lu, and Lynden A. Archer. "Regulating Li deposition at artificial solid electrolyte interphases." Journal of Materials Chemistry A 5, no. 7 (2017): 3483–92. http://dx.doi.org/10.1039/c6ta10204b.

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8

Gao, Yue, Daiwei Wang, Yun Kyung Shin, Zhifei Yan, Zhuo Han, Ke Wang, Md Jamil Hossain, et al. "Stable metal anodes enabled by a labile organic molecule bonded to a reduced graphene oxide aerogel." Proceedings of the National Academy of Sciences 117, no. 48 (November 16, 2020): 30135–41. http://dx.doi.org/10.1073/pnas.2001837117.

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Metallic anodes (lithium, sodium, and zinc) are attractive for rechargeable battery technologies but are plagued by an unfavorable metal–electrolyte interface that leads to nonuniform metal deposition and an unstable solid–electrolyte interphase (SEI). Here we report the use of electrochemically labile molecules to regulate the electrochemical interface and guide even lithium deposition and a stable SEI. The molecule, benzenesulfonyl fluoride, was bonded to the surface of a reduced graphene oxide aerogel. During metal deposition, this labile molecule not only generates a metal-coordinating benzenesulfonate anion that guides homogeneous metal deposition but also contributes lithium fluoride to the SEI to improve Li surface passivation. Consequently, high-efficiency lithium deposition with a low nucleation overpotential was achieved at a high current density of 6.0 mA cm−2. A Li|LiCoO2cell had a capacity retention of 85.3% after 400 cycles, and the cell also tolerated low-temperature (−10 °C) operation without additional capacity fading. This strategy was applied to sodium and zinc anodes as well.
9

Yao, Zhujun, Xinhui Xia, Yu Zhong, Yadong Wang, Bowei Zhang, Dong Xie, Xiuli Wang, Jiangping Tu, and Yizhong Huang. "Hybrid vertical graphene/lithium titanate–CNTs arrays for lithium ion storage with extraordinary performance." Journal of Materials Chemistry A 5, no. 19 (2017): 8916–21. http://dx.doi.org/10.1039/c7ta02511d.

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In the present study, we report a synthetic strategy for the direct fabrication of hybrid vertical graphene/lithium titanate–CNTs arrays via atomic layer deposition in combination with chemical vapor deposition.
10

Fang, Chengcheng, Bingyu Lu, Gorakh Pawar, Minghao Zhang, Diyi Cheng, Shuru Chen, Miguel Ceja, et al. "Pressure-tailored lithium deposition and dissolution in lithium metal batteries." Nature Energy 6, no. 10 (October 2021): 987–94. http://dx.doi.org/10.1038/s41560-021-00917-3.

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11

Vanleeuw, D., D. Sapundjiev, G. Sibbens, S. Oberstedt, and P. Salvador Castiñeira. "Physical vapour deposition of metallic lithium." Journal of Radioanalytical and Nuclear Chemistry 299, no. 2 (August 2, 2013): 1113–20. http://dx.doi.org/10.1007/s10967-013-2669-6.

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12

Chang, Wesley. "2021 F. M. Becket Fellowship – Summary Report Measuring Transient Electrochemistry of Lithium Metal Anodes under Varying External Stack Pressures." Electrochemical Society Interface 30, no. 4 (December 1, 2021): 32–33. http://dx.doi.org/10.1149/2.f06214if.

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Lithium metal anodes are challenged by the inherent chemical and electrochemical reactivity of lithium metal, which is further exacerbated by non-uniform high surface area deposition. Recently, lithium difluoro(oxalato)borate (LiDFOB) salt coupled with a fluorinated solvent has been demonstrated to result in densely deposited lithium morphology along with high Coulombic efficiencies due to a stable solidelectrolyte-interphase. Along with other newly discovered electrolyte compositions for stable lithium deposition, these studies typically utilize high stack pressures and elevated temperatures. These developments are promising, and would further benefit from a study that maps out the effects of varying stack pressure and temperature on lithium anode mechanics, chemistry, and electrochemistry.
13

Li, Zhe, Jun Huang, Bor Yann Liaw, Viktor Metzler, and Jianbo Zhang. "A review of lithium deposition in lithium-ion and lithium metal secondary batteries." Journal of Power Sources 254 (May 2014): 168–82. http://dx.doi.org/10.1016/j.jpowsour.2013.12.099.

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14

Shi, Feifei, Allen Pei, David Thomas Boyle, Jin Xie, Xiaoyun Yu, Xiaokun Zhang, and Yi Cui. "Lithium metal stripping beneath the solid electrolyte interphase." Proceedings of the National Academy of Sciences 115, no. 34 (August 6, 2018): 8529–34. http://dx.doi.org/10.1073/pnas.1806878115.

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Lithium stripping is a crucial process coupled with lithium deposition during the cycling of Li metal batteries. Lithium deposition has been widely studied, whereas stripping as a subsurface process has rarely been investigated. Here we reveal the fundamental mechanism of stripping on lithium by visualizing the interface between stripped lithium and the solid electrolyte interphase (SEI). We observed nanovoids formed between lithium and the SEI layer after stripping, which are attributed to the accumulation of lithium metal vacancies. High-rate dissolution of lithium causes vigorous growth and subsequent aggregation of voids, followed by the collapse of the SEI layer, i.e., pitting. We systematically measured the lithium polarization behavior during stripping and find that the lithium cation diffusion through the SEI layer is the rate-determining step. Nonuniform sites on typical lithium surfaces, such as grain boundaries and slip lines, greatly accelerated the local dissolution of lithium. The deeper understanding of this buried interface stripping process provides beneficial clues for future lithium anode and electrolyte design.
15

Xu, Fan, Nancy J. Dudney, Gabriel M. Veith, Yoongu Kim, Can Erdonmez, Wei Lai, and Yet-Ming Chiang. "Properties of lithium phosphorus oxynitride (Lipon) for 3D solid-state lithium batteries." Journal of Materials Research 25, no. 8 (August 2010): 1507–15. http://dx.doi.org/10.1557/jmr.2010.0193.

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The thin film electrolyte known as Lipon (lithium phosphorous oxynitride) has proven successful for planar thin film battery applications. Here, the sputter deposition of the amorphous LiPON electrolyte onto more complex 3D structures is examined. The 3D structures include off-axis alignment of planar substrates and also 10–100 μm arrays of pores, columns, and grooves. For magnetron sputtering in N2 gas at 2.6 Pa, the Lipon film deposition is not restricted to be line-of-sight to the target, but forms conformal and dense films over the 3D and off-axis substrates. The deposition rate decreases for areas and grooves that are less accessible by the sputtered flux. The composition varies, but remains within the range that gives sufficient Li+ ionic conductivity, 2 ± 1 μS/cm.
16

Zhuang, Jingchun, Xianshu Wang, Mengqing Xu, Zhi Chen, Mingzhu Liu, Xueqiong Cheng, and Weishan Li. "A self-healing interface on lithium metal with lithium difluoro (bisoxalato) phosphate for enhanced lithium electrochemistry." Journal of Materials Chemistry A 7, no. 45 (2019): 26002–10. http://dx.doi.org/10.1039/c9ta09539j.

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17

Gan, He, Jing Wu, Hui Chen, Run Li, and Hongbo Liu. "Guiding lithium deposition in tent-like nitrogen-doped porous carbon microcavities for stable lithium metal anodes." Journal of Materials Chemistry A 8, no. 27 (2020): 13480–89. http://dx.doi.org/10.1039/d0ta04784h.

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18

Arise, Ichiro, Yuto Miyahara, Kohei Miyazaki, and Takeshi Abe. "Dendrite Growth of Lithium through Separator Using In Situ Measurement Technique." Journal of The Electrochemical Society 169, no. 2 (February 1, 2022): 020546. http://dx.doi.org/10.1149/1945-7111/ac52c4.

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In situ techniques as a clue to clarify the mechanism of lithium dendrite growth through the separator were applied. The aim of this work was to clarify the dendrite growth mechanism through the separator and to investigate and discuss the relationship between lithium intercalation into graphite and lithium deposition on the graphite surface, applying in situ and ex situ optical microscope and in situ electrochemical impedance spectroscopy. It was visually characterized the lithium dendrite growth by the ionic transfer through the separator and obtained the fundamental knowledge by in situ optical microscope. In the case of lithium deposition through the aramid coated separator (ACS), the dendrites were observed to be granular over a wide area. On the other hand, in the case of lithium deposition through the ceramic coated separator (CCS), dendrites were fibrous over a wide area by ex situ optical microscope. The superiority of ACS is related to the flatness and uniformity of the pores due to aramid resin. This result was supported by an analysis applying in situ electrochemical impedance spectroscopy.
19

Bucur, Claudiu B., Adrian Lita, Naoki Osada, and John Muldoon. "A soft, multilayered lithium–electrolyte interface." Energy & Environmental Science 9, no. 1 (2016): 112–16. http://dx.doi.org/10.1039/c5ee03056k.

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It is desirable that a thin film lithium–electrolyte interface is flexible and self-healing to accommodate the large volume expansion during lithium deposition without rupturing and impede electrolyte decomposition.
20

Østreng, Erik, Ponniah Vajeeston, Ola Nilsen, and Helmer Fjellvåg. "Atomic layer deposition of lithium nitride and carbonate using lithium silylamide." RSC Advances 2, no. 15 (2012): 6315. http://dx.doi.org/10.1039/c2ra20731a.

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21

Kim, Yun-Jung, Hyun S. Jin, Dong-Hyun Lee, Jaeho Choi, Wonhee Jo, Hyungjun Noh, Jinhong Lee, et al. "Guided Lithium Deposition by Surface Micro-Patterning of Lithium-Metal Electrodes." ChemElectroChem 5, no. 21 (August 24, 2018): 3169–75. http://dx.doi.org/10.1002/celc.201800694.

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22

Chen, Weilin, Youran Hong, Zehua Zhao, Yuting Zhang, Linhai Pan, Jia Wan, Maria Nazir, Jiangwei Wang, and Haiyong He. "Directing the deposition of lithium metal to the inner concave surface of graphitic carbon tubes to enable lithium-metal batteries." Journal of Materials Chemistry A 9, no. 31 (2021): 16936–42. http://dx.doi.org/10.1039/d1ta04303j.

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23

Li, Dongdong, Yuan Gao, Chuan Xie, and Zijian Zheng. "Au-coated carbon fabric as Janus current collector for dendrite-free flexible lithium metal anode and battery." Applied Physics Reviews 9, no. 1 (March 2022): 011424. http://dx.doi.org/10.1063/5.0083830.

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Composite lithium metal anodes with three-dimensional (3D) conductive fabric present great potential to be used in high-energy-density flexible batteries for next-generation wearable electronics. However, lithium dendrites at the top of the fabric anode increase the risk of separator piercing and, therefore, cause a high possibility of short circuits, especially when undergoing large mechanical deformation. To ensure the safe application of the flexible lithium metal batteries, we herein propose a 3D Janus current collector by a simple modification of the bottom side of carbon fabric (CF) with a lithiophilic Au layer to construct highly flexible, stable, and safe Li metal anodes. The Janus Au layer can guide an orientated deposition of Li to the bottom of the CF. The lithium dendrite problem can be largely alleviated due to the lithium-free interface between the anode and separator, and meanwhile, the porous upper skeleton of the CF also provides large space to buffer the volume expansion of lithium metal. The resulting composite lithium metal anode exhibits a significant improvement in the life cycle (∼two fold) compared to the traditional top deposition of lithium metal. More importantly, assembled full batteries using the Janus anode structure exhibit high stability and safety during severe mechanical deformation, indicating the opportunity of the orientated deposition strategy to be used in future flexible and wearable electronics.
24

Kim, Kwiyong, Yifu Chen, Jong-In Han, Hyung Chul Yoon, and Wenzhen Li. "Lithium-mediated ammonia synthesis from water and nitrogen: a membrane-free approach enabled by an immiscible aqueous/organic hybrid electrolyte system." Green Chemistry 21, no. 14 (2019): 3839–45. http://dx.doi.org/10.1039/c9gc01338e.

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25

Ono, Satomi, and Shin-ichi Hirano. "Processing of highly oriented lithium tantalate films by chemical solution deposition." Journal of Materials Research 17, no. 10 (October 2002): 2532–39. http://dx.doi.org/10.1557/jmr.2002.0368.

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The synthesis of lithium tantalate films by a chemical solution deposition method was studied. A precursor solution was prepared by dissolving lithium ethoxide and tantalum pentaethoxide in ethanol. The addition of formic acid to this precursor solution was very effective in the preparation of homogeneous and transparent precursor films on substrates by spin coating. Lithium tantalate films crystallized on sapphire (001) substrates with a highly preferred orientation along the c axis with heat-treating at temperatures above 450 °C. The refractive index of the film prepared at 550 °C was 2.049, which is close to the value for single crystals of lithium tantalate (2.176).
26

Sun, Changzhi, Tian Wu, Jianing Wang, Wenwen Li, Jun Jin, Jianhua Yang, and Zhaoyin Wen. "Favorable lithium deposition behaviors on flexible carbon microtube skeleton enable a high-performance lithium metal anode." Journal of Materials Chemistry A 6, no. 39 (2018): 19159–66. http://dx.doi.org/10.1039/c8ta06828c.

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27

Nisula, Mikko, Yohei Shindo, Hideyuki Koga, and Maarit Karppinen. "Atomic Layer Deposition of Lithium Phosphorus Oxynitride." Chemistry of Materials 27, no. 20 (October 7, 2015): 6987–93. http://dx.doi.org/10.1021/acs.chemmater.5b02199.

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28

Ma, Lu, Ramsay B. Nuwayhid, Tianpin Wu, Yu Lei, Khalil Amine, and Jun Lu. "Atomic Layer Deposition for Lithium-Based Batteries." Advanced Materials Interfaces 3, no. 21 (September 5, 2016): 1600564. http://dx.doi.org/10.1002/admi.201600564.

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29

Sergeev, V. Yu, E. S. Marmar, J. A. Snipes, J. L. Terry, H. Park, D. K. Mansfield, M. Bell, and D. McCune. "Lithium pellet deposition and penetration in TFTR." Review of Scientific Instruments 63, no. 10 (October 1992): 4984–86. http://dx.doi.org/10.1063/1.1143521.

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30

Wild, Joseph, Peiyu Wang, Tianwei Jin, and Yuan Yang. "Modeling Isotope Separation in Electrochemical Lithium Deposition." Journal of The Electrochemical Society 169, no. 3 (March 1, 2022): 032504. http://dx.doi.org/10.1149/1945-7111/ac5854.

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Naturally occurring Li consists of two stable isotopes, 6Li with an abundance of about 7.5%, and 7Li making up the remainder with 92.5%. The development of a 6Li enrichment technique, in terms of technical reliability and environmental safety to reach 6Li future requirements, represents a key step in the roadmap for nuclear fusion energy supply worldwide. This paper uses finite element analysis-based models to simulate electrochemical Li isotope separation, which is an attractive method in terms of simplicity, safety, and scalability. In the model, we quantitatively analyze how different electrochemical factors including thermodynamics, charge-transfer kinetics, and diffusivities affect the separation process (separation factor), together with cell parameters, such as cell length and current density. The maximum separation factor of 1.128 could be obtained with the cell under the optimal thermodynamic, kinetic, and diffusive conditions, which is among the highest separation factors ever reported. These results will assist in designing the actual isotope separation setup with large separation factor and appropriate timing for sample collection.
31

Assegie, Addisu Alemayehu, Ju-Hsiang Cheng, Li-Ming Kuo, Wei-Nien Su, and Bing-Joe Hwang. "Polyethylene oxide film coating enhances lithium cycling efficiency of an anode-free lithium-metal battery." Nanoscale 10, no. 13 (2018): 6125–38. http://dx.doi.org/10.1039/c7nr09058g.

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32

Li, Wenjun, Hao Zheng, Geng Chu, Fei Luo, Jieyun Zheng, Dongdong Xiao, Xing Li, et al. "Effect of electrochemical dissolution and deposition order on lithium dendrite formation: a top view investigation." Faraday Discuss. 176 (2014): 109–24. http://dx.doi.org/10.1039/c4fd00124a.

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Rechargeable metallic lithium batteries are the ultimate solution to electrochemical storage due to their high theoretical energy densities. One of the key technological challenges is to control the morphology of metallic lithium electrode during electrochemical dissolution and deposition. Here we have investigated the morphology change of metallic lithium electrode after charging and discharging in nonaqueous batteries by ex situ SEM techniques from a top view. Formation of the hole structure after lithium dissolution and the filling of dendrite-like lithium into the holes has been observed for the first time. In addition, an in situ SEM investigation using an all-solid Li/Li2O/super aligned carbon nanotube set-up indicates that lithium ions could diffuse across through the surface oxide layer and grow lithium dendrites after applying an external electric field. The growth of lithium dendrites can be guided by electron flow when the formed lithium dendrite touches the carbon nanotube.
33

Cheng, Xin-Bing, Ting-Zheng Hou, Rui Zhang, Hong-Jie Peng, Chen-Zi Zhao, Jia-Qi Huang, and Qiang Zhang. "Dendrite-Free Lithium Deposition Induced by Uniformly Distributed Lithium Ions for Efficient Lithium Metal Batteries." Advanced Materials 28, no. 15 (February 22, 2016): 2888–95. http://dx.doi.org/10.1002/adma.201506124.

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34

Ma, Mingming, Chaoqi Dai, Kailin Luo, Shun Li, Jiahe Chen, Zhendong Li, Xiaodi Ren, et al. "Magnetohydrodynamic Interface‐Rearranged Lithium Ions Distribution for Uniform Lithium Deposition and Stable Lithium Metal Anode." ChemPhysChem 22, no. 10 (April 28, 2021): 1027–33. http://dx.doi.org/10.1002/cphc.202000897.

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35

Zhao, Yun, Bingbing Chen, Shuhui Xia, Jianyong Yu, Jianhua Yan, and Bin Ding. "Selective nucleation and targeted deposition effect of lithium in a lithium-metal host anode." Journal of Materials Chemistry A 9, no. 9 (2021): 5381–89. http://dx.doi.org/10.1039/d0ta11643b.

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36

Bieker, Georg, Martin Winter, and Peter Bieker. "Electrochemical in situ investigations of SEI and dendrite formation on the lithium metal anode." Physical Chemistry Chemical Physics 17, no. 14 (2015): 8670–79. http://dx.doi.org/10.1039/c4cp05865h.

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37

Lürenbaum, Constantin, Britta Vortmann-Westhoven, Marco Evertz, Martin Winter, and Sascha Nowak. "Quantitative spatially resolved post-mortem analysis of lithium distribution and transition metal depositions on cycled electrodes via a laser ablation-inductively coupled plasma-optical emission spectrometry method." RSC Advances 10, no. 12 (2020): 7083–91. http://dx.doi.org/10.1039/c9ra09464d.

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38

Li, Zeheng, Nan Xu, Ying Sha, Jiapeng Ji, Tiefeng Liu, Lijing Yan, Yi He, et al. "Chitosan oligosaccharide derived polar host for lithium deposition in lithium metal batteries." Sustainable Materials and Technologies 24 (July 2020): e00158. http://dx.doi.org/10.1016/j.susmat.2020.e00158.

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39

Xiang, Jingwei, Ying Zhao, Lixia Yuan, Chaoji Chen, Yue Shen, Fei Hu, Zhangxiang Hao, Jing Liu, Baixiang Xu, and Yunhui Huang. "A strategy of selective and dendrite-free lithium deposition for lithium batteries." Nano Energy 42 (December 2017): 262–68. http://dx.doi.org/10.1016/j.nanoen.2017.10.065.

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40

Dong, Jing, Hongliu Dai, Chao Wang, and Chao Lai. "Uniform lithium deposition driven by vertical magnetic field for stable lithium anodes." Solid State Ionics 341 (November 2019): 115033. http://dx.doi.org/10.1016/j.ssi.2019.115033.

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41

Lee, Yong-Gun, Saebom Ryu, Toshinori Sugimoto, Taehwan Yu, Won-seok Chang, Yooseong Yang, Changhoon Jung, et al. "Dendrite-Free Lithium Deposition for Lithium Metal Anodes with Interconnected Microsphere Protection." Chemistry of Materials 29, no. 14 (July 17, 2017): 5906–14. http://dx.doi.org/10.1021/acs.chemmater.7b01304.

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42

Sachdev, H., R. Haubner, and B. Lux. "Lithium addition during CVD diamond deposition using lithium tert.-butanolat as precursor." Diamond and Related Materials 6, no. 2-4 (March 1997): 494–500. http://dx.doi.org/10.1016/s0925-9635(96)00628-0.

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43

Yang, Chunpeng, Yonggang Yao, Shuaiming He, Hua Xie, Emily Hitz, and Liangbing Hu. "Ultrafine Silver Nanoparticles for Seeded Lithium Deposition toward Stable Lithium Metal Anode." Advanced Materials 29, no. 38 (August 18, 2017): 1702714. http://dx.doi.org/10.1002/adma.201702714.

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44

Amanchukwu, Chibueze V., Xian Kong, Jian Qin, Yi Cui, and Zhenan Bao. "Nonpolar Alkanes Modify Lithium‐Ion Solvation for Improved Lithium Deposition and Stripping." Advanced Energy Materials 9, no. 41 (September 23, 2019): 1902116. http://dx.doi.org/10.1002/aenm.201902116.

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45

Angarita Gomez, Maria, and Perla B. Balbuena. "Slow Growth Approach for Lithium Ion Deposition on Lithium Metal Anode Surfaces." ECS Meeting Abstracts MA2020-02, no. 4 (November 23, 2020): 794. http://dx.doi.org/10.1149/ma2020-024794mtgabs.

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46

Jiang, Zhanguo, Tiefeng Liu, Lijing Yan, Jie Liu, Feifei Dong, Min Ling, Chengdu Liang, and Zhan Lin. "Metal-organic framework nanosheets-guided uniform lithium deposition for metallic lithium batteries." Energy Storage Materials 11 (March 2018): 267–73. http://dx.doi.org/10.1016/j.ensm.2017.11.003.

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47

Zhang, Jian, Musen Zhou, Jiayan Shi, Yifan Zhao, Xiaoyu Wen, Chi-Cheung Su, Jianzhong Wu, and Juchen Guo. "Regulating lithium deposition via electropolymerization of acrylonitrile in rechargeable lithium metal batteries." Nano Energy 88 (October 2021): 106298. http://dx.doi.org/10.1016/j.nanoen.2021.106298.

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48

Chen, Qiulin, Hao Li, Melissa L. Meyerson, Rodrigo Rodriguez, Kenta Kawashima, Jason A. Weeks, Hohyun Sun, et al. "Li–Zn Overlayer to Facilitate Uniform Lithium Deposition for Lithium Metal Batteries." ACS Applied Materials & Interfaces 13, no. 8 (February 16, 2021): 9985–93. http://dx.doi.org/10.1021/acsami.0c21195.

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49

Sun, Changzhi, Yanpei Li, Jun Jin, Jianhua Yang, and Zhaoyin Wen. "ZnO nanoarray-modified nickel foam as a lithiophilic skeleton to regulate lithium deposition for lithium-metal batteries." Journal of Materials Chemistry A 7, no. 13 (2019): 7752–59. http://dx.doi.org/10.1039/c9ta00862d.

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50

Bocchetta, Patrizia, Domenico Frattini, Miriana Tagliente, and Filippo Selleri. "Electrochemical Deposition of Polypyrrole Nanostructures for Energy Applications: A Review." Current Nanoscience 16, no. 4 (August 20, 2020): 462–77. http://dx.doi.org/10.2174/1573413715666190717113600.

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Abstract:
By collecting and analyzing relevant literature results, we demonstrate that the nanostructuring of polypyrrole (PPy) electrodes is a crucial strategy to achieve high performance and stability in energy devices such as fuel cells, lithium batteries and supercapacitors. In this critic and comprehensive review, we focus the attention on the electrochemical methods for deposition of PPy, nanostructures and potential applications, by analyzing the effect of different physico-chemical parameters, electro-oxidative conditions including template-based or template-free depositions and cathodic polymerization. Diverse interfaces and morphologies of polymer nanodeposits are also discussed.
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