Analyses of Thick Lithium Coatings Deposited by Sputter‐Evaporation and Exposed to Air

Rigaux, C.; Lafort, A.; Bodart, F.; Jongen, Y.; Cambriani, Andrea; Lucas, Stéphane

doi:10.1002/ppap.200930807

Cited by 4 publications

(4 citation statements)

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“…For example, [ 121,122 ] lithium layers of 10–40 µm thickness were deposited onto glass and SiO 2 substrates to investigate, by resonant nuclear reaction analysis, the Li diffusion into the substrates ( Figure 6 , left) and the lithium stability in air after being covered by a sputter‐deposited thin‐film of stainless‐steel (Figure 6, right). [ 146,147 ]…”

Section: Production Of Lithium Metal Anodesmentioning

confidence: 99%

“…For example, [121,122] lithium layers of 10-40 µm thickness were deposited onto glass and SiO 2 substrates to investigate, by resonant nuclear reaction analysis, the Li diffusion into the substrates (Figure 6, left) and the lithium stability in air after being covered by a sputter-deposited thin-film of stainlesssteel (Figure 6, right). [146,147] Actually, lithium sputter targets and sputtering are very well known. However, to prove the viability of sputtering as a valuable tool for LMAs production, there is the need of a great fundamental improvement, particularly in the fabrication methods, configuration, and handling of Li sputter targets.…”

Section: Sputter Depositionmentioning

confidence: 99%

“…Finally, thermal evaporation has been demonstrated to be the most appropriate PVD technique for obtaining thin films of metallic lithium, and it can hold a relevant position for the future of LMBs. [147][148][149][150][151][152][153] LMAs produced by PVD in general, including evaporation, are particularly good in terms of homogeneity and conformality of the surface, with defect-free surfaces being achievable. Moreover, PVD offers really good control of the thickness for lithium layers that could be in the range from nanometers to tens of micrometers, thus, being possible to overcome the current limitation on thickness for the conventional method.…”

Section: Thermal Evaporationmentioning

confidence: 99%

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Current Status and Future Perspective on Lithium Metal Anode Production Methods

Acebedo

Morant‐Miñana

Gonzalo

et al. 2023

Advanced Energy Materials

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Lithium metal batteries (LMBs) are one of the most promising energy storage technologies that would overcome the limitations of current Li‐ion batteries, based on their low density (0.534 g cm−3), low reduction potential (−3.04 V vs Standard Hydrogen Electrode) as well as their high theoretical capacities (3860 mAh g−1 and 2061 mAh cm−3). The overall cell mass and volume would be reduced while both gravimetric and volumetric energy densities would be greatly improved. Their electrochemical performance, however, is hampered by the low efficiency at high current densities and continuous degradation, which are related, among other factors, to the properties of the lithium metal anode (LMA). Hence, the production and processing of LMAs is crucial to obtain the desired properties that would enable LMBs. Here, the conventional method used for the production of LMAs, which is the combination of extraction, electrowinning, extrusion, and rolling processes, is reviewed. Then, the advances in the different alternative methods that can be used to produce and improve the properties of LMAs are described, which are divided into vapor phase, liquid phase, and electrodeposition. Within this last method, the anode‐less concept, for which different approaches to the development of advanced current collectors are illustrated, is included.

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Section: Production Of Lithium Metal Anodesmentioning

confidence: 99%

Section: Sputter Depositionmentioning

confidence: 99%

Section: Thermal Evaporationmentioning

confidence: 99%

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Current Status and Future Perspective on Lithium Metal Anode Production Methods

Acebedo

Morant‐Miñana

Gonzalo

et al. 2023

Advanced Energy Materials

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“…The various possible reactions can be prevented by 'sandwiching' the Li layer between a passivation layer on the substrate side and a protective layer coating the lithium directly after evaporation. The encapsulation by means of a metallic layer to improve the chemical stability has been applied for thick Li coatings deposited by sputter evaporation [3] and for thin 6 Li targets [4]. Protective layers of stainless steel, Ni and Ti could not prevent the formation of Li compounds by the reaction with atmospheric air.…”

Section: Target Encapsulationmentioning

confidence: 99%

Physical vapour deposition of metallic lithium

Vanleeuw

Sapundjiev

Sibbens

et al. 2013

J Radioanal Nucl Chem

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The preparation of thin films of LiF was resumed at the European Commission-Joint Research Centre-Institute for Reference Materials and Measurements (EC-JRC-IRMM) few years ago. Deposits of 6 LiF for cross-section measurements and 7 LiF for neutron production via the Li(p,n) reaction with an areal density up to *600 lg cm -2 are prepared by physical vapour deposition. In order to reach high neutron yields, a larger number of lithium nuclei per unit surface is required. In a proton beam, interaction with fluorine results in high-energetic gamma-rays which can interfere with experiments making use of gamma spectrometry. In this regard, the deposition of metallic lithium by means of physical vapour deposition up to an areal density of 300 lg cm -2 was examined. Yet, metallic lithium is known to diffuse into certain materials and reacts with atmospheric air by forming several reaction products. Therefore, the effect of a passivation layer on the substrate and protective covers of Au or LiF on the metallic Li layer (sandwiches), deposited by means of a multicrucible evaporation system, and the stability of the layers when irradiated with a proton beam were investigated.

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