Tag: ion

Surface Modification of Lithium Metal Foil

lithium metal foil is a soft, flexible sheet of lithium that can be rolled down to an extremely thin thickness. This material has potential applications in lithium batteries for mobile phones and other electronics, because it can be a low-cost alternative to the more expensive lithium cobalt (LiCo) and nickel manganese (NMC) electrodes currently used.

The performance of these lithium metal anodes can be dramatically improved by surface modification to suppress dendrite growth and improve ionic conductivity between the electrode and the liquid electrolyte. One such method involves spray painting the lithium surface with a soluble graphene oxide (GO) solution, which is reduced spontaneously to form a thick layer of GO on the electrode, resulting in a much smoother and tighter surface than the unmodified foil. As a result, the GO-modified foil is able to sustain flat voltage plateaus for up to 1,000 cycles in Li/Li coin cells under OCV.

A less-studied method of surface modification consists of immersing the lithium metal in a DMSO solution containing an ionically conductive polymer to form a protective layer on the electrode surface. Choi et al. showed that the ionically conductive polymer PEDOT-co-PEG was capable of inhibiting dendrite growth by providing inter-space between lithium ions, as confirmed by XPS analysis.

To demonstrate the effectiveness of this approach, the morphology and chemistry of both the as-received and roll-pressed lithium electrodes were studied in detail by AFM, SEM, and XPS. The results indicate that the roll-press treatment significantly reduces both the roughness and thickness of the native surface film on the lithium foil. The morphology of the as-received lithium is characterised by mountain- and valley-like structures, while the thinning of the native film leads to a flatter topography with fewer of these structures on the roll-pressed foil. These changes were reflected in the evolution of the SEI during cycling of Li/Li symmetric cells, with the as-received electrode exhibiting major voltage oscillations after the first cycle while the roll-pressed electrode displayed a stable charge–discharge behavior for up to 70 cycles.

lithium metal foil

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The Melting Point of TiO2

TiO2 is an inorganic compound, also known as titanium(IV) oxide, that is used in a variety of applications, such as sensors for CO, H2, ozone, and formaldehyde. The melting point of TiO2 is 1840degC.

The structure of TiO2 is dependent on the annealing conditions. For example, it is possible to form a TiO2-x/TiO2-based heterostructure by annealing at 800 degC.

TiO2 is an n-type semiconductor, with a charge mobility of 0.4 cm2/V s. It has a relatively low melting point. However, it is difficult to produce large Ti3O5 crystals due to the polymorphism of titanium oxides.

In addition, TiO2 has been applied as sensing material in room temperature sensors for CO, H2, ozone, formaldehyde, and other gases. Moreover, it has been used as a sensor in the sensing of C7H8.

There are several methods for forming TiO2 structures. One method involves thermochemical treatment. Another is ion irradiation. Ion irradiation results in a change in the crystalline structure of the titanium oxide. These changes can cause the formation of latent ion tracks. Similarly, excessive local heating may also lead to the formation of latent ion tracks.

An XPS analysis showed the presence of ion beam-induced vacancies in the TiO2 lattice. These vacancies are consistent with the lateral dimension of the ion track observed in high resolution TEM images. This indicates that the ion track forms inside the TiO2 material.

The model of thermal spike induced melting predicts that this type of melting is possible. The resulting strain and distortions of the crystalline structure are manifested as shi in the Raman spectra.


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TiO2 is an inorganic compound, also known as titanium(IV) oxide, that is used in a variety of applications, such as sensors for CO, H2, ozone, […]

Continue reading