Li and Na-ion diffusion and intercalation characteristics in vertically aligned TiS&lt;sub&gt;2&lt;/sub&gt; nanowall network grown using atomic layer deposition

Sayed, Farheen N.; Sreedhara, M. B.; Soni, Amit; Bhat, Usha; Datta, Ranjan; Bhattacharyya, Aninda J.

doi:10.1088/2053-1591/ab3e19

Cited by 15 publications

(25 citation statements)

References 31 publications

(41 reference statements)

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“…Here, the conductivity at 30 °C was about 40 times higher than that of the room‐temperature orthorhombic phase of LFC, which was calculated to have a diffusion coefficient of 2.8 × 10 −10 cm 2 s −1 by the Nernst–Einstein equation. [ 46 ] The value was compared with other diffusion coefficients of the orthorhombic LFC and some representative cathode materials for Li‐ion batteries, [ 47–51 ] as shown in Table 1 . Note that the chemical diffusion coefficient measured for thin‐film electrodes, not for composite electrodes, are only selected in Table 1 for comparison purposes considering the Haven ratio.…”

Section: Resultsmentioning

confidence: 99%

High Formability and Fast Lithium Diffusivity in Metastable Spinel Chloride for Rechargeable All‐Solid‐State Lithium‐Ion Batteries

Tanibata

Kato

Takimoto

et al. 2020

Adv Energy and Sustain Res

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Materials with high formability and Li‐ion diffusivity are desired to realize safe bulk‐type all‐solid‐state Li‐ion batteries with high energy density. Spinel‐type Li2FeCl4, which is expected as a Li‐ion‐conductive electrode, adopts the high‐temperature cubic phase (space group: Fd‐3m) by a mechanochemical synthesis method. The powder‐compressed pellet shows a high relative density of 92% and large neck formation between the particles. An analysis of the distribution of relaxation times from the AC impedance results indicates that the contribution of the grain boundary impedance is almost negligible (≈3%) in the powder‐compressed pellet. Even the Li diffusion coefficient, which is underestimated by the Nernst–Einstein equation, is several orders of magnitude higher than those of conventional oxide and sulfide electrode materials. Analyzing the diffusion pathways using a classical force field calculation suggests that stabilizing the high‐temperature phase at room temperature delocalizes Li ions in the diffusion pathway, thus realizing high Li‐ion diffusivity. The Li2FeCl4 green compact containing 10 wt% carbon as an electron‐conductive additive shows a one‐electron charge reaction with a capacity of 126 mAh g−1, with no large overpotential at a high operating voltage of 3.6 V versus Li/Li+ at 30 °C.

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Section: Resultsmentioning

confidence: 99%

High Formability and Fast Lithium Diffusivity in Metastable Spinel Chloride for Rechargeable All‐Solid‐State Lithium‐Ion Batteries

Tanibata

Kato

Takimoto

et al. 2020

Adv Energy and Sustain Res

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“…Sayed et al. [ 255 ] have studied diffusion and intercalation mechanisms of Li + and Na + ions into rough ALD TiS 2 films. The first cycle discharge capacities of both Li + and Na + ions, ≈750 and 450 mAh g −1 , respectively, were lower compared to most of the MoS 2 and WS 2 anodes discussed here but still higher than that of graphite, for example.…”

Section: Applications Of Atomic Layer Deposited 2d Metal Dichalcogenidesmentioning

confidence: 99%

“…Tens of nm rough films (50 nm) LIB, NIB [255] Ti(NMe 2 ) 4 + H 2 S 150-180 ≈5-100 nm films (amorp., oxidizes) - [256] 100 ≈30 nm rough film (cryst.) - [257] Ti(NMe 2 ) 4 + H 2 S plasma 150-200 ≈30 nm rough film (≈50-100 nm) - [257] WS 2 WCl 6 + H 2 S e) 390 a few-10 ML (cryst.)…”

mentioning

confidence: 99%

Atomic Layer Deposition of 2D Metal Dichalcogenides for Electronics, Catalysis, Energy Storage, and Beyond

Mattinen

Leskelä

Ritala

2021

Adv Materials Inter

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it was soon replaced by other materials. Research on the fundamental properties and preparation of TMDC monolayers in solution (1986), [8] on single-crystal substrates in ultrahigh vacuum (2001), [9] and in an accessible way using mechanical exfoliation [10] (2005) followed. It was the discovery of graphene in 2004 [11] with its ever expanding list of unique and exciting properties, phenomena, and potential applications [12] that amassed broad attention to 2D materials and resulted in the 2010 Nobel Prize in Physics awarded to Andre Geim and Konstantin Novoselov. Tremendous efforts have been put toward synthesis and applications of graphene, including the billion euro Graphene Flagship project funded by the European Union. [13,14] Graphene is a semimetal, however, and the need to have semiconducting materials for many crucial applications, in particular in electronics, has led researchers to search for other 2D materials. The scientific community turned to TMDCs following breakthroughs in observation of unique thickness-dependent properties, [15,16] monolayer synthesis using chemical vapor deposition (CVD), [17,18] and demonstration of high-performance semiconductor devices [19-21] in 2010-2013 (Figure 1). Indeed, in 2013 the number of scientific publications on TMDCs, in particular MoS 2 , nearly tripled over 2012, and the strong growth has continued to date, fueled by advances in synthesis, new devices, and exciting physical phenomena. The explosive growth in MoS 2 research has also expanded to other TMDCs, [22] resulting in yet new phenomena and potential applications being found. [23-26] It is now clear that TMDCs are remarkable in many ways. Their layered crystal structure gives rise to fundamental physics not seen in 3D materials, which enables novel devices and applications. [25,26,32,34-36] The layered structure also gives TMDCs their highly anisotropic properties, extremely high specific surface areas, possibility to intercalate different species between the layers, and stability as ultrathin sheets down to three atomic layers thick. The TMDC family contains dozens of different materials from semiconductors to semimetals, metals, and even superconductors. [5,22,25,34] However, TMDC research is still mostly in the early discovery stages and the investigations of TMDCs largely continue using flakes produced by mechanical exfoliation of bulk crystals. [10,26] Unfortunately, this method cannot be scaled up for practical 2D transition metal dichalcogenides (TMDCs) are among the most exciting materials of today. Their layered crystal structures result in unique and useful electronic, optical, catalytic, and quantum properties. To realize the technological potential of TMDCs, methods depositing uniform films of controlled thickness at low temperatures in a highly controllable, scalable, and repeatable manner are needed. Atomic layer deposition (ALD) is a chemical gas-phase thin film deposition method capable of meeting these challenges. In this review, the applications evaluated for ALD TMDCs are systematically...

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“…Consequently, the VO 2 cathode achieved a high specific capacity (444.2 mAh g −1 at 50 mA g −1 ), superior rate capability (156.7 mAh g −1 at 2000 mA g −1 ), and stable cycle life (900 cycles, Figure 8d–f). Low‐tortuous cathodes such as LFP walls, [ 104 ] LFP nanoarrays, [ 105 ] LiCoO 2 nanorods, [ 106 ] LiCoO 2 nanowires, [ 107 ] V 2 O 5 nanoneedle arrays, [ 108 ] FeF 2 walls, [ 109 ] and TiS 2 nanowalls [ 110 ] have also been developed via glancing angle deposition, stacked LiCoO 2 /graphite sheets cosintering approach, solvothermal method, and atomic layer deposition, to improve their energy densities and rate capacities.…”

Section: Low‐tortuous Cathodes For Metallic Lithium Batteriesmentioning

confidence: 99%

Tortuosity Modulation toward High‐Energy and High‐Power Lithium Metal Batteries

Shi

Zhang

et al. 2021

Advanced Energy Materials

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Li and Na-ion diffusion and intercalation characteristics in vertically aligned TiS<sub>2</sub> nanowall network grown using atomic layer deposition

Cited by 15 publications

References 31 publications

High Formability and Fast Lithium Diffusivity in Metastable Spinel Chloride for Rechargeable All‐Solid‐State Lithium‐Ion Batteries

High Formability and Fast Lithium Diffusivity in Metastable Spinel Chloride for Rechargeable All‐Solid‐State Lithium‐Ion Batteries

Atomic Layer Deposition of 2D Metal Dichalcogenides for Electronics, Catalysis, Energy Storage, and Beyond

Tortuosity Modulation toward High‐Energy and High‐Power Lithium Metal Batteries

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