A review of atomic layer deposition for high lithium-ion battery performance

Riyanto, Edy; Martides, Erie; Pikra, Ghalya; Atmaja, Tinton Dwi; Pramana, Rakhmad Indra; Purwanto, Andri Joko; Santosa, Arifin; Junianto, Endro; Darussalam, Rudi; Saepudin, Aep; Susatyo, Anjar; Subekti, Ridwan Arief; Utomo, Yusuf Suryo; Subagio, Dalmasius Ganjar; Fudholi, Ahmad; Abimanyu, Haznan; Radiansah, Yadi; Sudibyo, Henny; Kusnadi, Kusnadi; Rajani, Ahmad; Suprapto, Suprapto; Prawara, Budi

doi:10.1016/j.jmrt.2021.10.138

Cited by 12 publications

(9 citation statements)

References 142 publications

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“…A key issue in the batteries, especially in lithium-ion batteries (LiB), is the degradation reaction taking place at the electrolyte interface, causing the formation of a passivation layer at the surface of the negatively charged electrode. − Previous ALD-based reports showed that the deposition of ultrathin buffer layers on electrode materials is effective to reduce the passivation layer formation and promote a rapid electron transfer . Typical ALD deposited layers are based on oxide materials such Al 2 O 3 , ZnO, or HfO 2 , all of them improving the battery lifetime during long-term cycles.…”

Section: Overview and Discussionmentioning

confidence: 99%

Assessing the Environmental Impact of Atomic Layer Deposition (ALD) Processes and Pathways to Lower It

et al. 2023

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Due to concerns on resources depletion, climate change, and overall pollution, the quest toward more sustainable processes is becoming crucial. Atomic layer deposition (ALD) is a versatile technology, allowing for the precise coating of challenging substrates with a nanometer control over thickness. Due to its unique ability to nanoengineer interfaces and surfaces, ALD is widely used in many applications. Although the ALD technique offers the potential to tackle environmental challenges, in particular, considerations regarding the sustainability of renewable energy devices urge for greater efficiency and lower carbon footprint. Indeed, the process itself has currently a consequential impact on the environment, which should ideally be reduced as the technique is implemented in a wider range of products and applications. This paper reviews the studies carried out on the assessment of the environmental impact of ALD and summarizes the main results reported in the literature. Next, the principles of green chemistry are discussed, considering the specificities of the ALD process. This work also suggests future pathways to reduce the ALD environmental impact; in particular, the optimization of the reactor and processing parameters, the use of high throughput processes such as spatial ALD (SALD), and the chemical design of greener precursors are proposed as efficient routes to improve ALD sustainability.

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Section: Overview and Discussionmentioning

confidence: 99%

Assessing the Environmental Impact of Atomic Layer Deposition (ALD) Processes and Pathways to Lower It

et al. 2023

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“…[179,[181][182][183][184][185][186][187][188][189][190][191] Several remarkable reviews primarily concentrated on ALD-based electrode materials for rechargeable batteries. [192][193][194][195][196][197][198][199][200][201][202][203][204][205] Among these, several notable reviews have been primarily dedicated to exploring ALD-based electrode materials in the context of rechargeable batteries. Such investigations are crucial in our pursuit of improved energy storage solutions, and these comprehensive analyses have significantly advanced our understanding in this area.…”

Section: Ald Applications For Scsmentioning

confidence: 99%

Atomic Layer Deposition—A Versatile Toolbox for Designing/Engineering Electrodes for Advanced Supercapacitors

Ansari,

Hussain,

Mohapatra

et al. 2023

Advanced Science

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Atomic layer deposition (ALD) has become the most widely used thin‐film deposition technique in various fields due to its unique advantages, such as self‐terminating growth, precise thickness control, and excellent deposition quality. In the energy storage domain, ALD has shown great potential for supercapacitors (SCs) by enabling the construction and surface engineering of novel electrode materials. This review aims to present a comprehensive outlook on the development, achievements, and design of advanced electrodes involving the application of ALD for realizing high‐performance SCs to date, as organized in several sections of this paper. Specifically, this review focuses on understanding the influence of ALD parameters on the electrochemical performance and discusses the ALD of nanostructured electrochemically active electrode materials on various templates for SCs.It examines the influence of ALD parameters on electrochemical performance and highlights ALD's role in passivating electrodes and creating 3D nanoarchitectures. The relationship between synthesis procedures and SC properties is analyzed to guide future research in preparing materials for various applications. Finally, it is concluded by suggesting the directions and scope of future research and development to further leverage the unique advantages of ALD for fabricating new materials and harness the unexplored opportunities in the fabrication of advanced‐generation SCs.

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“…Nano-particle coatings are effective in improving structural stability and cycling performance of micron-sized CAM particles. Different coating materials like Al 2 O 3 [91,117,118], LiAlO 2 [119], CeO 2 [120], ZnO [121], ZrO 2 [121] have been coated on the surface of CAM particles through the sol-gel [119], dry mechanofusion (figure 10(b)) [122], and ALD [123,124] techniques. ALD has advantages over other coating methods in terms of regulating film thickness in the Angstrom range, allowing a uniform coating and good conformality [124].…”

Section: Doping Coating and Post-processingmentioning

confidence: 99%

“…Different coating materials like Al 2 O 3 [91,117,118], LiAlO 2 [119], CeO 2 [120], ZnO [121], ZrO 2 [121] have been coated on the surface of CAM particles through the sol-gel [119], dry mechanofusion (figure 10(b)) [122], and ALD [123,124] techniques. ALD has advantages over other coating methods in terms of regulating film thickness in the Angstrom range, allowing a uniform coating and good conformality [124]. Studies investigating effect of ALD coatings on the electrochemical performance have been collated [123,124].…”

Section: Doping Coating and Post-processingmentioning

confidence: 99%

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Status and outlook for lithium-ion battery cathode material synthesis and the application of mechanistic modeling

Pardikar

Entwistle

et al. 2023

J. Phys. Energy

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This work reviews different techniques available for the synthesis and modification of cathodeactive material particles used in Li-ion batteries. The synthesis techniques are analyzed in termsof processes involved and product particle structure. The knowledge gap in the process-particlestructure relationship is identified. Many of these processes are employed in other similarindustries; hence, parallel insights and knowledge transfer can be applied to battery materials.Here, we discuss examples of applications of different mechanistic models outside the batteryliterature and identify similar potential applications for the synthesis of cathode active materials.We propose that the widespread implementation of such mechanistic models will increase theunderstanding of the process-particle structure relationship. Such understanding will providebetter control over the cathode active material synthesis technique and open doors to the precisetailoring of product particle morphologies favorable for enhanced electrochemical performance.

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A review of atomic layer deposition for high lithium-ion battery performance

Cited by 12 publications

References 142 publications

Assessing the Environmental Impact of Atomic Layer Deposition (ALD) Processes and Pathways to Lower It

Assessing the Environmental Impact of Atomic Layer Deposition (ALD) Processes and Pathways to Lower It

Atomic Layer Deposition—A Versatile Toolbox for Designing/Engineering Electrodes for Advanced Supercapacitors

Status and outlook for lithium-ion battery cathode material synthesis and the application of mechanistic modeling

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