Electrochemical Thin Layers in Nanostructures for Energy Storage

Noked, Malachi; Liu, Chanyuan; Hu, Jiangsheng; Gregorczyk, Keith; Rubloff, Gary W.; Lee, Sang Bok

doi:10.1021/acs.accounts.6b00315

Cited by 23 publications

(13 citation statements)

References 41 publications

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“…ALD Al 2 O 3 is generally used for this application and it has been found that a few ALD cycles can improve the cycling capability and capacity retention of the electrodes [80,81]. These results will not be discussed further here but the reader is advised that a lot of literature on this subject is available [80][81][82][83]. Some examples of ALD-made metal fluorides as artificial SEI layers will be shortly mentioned in Section 5.…”

Section: Atomic Layer Deposition Of Conventional Lithium-ion Battery mentioning

confidence: 99%

Metal Fluorides as Lithium-Ion Battery Materials: An Atomic Layer Deposition Perspective

2018

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Lithium-ion batteries are the enabling technology for a variety of modern day devices, including cell phones, laptops and electric vehicles. To answer the energy and voltage demands of future applications, further materials engineering of the battery components is necessary. To that end, metal fluorides could provide interesting new conversion cathode and solid electrolyte materials for future batteries. To be applicable in thin film batteries, metal fluorides should be deposited with a method providing a high level of control over uniformity and conformality on various substrate materials and geometries. Atomic layer deposition (ALD), a method widely used in microelectronics, offers unrivalled film uniformity and conformality, in conjunction with strict control of film composition. In this review, the basics of lithium-ion batteries are shortly introduced, followed by a discussion of metal fluorides as potential lithium-ion battery materials. The basics of ALD are then covered, followed by a review of some conventional lithium-ion battery materials that have been deposited by ALD. Finally, metal fluoride ALD processes reported in the literature are comprehensively reviewed. It is clear that more research on the ALD of fluorides is needed, especially transition metal fluorides, to expand the number of potential battery materials available.

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Section: Atomic Layer Deposition Of Conventional Lithium-ion Battery mentioning

confidence: 99%

Metal Fluorides as Lithium-Ion Battery Materials: An Atomic Layer Deposition Perspective

2018

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“…[4][5][6] To overcome the unfavorable cost and accelerate the practical applications, an appropriate specific amount of efficient non-precious transition metal compound materials including oxides, hydroxides, sulfides, phosphides, and phosphates, have been well-developed for electrochemical oxygen reduction and evolution reactions, exhibiting considerable electrocatalytic performance. [7][8][9] However, the insufficient stability and easy-aggregation property under harsh operating conditions and long-term service greatly weaken their superiority for widespread applications. [10][11][12] Accordingly, the catalysts with high electrocatalytic efficiency and robust durability beyond metallic electrocatalysts have attracted unprecedented attention.…”

Section: Introductionmentioning

confidence: 99%

“…Nevertheless, noble metal materials, for instance, Pt and its alloys for ORR and IrO 2 /RuO 2 for OER, remain the efficient electrocatalysts to decrease the large overpotentials resulted from polarization effect and unfavorably sluggish kinetics caused by multi‐electron process . To overcome the unfavorable cost and accelerate the practical applications, an appropriate specific amount of efficient non‐precious transition metal compound materials including oxides, hydroxides, sulfides, phosphides, and phosphates, have been well‐developed for electrochemical oxygen reduction and evolution reactions, exhibiting considerable electrocatalytic performance . However, the insufficient stability and easy‐aggregation property under harsh operating conditions and long‐term service greatly weaken their superiority for widespread applications .…”

Section: Introductionmentioning

confidence: 99%

Hierarchically Porous Heteroatoms‐doped Vesica‐like Carbons as Highly Efficient Bifunctional Electrocatalysts for Zn‐air Batteries

et al. 2018

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Developing highly efficient and cost‐effective electrocatalysts to boost the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) is vital for the sustainable energy systems. The nitrogen and phosphorus codoped vesica‐like carbons with hierarchical nanoporous structure are synthesized through an efficient self‐polymerization strategy with the template of g‐C3N4 monolith. Featuring sufficient heteroatom‐doping, well‐developed porous hierarchy, and high electrochemical surface area, the fabricated carbon materials exhibit considerable activity and robust stability in both electrocatalyzing ORR and OER, in competition with the precious metal electrocatalysts, which are thus capable of using as air cathode catalysts for rechargeable Zn‐air batteries, affording large discharge current density and impressive operation stability.

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“…Electrochemical devices such as batteries, fuel cells, and supercapacitors play a central role in this field 2, 3, 4. Each renewable energy source (e.g., wind, solar, geothermal) sets its own requirements for energy density, power density, life‐time, cost, and size.…”

Section: Introductionmentioning

confidence: 99%

“…[1] Electrochemical devices such as batteries, fuel cells, and supercapacitors play ac entralr olei nt his field. [2][3][4] Each renewable energy source (e.g.,w ind, solar,g eothermal) sets its own requirements for energy density,p ower density,l ife-time, cost, and size. Supercapacitors (also called electrochemical capacitors or ultracapacitors) are important power sourcesfor applications that require fast chargeand discharge.…”

Section: Introductionmentioning

confidence: 99%

Boosting the Supercapacitance of Nitrogen‐Doped Carbon by Tuning Surface Functionalities

et al. 2017

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The specific capacitance of a highly porous, nitrogen‐doped carbon is nearly tripled by orthogonal optimization of the microstructure and surface chemistry. First, the carbons’ hierarchical pore structure and specific surface area were tweaked by controlling the temperature and sequence of the thermal treatments. The best process (pyrolysis at 900 °C, washing, and subsequent annealing at 1000 °C) yielded a carbon with a specific capacitance of 117 F g−1—nearly double that of a carbon made by a typical single‐step synthesis at 700 °C. Following the structural optimization, the surface chemistry of the carbons was enriched by applying an oxidation routine based on a mixture of nitric and sulfuric acid in a 1:4 ratio at two different treatment temperatures (0 and 20 °C) and different treatment times. The optimal treatment times were 4 h at 0 °C and only 1 h at 20 °C. Overall, the specific capacitance nearly tripled relative to the original carbon, reaching 168 F g−1. The inherent nitrogen doping of the carbon comes into interplay with the acid‐induced surface functionalization, creating a mixture of oxygen‐ and nitrogen‐oxygen functionalities. The evolution of the surface chemistry was carefully followed by X‐ray photoelectron spectroscopy and by N2 sorption porosimetry, revealing stepwise surface functionalization and simultaneous carbon etching. Overall, these processes are responsible for the peak‐shaped capacitance trends in the carbons.

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Electrochemical Thin Layers in Nanostructures for Energy Storage

Cited by 23 publications

References 41 publications

Metal Fluorides as Lithium-Ion Battery Materials: An Atomic Layer Deposition Perspective

Metal Fluorides as Lithium-Ion Battery Materials: An Atomic Layer Deposition Perspective

Hierarchically Porous Heteroatoms‐doped Vesica‐like Carbons as Highly Efficient Bifunctional Electrocatalysts for Zn‐air Batteries

Boosting the Supercapacitance of Nitrogen‐Doped Carbon by Tuning Surface Functionalities

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