High‐Rate, Long‐Life Ni–Sn Nanostructured Electrodes for Lithium‐Ion Batteries

Hassoun, Jusef; Panero, S.; Simon, Patrice; Taberna, Pierre Louis; Scrosati, B.

doi:10.1002/adma.200602035

Cited by 390 publications

(262 citation statements)

References 14 publications

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“…One strategy is to design the nanostructure of electrode materials. [3,5,11] For example, if the SnO 2 anode comprises hollow and/or porous nanostructures, the local empty space in the structures can partially accommodate the large volume change, delaying capacity fading. [12][13][14][15][16][17][18][19][20] Another commonly used approach is to use nanocomposite materials (e.g., the inactive/ active concept).…”

mentioning

confidence: 99%

Designed Synthesis of Coaxial SnO₂@carbon Hollow Nanospheres for Highly Reversible Lithium Storage

2009

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A proof‐of‐concept structural design is demonstrated for high‐capacity lithium‐ion batteries anode materials by multistep synthesis of coaxial SnO2@carbon hollow nanospheres. This material integrates two beneficial features: hollow structure and carbon nanopainting. When evaluated for reversible lithium storage, these functional materials manifest excellent cycling performance and rate capabilities.

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confidence: 99%

Designed Synthesis of Coaxial SnO₂@carbon Hollow Nanospheres for Highly Reversible Lithium Storage

2009

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“…This leaves abundant Ni as a good choice for Ohmic contact as it is inexpensive, relatively less toxic, and has been widely used as an electrode material in other common applications, such as batteries 7 and fuel cells. 8 Its silicide is used in microelectronics to contact complementary metaloxide semiconductor integrated circuits because of its low resistivity, low temperature of formation, and good stability.…”

mentioning

confidence: 99%

Depleted-heterojunction colloidal quantum dot photovoltaics employing low-cost electrical contacts

Debnath

Greiner

Kramer

et al. 2010

Applied Physics Letters

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With an aim to reduce the cost of depleted-heterojunction colloidal quantum dot solar cells, we describe herein a strategy that replaces costly Au with a low-cost Ni-based Ohmic contact. The resultant devices achieve 3.5% Air Mass 1.5 power conversion efficiency. Only by incorporating a 1.2-nm-thick LiF layer between the PbS quantum dot film and Ni, we were able to prevent undesired reactions and degradation at the metal-semiconductor interface.

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“…10 Tin can also be electrodeposited on different complex architectures. 13,14 In this case, the deposition requires either an acidic electrolyte, 14,15 or a solution with a high pH containing a complexing agent such as oxalate, 13 to give deposits of pure tin. To coat complex architectures, the use of pulsed deposition has proved successful.…”

Section: Using Electrodeposition For the Synthesis Of Negative Electrmentioning

confidence: 99%

Electrodeposition as a Tool for 3D Microbattery Fabrication

et al. 2011

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I t is not difficult to explain the increasing worldwide interest in battery development. The current changes in the global energy outlook, including the shift to a higher fraction of solar and wind power, as well as the declining use of fossil fuels in vehicles, call for new autonomous energy storage solutions. The downscaling of microelectronic systems to produce small devices such as medical implants, micro sensors, self powered integrated circuits or microelectromechanical systems (MEMS), requires rechargeable batteries with better energy and power densities per footprint area than can be achieved with the thin film 2D batteries existing today.Today's rechargeable lithium-ion batteries-with the best performance when it comes to energy density and with a reasonably good power efficiency-are dominating the market for consumer electronics. There is, however, a need for rechargeable storage devices that combine small volume with high energy and power densities. Typically, there is a demand for batteries on the 1-10 mm 3 volume scale, including all components and associated packaging. Moreover, miniaturized devices usually need the energy storage functions to be physically located on a small area-on a chip-making the energy and power density per footprint area a key factor for these batteries. The energy demand for these products is generally in the order of 1 J/(mm 2 day), which conventional battery technologies fail to supply by an order of magnitude or more. Given the wide range of electrode chemistries available for lithium-ion batteries, these batteries are well-suited to be shaped into different complex 3D high-capacity architectures.This article focuses on the use of electrodeposition as a tool for manufacturing complex 3D battery architectures. Electrodeposition as a Tool for 3D Microbattery Fabrication

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High‐Rate, Long‐Life Ni–Sn Nanostructured Electrodes for Lithium‐Ion Batteries

Cited by 390 publications

References 14 publications

Designed Synthesis of Coaxial SnO₂@carbon Hollow Nanospheres for Highly Reversible Lithium Storage

Designed Synthesis of Coaxial SnO₂@carbon Hollow Nanospheres for Highly Reversible Lithium Storage

Depleted-heterojunction colloidal quantum dot photovoltaics employing low-cost electrical contacts

Electrodeposition as a Tool for 3D Microbattery Fabrication

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High‐Rate, Long‐Life Ni–Sn Nanostructured Electrodes for Lithium‐Ion Batteries

Cited by 390 publications

References 14 publications

Designed Synthesis of Coaxial SnO2@carbon Hollow Nanospheres for Highly Reversible Lithium Storage

Designed Synthesis of Coaxial SnO2@carbon Hollow Nanospheres for Highly Reversible Lithium Storage

Depleted-heterojunction colloidal quantum dot photovoltaics employing low-cost electrical contacts

Electrodeposition as a Tool for 3D Microbattery Fabrication

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Product

Resources

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Designed Synthesis of Coaxial SnO₂@carbon Hollow Nanospheres for Highly Reversible Lithium Storage

Designed Synthesis of Coaxial SnO₂@carbon Hollow Nanospheres for Highly Reversible Lithium Storage