Multifunctional 3D nanoarchitectures for energy storage and conversion

Rolison, Debra R.; Long, Jeffrey W.; Lytle, Justin C.; Fischer, Anne E.; Rhodes, Christopher P.; McEvoy, Todd M.; Bourg, Megan; Lubers, Alia M.

doi:10.1039/b801151f

Cited by 781 publications

(610 citation statements)

References 251 publications

(399 reference statements)

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“…In addition, the method of fabrication must be scalable to allow for large amounts of total stored energy. 6,7 There have been many preliminary attempts to create such a network using foams, 8 nanocolumns, 9 nanowires, 10 nanoakes, 11 and lithographically dened microstructures. 12 Nonetheless, these designs have not been able to meet the requirements of next generation electrodes mentioned above.…”

Section: Introductionmentioning

confidence: 99%

Microstructural tunability of co-continuous bijel-derived electrodes to provide high energy and power densities

2016

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Section: Introductionmentioning

confidence: 99%

Microstructural tunability of co-continuous bijel-derived electrodes to provide high energy and power densities

2016

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“…However, conventional pseudocapacitors made from state‐of‐the‐art electrode materials, typically transition‐metal oxides (TMOs) such as MnO 2 ,5, 15, 19, 20 TiO 2 ,6, 16 and Co 3 O 4 ,19, 21 often exhibit much lower power capability than EDLCs due to their intrinsically poor conductivity 15, 21. It thus remains a primarily challenge in realizing high‐power and high‐energy densities in pseudocapacitors, which requires pseudocapacitive electrode materials simultaneously providing large specific surface area and ultrahigh transports of ions and electrons 22, 23, 24. In this regard, controlling nanostructures and exploring novel materials have become critical processes to meet these requirements in developing TMO‐based composite electrodes,1, 6, 17, 23, 25 wherein various conductive materials, including nanostructured carbons (such as porous carbon,14, 26 carbon nanotubes,27, 28, 29, 30 and graphene 31, 32) and conducting polymers, are extensively employed to serve as electron pathways.…”

Section: Introductionmentioning

confidence: 99%

Ultrahigh‐Power Pseudocapacitors Based on Ordered Porous Heterostructures of Electron‐Correlated Oxides

et al. 2016

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Nanostructured transition‐metal oxides can store high‐density energy in fast surface redox reactions, but their poor conductivity causes remarkable reductions in the energy storage of most pseudocapacitors at high power delivery (fast charge/discharge rates). Here it is shown that electron‐correlated oxide hybrid electrodes made of nanocrystalline vanadium sesquioxide and manganese dioxide with 3D and bicontinuous nanoporous architecture (NP V2O3/MnO2) have enhanced conductivity because of metallization of electron‐correlated V2O3 skeleton via insulator‐to‐metal transition. The conductive V2O3 skeleton at ambient temperature enables fast electron and ion transports in the entire electrode and facilitates charge transfer at abundant V2O3/MnO2 interface. These merits significantly improve the pseudocapacitive behavior and rate capability of the constituent MnO2. Symmetric pseudocapacitors assembled with binder‐free NP V2O3/MnO2 electrodes deliver ultrahigh electrical powers (up to ≈422 W cm23) while maintaining the high volumetric energy of thin‐film lithium battery with excellent stability.

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“…In comparison to the 2D planar substrates, the 3D porous substrates have the following advantages ( Figure 9 ): First, the unique 3D structure provides more growth sites, thus a higher loading mass of active materials can be realized, leading to a higher specific areal capacity and a higher gravimetric capacity with respect to the whole electrode 126, 127. Second, the unique porous structure of 3D conductive substrates offers accessible pathways for the penetration of electrolyte, accelerating the Li + ion diffusion and interface reaction kinetics 128. Finally, the fast electron transport along the 3D conductive substrate is beneficial for improving the high‐rate performance.…”

Section: Self‐supported Metal Oxide Nanoarrays On 3d Porous Substratesmentioning

confidence: 99%

Recent Progress in Self‐Supported Metal Oxide Nanoarray Electrodes for Advanced Lithium‐Ion Batteries

Zhang

2016

Advanced Science

107

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The rational design and fabrication of electrode materials with desirable architectures and optimized properties has been demonstrated to be an effective approach towards high‐performance lithium‐ion batteries (LIBs). Although nanostructured metal oxide electrodes with high specific capacity have been regarded as the most promising alternatives for replacing commercial electrodes in LIBs, their further developments are still faced with several challenges such as poor cycling stability and unsatisfying rate performance. As a new class of binder‐free electrodes for LIBs, self‐supported metal oxide nanoarray electrodes have many advantageous features in terms of high specific surface area, fast electron transport, improved charge transfer efficiency, and free space for alleviating volume expansion and preventing severe aggregation, holding great potential to solve the mentioned problems. This review highlights the recent progress in the utilization of self‐supported metal oxide nanoarrays grown on 2D planar and 3D porous substrates, such as 1D and 2D nanostructure arrays, hierarchical nanostructure arrays, and heterostructured nanoarrays, as anodes and cathodes for advanced LIBs. Furthermore, the potential applications of these binder‐free nanoarray electrodes for practical LIBs in full‐cell configuration are outlined. Finally, the future prospects of these self‐supported nanoarray electrodes are discussed.

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Multifunctional 3D nanoarchitectures for energy storage and conversion

Cited by 781 publications

References 251 publications

Microstructural tunability of co-continuous bijel-derived electrodes to provide high energy and power densities

Microstructural tunability of co-continuous bijel-derived electrodes to provide high energy and power densities

Ultrahigh‐Power Pseudocapacitors Based on Ordered Porous Heterostructures of Electron‐Correlated Oxides

Recent Progress in Self‐Supported Metal Oxide Nanoarray Electrodes for Advanced Lithium‐Ion Batteries

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