Hydrothermal Fabrication of Three‐Dimensional Secondary Battery Anodes

Liu, Jinyun; Zhang, Huigang; Wang, Junjie; Cho, Jiung; Pikul, James H.; Epstein, Eric S.; Huang, Xing‐Jiu; Liu, Jinhuai; King, William P.; Braun, Paul V.

doi:10.1002/adma.201402552

Cited by 48 publications

(34 citation statements)

References 37 publications

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“…Fe 3 O 4 /C Composite Growth and Carbonization Treatment : In a typical solvothermal growth, via a process similar to our previous report, 5 mmol ferrocene (Sigma–Aldrich Corp.) was dissolved in 35 mL acetone. Subsequently, 1.0 mL hydrogen peroxide (30 wt%) was added into the solution followed by ultrasonication for 30 min.…”

Section: Methodsmentioning

confidence: 99%

High Full‐Electrode Basis Capacity Template‐Free 3D Nanocomposite Secondary Battery Anodes

Liu

Wang

Kim

et al. 2015

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A high full-electrode basis capacity secondary battery anode consisting of a template-free 3D nanostructured Fe3O4/C composite is presented. On a full electrode basis, the nanocomposite exhibits attractive electrochemical performance including a volumetric capacity of 1064 mAh cm(-3), which significantly exceeds both the practical (≈300 mAh cm(-3)) and theoretical (837 mAh cm(-3)) capacity of a commercial graphite-based anode.

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Section: Methodsmentioning

confidence: 99%

High Full‐Electrode Basis Capacity Template‐Free 3D Nanocomposite Secondary Battery Anodes

Liu

Wang

Kim

et al. 2015

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“…[5,23–26] These technological advancements have led to the search for 3D structured microbatteries, flexible and stretchable electrochemical energy storage and conversion technologies. [27,28] Insufficient power from 2D battery configurations, including the standard slurry mixture approach to cathode materials, was an open call for the development and improvement of 3D micro- or nanobatteries using cheap and light micro/nano fabrication materials and techniques. [29] At the core of these developments are the advancement in the type of materials, where composition, crystallinity, shape and chemical potential define the cycle life, capacity, voltage and energy density, etc.…”

Section: Introductionmentioning

confidence: 99%

2D and 3D photonic crystal materials for photocatalysis and electrochemical energy storage and conversion

Collins

Armstrong

McNulty

et al. 2016

Science and Technology of Advanced Materials

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This perspective reviews recent advances in inverse opal structures, how they have been developed, studied and applied as catalysts, catalyst support materials, as electrode materials for batteries, water splitting applications, solar-to-fuel conversion and electrochromics, and finally as photonic photocatalysts and photoelectrocatalysts. Throughout, we detail some of the salient optical characteristics that underpin recent results and form the basis for light-matter interactions that span electrochemical energy conversion systems as well as photocatalytic systems. Strategies for using 2D as well as 3D structures, ordered macroporous materials such as inverse opals are summarized and recent work on plasmonic–photonic coupling in metal nanoparticle-infiltrated wide band gap inverse opals for enhanced photoelectrochemistry are provided.

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“…22 However, these deposition techniques are typically expensive, slow, providing a limited choice of active materials and not available for the large surface area. 23 In addition, they cannot modulate the facet selectivity of the photocatalysts and it could not be expected to improve PEC performance from facet engineering.…”

Section: Introductionmentioning

confidence: 99%

A selectively exposed crystal facet-engineered TiO₂ thin film photoanode for the higher performance of the photoelectrochemical water splitting reaction

Kim

Yeob

Cheng

et al. 2015

Energy Environ. Sci.

100

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In the present study, selectively exposed (101)-crystal facet engineered TiO2 photoanode is investigated for the higher efficiency of hydrogen evolution reaction. Till date, even the photoelectrochemical performance (PEC) depending on the exposed crystal facet have been calculated and demonstrated in the semiconducting microcrystals, selectively exposed crystal facet of photocatalyst thin films has not been reported yet. Herein, we demonstrate TiO2 thin film photoanode with 100%-exclusively exposed crystal facet and suggest the methodology for metal oxide thin film photoanode with selectively exposed crystal facet. Selectively exposed crystal facet-manipulated metal oxide thin film photoanode is fabricated over the pre-synthesized microcrystals through a three-step strategy: 1) hydrothermal synthesis of microcrystals, 2) positioning of microcrystals via polymer-induced manual assembly, and 3) fabrication of selectively exposed crystal facet of TiO2 thin film through secondary growth hydrothermal reaction. Based on the synthesis of representative TiO2 microcrystals with dominantly exposed (101), (100) and (001) crystal facet, selectively exposed crystal faceted TiO2 thin film photoanode is comparatively investigated for practical PEC performance. The photocurrent density of selectively exposed (101) crystal faceted TiO2 thin film photoanode is determined as 0.13 mA cm -2 and produce 18% of incident photon-to-current conversion efficiency at 0.65 V Ag/AgCl potential under AM 1.5 G illumination. Its photoelectrochemical hydrogen production reached to 0.07 mmol cm -2 for 12 hrs, which is higher than those of (100) and (001) faceted photoelectrode.

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Hydrothermal Fabrication of Three‐Dimensional Secondary Battery Anodes

Cited by 48 publications

References 37 publications

High Full‐Electrode Basis Capacity Template‐Free 3D Nanocomposite Secondary Battery Anodes

High Full‐Electrode Basis Capacity Template‐Free 3D Nanocomposite Secondary Battery Anodes

2D and 3D photonic crystal materials for photocatalysis and electrochemical energy storage and conversion

A selectively exposed crystal facet-engineered TiO₂ thin film photoanode for the higher performance of the photoelectrochemical water splitting reaction

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Hydrothermal Fabrication of Three‐Dimensional Secondary Battery Anodes

Cited by 48 publications

References 37 publications

High Full‐Electrode Basis Capacity Template‐Free 3D Nanocomposite Secondary Battery Anodes

High Full‐Electrode Basis Capacity Template‐Free 3D Nanocomposite Secondary Battery Anodes

2D and 3D photonic crystal materials for photocatalysis and electrochemical energy storage and conversion

A selectively exposed crystal facet-engineered TiO2 thin film photoanode for the higher performance of the photoelectrochemical water splitting reaction

Contact Info

Product

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A selectively exposed crystal facet-engineered TiO₂ thin film photoanode for the higher performance of the photoelectrochemical water splitting reaction