3D Honeycomb Architecture Enables a High‐Rate and Long‐Life Iron (III) Fluoride–Lithium Battery

Wu, Feixiang; Šrot, Vesna; Chen, Shuangqiang; Lorger, Simon; Aken, Peter A. van; Maier, Joachim; Yu, Yan

doi:10.1002/adma.201905146

Cited by 99 publications

(103 citation statements)

References 50 publications

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“…[88][89][90][91][92] Thee xcellent conductivity as well as the facilely tuned pore characteristics and physicochemical properties of carbon-based supports accelerate the mass transport and gas diffusion kinetics. [93][94][95][96][97][98] Furthermore,t he combination of metal atoms and non-carbon supports generates more potential active centers for the HER. [99] At present, M-N x ,M-C x etc.…”

Section: Single-metal Active Centersmentioning

confidence: 99%

“…The strong metal–support interactions not only immobilize the metal atoms on the supports to influence the coordination configurations, but also modulate the electron transfer and adsorption/desorption behavior [88–92] . The excellent conductivity as well as the facilely tuned pore characteristics and physicochemical properties of carbon‐based supports accelerate the mass transport and gas diffusion kinetics [93–98] . Furthermore, the combination of metal atoms and non‐carbon supports generates more potential active centers for the HER [99] .…”

Section: Single‐metal Active Centersmentioning

confidence: 99%

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Designing Atomic Active Centers for Hydrogen Evolution Electrocatalysts

et al. 2020

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The evolution of hydrogen from water using renewable electrical energy is a topic of current interest. Pt/C exhibits the highest catalytic activity for the H2 evolution reaction (HER), but scarce supplies and high cost limit its large‐scale application. Atomic active centers in single‐atom catalysts, single‐atom alloys, and catalysts with two atom sorts exhibit maximum atomic efficiency, unique structure, and exceptional activity for the HER. Interactions between well‐defined active sites and supports are known to affect electron transfer and dramatically accelerate the reaction. This Review first highlights methods for studying atomic active centers for the HER. Then, active sites with different coordination configurations are described. Active centers with one metal atom, two different metal atoms as well as nonmetal atoms are analyzed at the atomic scale. Finally, future research perspectives are proposed.

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Section: Single-metal Active Centersmentioning

confidence: 99%

Section: Single‐metal Active Centersmentioning

confidence: 99%

Designing Atomic Active Centers for Hydrogen Evolution Electrocatalysts

et al. 2020

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“…[88][89][90][91][92] Sowohl die ausgezeichnete Leitfähigkeit, die Tr äger auf Kohlenstoffbasis bieten, als auch die leicht einstellbaren Eigenschaften ihrer Poren und ihre physikochemischen Eigenschaften beschleunigen den Massentransport sowie die Kinetik der Gasdiffusion. [93][94][95][96][97][98] Im Übrigen erzeugt die Kombination von Metallatomen mit Nicht-Kohlenstoffträgern mehr potentielle aktive Zentren fürd ie HER. [99] Gegenwärtig haben sich M-N x ,M -C x usw.…”

Section: Aktive Atomare Einzelmetallzentrenunclassified

“…Die starken Wechselwirkungen zwischen den aktiven Metallatomen und dem Träger immobilisieren die Metallatome, wodurch die Koordinationskonfiguration beeinflusst wird, und bestimmen den Prozess der Elektronenübertragung sowie das Adsorptions‐/Desorptionsverhalten [88–92] . Sowohl die ausgezeichnete Leitfähigkeit, die Träger auf Kohlenstoffbasis bieten, als auch die leicht einstellbaren Eigenschaften ihrer Poren und ihre physikochemischen Eigenschaften beschleunigen den Massentransport sowie die Kinetik der Gasdiffusion [93–98] . Im Übrigen erzeugt die Kombination von Metallatomen mit Nicht‐Kohlenstoffträgern mehr potentielle aktive Zentren für die HER [99] .…”

Section: Aktive Atomare Einzelmetallzentrenunclassified

Design aktiver atomarer Zentren für HER‐Elektrokatalysatoren

et al. 2020

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Die Entwicklung von Wasserstoff aus Wasser mithilfe erneuerbarer elektrischer Energie ist zukunftsweisend. Die Kombination von Platin auf Kohlenstoff zeigt die höchste katalytische Aktivität bei der Wasserstoffentwicklungsreaktion (HER), jedoch schränken das knappe Angebot und die hohen Kosten die großtechnische Anwendung ein. Aktive atomare Zentren in Katalysatoren mit einer Atomsorte, Legierungen mit einer aktiven Atomsorte und Katalysatoren mit zwei Atomsorten weisen maximale Atomökonomie, einzigartige Strukturen und außergewöhnliche HER‐Aktivitäten auf. Die Wechselwirkungen zwischen wohldefinierten aktiven Zentren und Trägern beeinflussen die Elektronenübertragung und erhöhen die Reaktionsgeschwindigkeit beträchtlich. In diesem Aufsatz werden zunächst Methoden für die Untersuchung der aktiven atomaren Zentren bei der HER gezeigt. Danach werden aktive Zentren mit unterschiedlichen Koordinationsumgebungen vorgestellt. Aktive Zentren mit einem Metallatom, mit zwei unterschiedlichen Metallatomen und mit Nichtmetallatomen werden auf atomarer Ebene analysiert. Zum Schluss werden zukünftige Forschungsrichtungen vorgeschlagen.

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“…It is generally known that both the electrode materials and the separators play vital roles in achieving safe and high energy density batteries. Cathode materials with multi-electron charge transfer processes could deliver higher specific capacity and thus higher energy density [6,7,8]. Lithium sulfur batteries composed of lithium metal anode and sulfur cathode have been recognized as one of such battery systems due to their extremely high theoretical energy density (2600 Wh kg −1 , almost 7 times higher than that of typical layered oxide cathodes) [9,10].…”

Section: Introductionmentioning

confidence: 99%

MOF-Derived Co3O4 Polyhedrons as Efficient Polysulfides Barrier on Polyimide Separators for High Temperature Lithium–Sulfur Batteries

Zhou

Fang

et al. 2019

Nanomaterials

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The incorporation of highly polarized inorganic compounds in functional separators is expected to alleviate the high temperature safety- and performance-related issues for promising lithium–sulfur batteries. In this work, a unique Co3O4 polyhedral coating on thermal-stable polyimide (PI) separators was developed by a simple one-step low-temperature calcination method utilizing metal-organic framework (MOF) of Co-based zeolitic-imidazolate frameworks (ZIF-Co) precursors. The unique Co3O4 polyhedral structures possess several structural merits including small primary particle size, large pore size, rich grain boundary, and high ionic conductivity, which endow the ability to adequately adsorb dissolved polysulfides. The flexible-rigid lithium-lanthanum-zirconium oxide-poly(ethylene oxide) (LLZO-PEO) coating has been designed on another side of the polyimide non-woven membranes to inhibit the growth of lithium dendrites. As a result, the as-fabricated Co3O4/polyimide/LLZO-PEO (Co3O4/PI/LLZO) composite separators displayed fair dimensional stability, good mechanical strength, flame retardant properties, and excellent ionic conductivity. More encouragingly, the separator coating of Co3O4 polyhedrons endows Li–S cells with unprecedented high temperature properties (tested at 80 °C), including rate performance 620 mAh g−1 at 4.0 C and cycling stability of 800 mAh g−1 after 200 cycles—much better than the state-of-the-art results. This work will encourage more research on the separator engineering for high temperature operation.

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3D Honeycomb Architecture Enables a High‐Rate and Long‐Life Iron (III) Fluoride–Lithium Battery

Cited by 99 publications

References 50 publications

Designing Atomic Active Centers for Hydrogen Evolution Electrocatalysts

Designing Atomic Active Centers for Hydrogen Evolution Electrocatalysts

Design aktiver atomarer Zentren für HER‐Elektrokatalysatoren

MOF-Derived Co3O4 Polyhedrons as Efficient Polysulfides Barrier on Polyimide Separators for High Temperature Lithium–Sulfur Batteries

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