Jafar F. Al‐Sharab scite author profile

Near-theoretical utilization of high-energy-density CuF 2 positive electrode materials for lithium batteries was enabled through the use of nanocomposites consisting of 2-30 nm domains of CuF 2 within a mixed ionic + electronic conducting matrix of a metal oxide. Small but significant crystallographic changes to the core crystal of the CuF 2 were found to occur in all oxide-based matrices. These modifications to the core crystal and the surrounding matrix were investigated through a host of characterization methods, including XRD, XPS, and XAS. This new approach to the enablement of the anhydrous CuF 2 is distinctly superior in performance to that of macro CuF 2 or CuF 2 nanocomposites utilizing carbon as a matrix, the latter of which is also introduced herein for the first time.

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Coordination Geometry and Oxidation State Requirements of Corner-Sharing MnO₆ Octahedra for Water Oxidation Catalysis: An Investigation of Manganite (γ-MnOOH)

Smith

et al. 2016

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Surface-directed corner-sharing MnO 6 octahedra within numerous manganese oxide compounds containing Mn 3+ or Mn 4+ oxidation states show strikingly different catalytic activities for water oxidation, paradoxically poorest for Mn 4+ oxides, regardless of oxidation assay (photochemical and electrochemical). This is demonstrated herein by comparing crystalline oxides consisting of Mn 3+ (manganite, γ-MnOOH; bixbyite, Mn 2 O 3 ), Mn 4+ (pyrolusite, β-MnO 2 ) and multiple monophasic mixed-valence manganese oxides. Like all Mn 4+ oxides, pure β-MnO 2 has no detectable catalytic activity, while γ-MnOOH (tetragonally distorted Mn 3+ O 6 , D 4h symmetry) is significantly more active and Mn 2 O 3 (trigonal antiprismatic Mn 3+ O 6 , D 3d symmetry) is the most active. γ-MnOOH deactivates during catalytic turnover simultaneous with the disappearance of crystallographically defined corner-sharing Mn 3+ O 6 and the appearance of Mn 4+ . In a comparison of 2D-layered crystalline birnessites (δ-MnO 2 ), the monovalent Mn 4+ form is catalytically inert, while the hexagonal polymorph, containing few out-of-layer corner-sharing Mn 3+ O 6 , has ∼10-fold higher catalytic activity than the triclinic polymorph, containing in-plane edge-sharing Mn 3+ O 6 . These electronic and structural correlations point toward the more flexible (corner-shared) Mn 3+ O 6 sites, over more rigid (edge-shared) sites as substantially more active catalytic centers. Electrochemical measurements show and ligand field theory predicts that, among corner-shared Mn 3+ O 6 sites, those possessing D 3d ligand field symmetry have stronger covalent Mn−O bonding to the six equivalent oxygen ligands, which we ascribe as responsible for more efficient and faster electrolytic water oxidation. In contrast, D 4h Mn 3+ O 6 sites have weaker Mn−O bonding to the two axial oxygen ligands, have separated electrochemical oxidation waves for Mn and O, and are catalytically less efficient and exhibit slower catalytic turnover. By controlling the ligand field geometry and strength to oxygen ligands, we have identified the key variables for tuning water oxidation activity by manganese oxides. We apply these findings to propose a mechanism for water oxidation by the CaMn 4 O 5 catalytic site of natural photosynthesis.

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Edge‐Plane‐Rich Nitrogen‐Doped Carbon Nanoneedles and Efficient Metal‐Free Electrocatalysts

2012

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CNN news: N-doped carbon nanoneedles (CNNs) are synthesized by self-assembling core-shell nanostructures and nanoreactors around cellulose nanoneedles, and subsequent graphitization. The resulting graphitic nanoneedles (see picture) have well-organized graphitic multi-layers and large proportions of N-doped edge planes. The materials serve as efficient metal-free electrocatalysts for hydrazine oxidation.

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Investigation of the Lithiation and Delithiation Conversion Mechanisms of Bismuth Fluoride Nanocomposites

Bervas

Mansour

Yoon

et al. 2006

J. Electrochem. Soc.

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Combined in situ X-ray diffraction, in situ X-ray absorption spectroscopy, and selected area electron diffraction analyses have confirmed the occurrence of a reversible conversion reaction in the BiF 3 /C nanocomposite upon cycling, which leads to the formation of Bi 0 and LiF during lithiation and the reformation of BiF 3 during delithiation. It has been shown that only the high-pressure tysonite phase of BiF 3 reforms during the oxidation sweep and that no bismuth fluoride compound with an oxidation state of the bismuth lower than 3 is formed as intermediate during the lithiation or delithiation reactions. Finally, it has been demonstrated that the different plateaus or pseudo plateaus observed on the lithiation and delithiation voltage profiles stem from polarization changes brought about by the dramatic structural changes occurring in the nanocomposite upon cycling. A model, based on the variation of the electronic and ionic transport mechanisms as a function of the state of completion of the conversion and reconversion reactions, is proposed to explain those polarization changes.Conversion reactions are lithiation reactions in which the active material is fully reduced by lithium to the metal according to the following equationwhere M stands for a cation and X an anion. As all the oxidation states of the material are utilized, capacities much higher than in the intercalation reactions currently used in rechargeable Li-ion batteries can in theory be obtained, thereby leading to much higher energy densities.Conversion reactions have been known for a long time in primary battery applications with, for instance, the Li/CuO and Li/CF x systems that are still utilized today. 1 Due to the highly destructive nature of the reaction, which literally involves the breaking of chemical bonds and the formation of new ones, it has long been thought that such reactions were irreversible. To the best of our knowledge, Besenhard was the first to report the electrochemical reversibility of a conversion reaction in 1978 2 in a paper on bismuth chalcogenides. In this paper, it was shown that Bi 2 S 3 was reduced into Bi 0 and Li 2 S during lithiation and was reoxidized with 75% efficiency during the following delithiation; but this reversibility was observed for one cycle only. Selwyn et al. reported in 1987 that the conversion reactions occurring in Mo and W dichalcogenides exhibited some electrochemical reversibility but did not clearly identify the compound͑s͒ formed during the delithiation. 3 The possibility to have full electrochemical and structural reversibility in conversion reactions of dichalcogenides during charge has been proven for the first time only about 5 years ago by Tarascon's group. 4 They reported specific capacities as high as 700 mAh/g and full reversibility for several tenth of cycles when different transition metal oxides 4 and sulfides 5 were used as negative electrode or lowvoltage positive electrodes.As the output voltage of a conversion reaction scales with the ionicity of the M-X bond, metal nitride...

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Jafar F. Al‐Sharab

Structure and Electrochemistry of Copper Fluoride Nanocomposites Utilizing Mixed Conducting Matrices

Coordination Geometry and Oxidation State Requirements of Corner-Sharing MnO₆ Octahedra for Water Oxidation Catalysis: An Investigation of Manganite (γ-MnOOH)

Edge‐Plane‐Rich Nitrogen‐Doped Carbon Nanoneedles and Efficient Metal‐Free Electrocatalysts

Investigation of the Lithiation and Delithiation Conversion Mechanisms of Bismuth Fluoride Nanocomposites

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Jafar F. Al‐Sharab

Structure and Electrochemistry of Copper Fluoride Nanocomposites Utilizing Mixed Conducting Matrices

Coordination Geometry and Oxidation State Requirements of Corner-Sharing MnO6 Octahedra for Water Oxidation Catalysis: An Investigation of Manganite (γ-MnOOH)

Edge‐Plane‐Rich Nitrogen‐Doped Carbon Nanoneedles and Efficient Metal‐Free Electrocatalysts

Investigation of the Lithiation and Delithiation Conversion Mechanisms of Bismuth Fluoride Nanocomposites

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Coordination Geometry and Oxidation State Requirements of Corner-Sharing MnO₆ Octahedra for Water Oxidation Catalysis: An Investigation of Manganite (γ-MnOOH)