Biotemplating pores with size and shape diversity for Li-oxygen Battery Cathodes

Oh, Dahyun; Özgit-Akgün, Çaǧla; Akca, Esin; Thompson, Leslie E.; Tadesse, Loza F.; Kim, Ho-Cheol; Demirci, Gökhan; Miller, Robert D.; Maune, Hareem

doi:10.1038/srep45919

Cited by 25 publications

(6 citation statements)

References 37 publications

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“…C 1s spectra were separated into four peaks corresponding to the C–C, C–OH, CO, and C–N bands, respectively. The functional oxygen group is associated with the carbonization of the organic polymer, which will increase the surface wettability of the electrode . The N 1s spectrum can be deconvolved into three peaks, including pyridinic N, pyrrolic N, and graphic N (Figure e).…”

Section: Resultsmentioning

confidence: 99%

“…The functional oxygen group is associated with the carbonization of the organic polymer, which will increase the surface wettability of the electrode. 39 The N 1s spectrum can be deconvolved into three peaks, including pyridinic N, pyrrolic N, and graphic N (Figure 3e). The majority of the pyridine N peak suggests that the N element not only contributes to the Fe 2 N phase but also ensures N-doping in the carbon substrate for the CSHN sample.…”

Section: Resultsmentioning

confidence: 99%

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Iron Nitride@C Nanocubes Inside Core–Shell Fibers to Realize High Air-Stability, Ultralong Life, and Superior Lithium/Sodium Storages

Deng

Wang

et al. 2021

ACS Appl. Mater. Interfaces

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Poor air stability and severe structure pulverization are crucial issues for metal nitrides in metal-ion batteries. Herein, core–shell hybrid fibers (CSHN fiber) filled with metal nitride@C hollow nanocubes are introduced to be a new self-supporting anode for sodium-ion and lithium-ion batteries. The hierarchical carbon network provides fast electronic pathways and gives high protection for iron nitrides. Meanwhile, the self-supporting electrode avoids the complicated electrode fabrication process and decreases the opportunity to air exposure. Moreover, its porous nature ensures high buffer to volumetric expansion and improves the cycling stability. Therefore, it is a good platform to realize fast kinetics and high durability. For the first time, Fe2N@N-doped carbon CSHN hybrid fibers are constructed. Their influences on air stability and electrochemical behaviors are studied. Impressively, they achieve high stabilities in both lithium-ion (92.8%, at 5 A g–1, 1000 cycles) and sodium-ion (95.6%, at 2 A g–1, 2000 cycles) batteries. Therefore, this work introduces a new method to construct superior performance nitride anodes. Moreover, it also provides a new insight on the fabrication of highly efficient structures for diverse functional materials.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Iron Nitride@C Nanocubes Inside Core–Shell Fibers to Realize High Air-Stability, Ultralong Life, and Superior Lithium/Sodium Storages

Deng

Wang

et al. 2021

ACS Appl. Mater. Interfaces

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“…To address these constraints, new approaches to produce micron-scale porous structures with more efficient integration of active materials, conductivity enhancers, and binders have been proposed. For example, template-assisted methods offer excellent control over pore size and morphology but fabricating and then removing the fine-scale featured sacrificial templates can cause problems for cost and scalability and volumetric capacity tends to be unhelpfully low. − Lithographic technologies based on ultraviolet light irradiation and/or ion etching processes allow pore fraction, shape, and alignment to be controlled with micron resolution but require inherently high-cost fabrication apparatus. − Thus, there remains an opportunity for manufacturing approaches that allow improved and more flexible micron-scale pore engineering in LIB electrodes and that have the potential for cost-effective scalability.…”

Section: Introductionmentioning

confidence: 99%

Spray-Printed and Self-Assembled Honeycomb Electrodes of Silicon-Decorated Carbon Nanofibers for Li-Ion Batteries

Lee

Huang

et al. 2018

ACS Appl. Mater. Interfaces

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Directional, micron-scale honeycomb pores in Li-ion battery electrodes were fabricated using a layer-by-layer, self-assembly approach based on spray-printing of carbon nanofibers. By controlling the drying behavior of each printed electrode layer through optimization of (i) the volume ratio of fugitive bisolvent carriers in the suspension and (ii) the substrate temperature during printing, self-assembled, honeycomb pore channels through the electrode were created spontaneously and reliably on current collector areas larger than 20 cm × 15 cm. The honeycomb pore structure promoted efficient Li-ion dynamics at high charge/discharge current densities. Incorporating an optimum fraction (2.5 wt %) of high-energy-density Si particulate into the honeycomb electrodes provided a 4-fold increase in deliverable discharge capacity at 8000 mA/g. The spray-printed, honeycomb pore electrodes were then investigated as negative electrodes coupled with similar spray-printed LiFePO4 positive electrodes in a full Li-ion cell configuration, providing an approximately 50% improvement in rate capacity retention over half-cell configurations of identical electrodes at 4000 mA/g.

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“…Although the effect of macropores in electrodes on electrochemical performance has not been clear yet, the proposed pore size of 200-300 nm is in good agreement with previous studies of porous electrodes for Li-O 2 batteries as a representative of submicron-scale pore sizes. [23,29,30] Furthermore, the 3D nanostructured electrode can realize superhydrophobic surface properties by a nanometer-scale surface morphology not seen with Cu foam electrodes. In Table S1 (Supporting Information), the contact angle between the liquid/air/electrode was measured with deionized (DI) water and the electrolyte.…”

Section: Electrochemical Analysis Of Copper Electrodes With Different...mentioning

confidence: 99%

Unraveling the Significance of Li⁺/e⁻/O₂ Phase Boundaries with a 3D‐Patterned Cu Electrode for Li–O₂ Batteries

Hyun

Park

Bae

et al. 2023

Adv Funct Materials

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The reaction kinetics at a triple‐phase boundary (TPB) involving Li+, e−, and O2 dominate their electrochemical performances in Li–O2 batteries. Early studies on catalytic activities at Li+/e−/O2 interfaces have enabled great progress in energy efficiency; however, localized TPBs within the cathode hamper innovations in battery performance toward commercialization. Here, the effects of homogenized TPBs on the reaction kinetics in air cathodes with structurally designed pore networks in terms of pore size, interconnectivity, and orderliness are explored. The diffusion fluxes of reactants are visualized by modeling, and the simulated map reveals evenly distributed reaction areas within the periodic open structure. The 3D air cathode provides highly active, homogeneous TPBs over a real electrode scale, thus simultaneously achieving large discharge capacity, unprecedented energy efficiency, and long cyclability via mechanical/electrochemical stress relaxation. Homogeneous TPBs by cathode structural engineering provide a new strategy for improving the reaction kinetics beyond controlling the intrinsic properties of the materials.

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Biotemplating pores with size and shape diversity for Li-oxygen Battery Cathodes

Cited by 25 publications

References 37 publications

Iron Nitride@C Nanocubes Inside Core–Shell Fibers to Realize High Air-Stability, Ultralong Life, and Superior Lithium/Sodium Storages

Iron Nitride@C Nanocubes Inside Core–Shell Fibers to Realize High Air-Stability, Ultralong Life, and Superior Lithium/Sodium Storages

Spray-Printed and Self-Assembled Honeycomb Electrodes of Silicon-Decorated Carbon Nanofibers for Li-Ion Batteries

Unraveling the Significance of Li⁺/e⁻/O₂ Phase Boundaries with a 3D‐Patterned Cu Electrode for Li–O₂ Batteries

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Biotemplating pores with size and shape diversity for Li-oxygen Battery Cathodes

Cited by 25 publications

References 37 publications

Iron Nitride@C Nanocubes Inside Core–Shell Fibers to Realize High Air-Stability, Ultralong Life, and Superior Lithium/Sodium Storages

Iron Nitride@C Nanocubes Inside Core–Shell Fibers to Realize High Air-Stability, Ultralong Life, and Superior Lithium/Sodium Storages

Spray-Printed and Self-Assembled Honeycomb Electrodes of Silicon-Decorated Carbon Nanofibers for Li-Ion Batteries

Unraveling the Significance of Li+/e−/O2 Phase Boundaries with a 3D‐Patterned Cu Electrode for Li–O2 Batteries

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Product

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Unraveling the Significance of Li⁺/e⁻/O₂ Phase Boundaries with a 3D‐Patterned Cu Electrode for Li–O₂ Batteries