2017
DOI: 10.1002/aenm.201701967
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Core–Shell Aluminum@Carbon Nanospheres for Dual‐Ion Batteries with Excellent Cycling Performance under High Rates

Abstract: In a typical DIB, graphite is not only used as the anode material but can also serve as the cathode due to its intrinsic redox amphoteric nature. Thus, both Li + cations and anions such as PF 6 − and BF 4 − can intercalate/deintercalate into/from the graphite layers during the charging and discharging processes. Researchers have continued to make progress in DIBs, including studies on the intercalation of different anions into graphite, different cathode materials (e.g., graphitic carbon, [6] metalorganic fra… Show more

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Cited by 95 publications
(57 citation statements)
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“…This integrated DIB exhibited superior long-term cycling stability with capacity retention about 61 % after 1500 cycles at high current rate of 60 C. The integrity of the porous structure of Al anode still maintained very well after long-term cycling without obvious Graphite 106 (at 1 C) ca. 4.2 1500 / 99% at 2 C 85 mAh g À1 at 10 C Carbon-coated Al nanospheres [114] Graphite 105 (at 2 C) 4.2 1000 / 89% at 2 C 100 mAh g À1 at 10 C (87 mAh g À1 at 20 C) pulverization, suggesting the effective volume change accommodation by the porous structure. Moreover, ultrafast charge/ discharge rate up to 120 C was achieved.…”
Section: Porous Structure Design and Carbon-coated Compositementioning
confidence: 99%
See 1 more Smart Citation
“…This integrated DIB exhibited superior long-term cycling stability with capacity retention about 61 % after 1500 cycles at high current rate of 60 C. The integrity of the porous structure of Al anode still maintained very well after long-term cycling without obvious Graphite 106 (at 1 C) ca. 4.2 1500 / 99% at 2 C 85 mAh g À1 at 10 C Carbon-coated Al nanospheres [114] Graphite 105 (at 2 C) 4.2 1000 / 89% at 2 C 100 mAh g À1 at 10 C (87 mAh g À1 at 20 C) pulverization, suggesting the effective volume change accommodation by the porous structure. Moreover, ultrafast charge/ discharge rate up to 120 C was achieved.…”
Section: Porous Structure Design and Carbon-coated Compositementioning
confidence: 99%
“…SEM morphologies of a) Al nanospheres (nAl), b) carboncoated Al nanospheres (nAl@C), c) HRTEM images of the nAl@C nanospheres, and d) Long-term cycling stability of the nAl@C-G DIB at a high current rate of 15 C for 1000 cycles. Reproduced from Ref [114]. with permission from WILEY-VCH, copyright 2018.…”
mentioning
confidence: 99%
“…The process is accomplished inside the cell electrochemically, so that there is no need to worry aboutt he handling of active potassium metal.T he same configuration is also applicable for sodium-ion-based dual-ion cells (Figure 8g). [96][97][98][99] Most recently,b enefiting from the dendrite-free properties and lower platingb arrier,aroom-temperature calcium-based dual-ion battery with tin as the alloy-type anode was first introduced (Figure 8i,j,k). It is known that lithium ions can alloy with aluminum at low po-tentials.T his makes aluminumb oth the current collector and anode material.…”
Section: Aluminummentioning
confidence: 99%
“…[95] Additionally,m odification of the aluminuma node, separator,o rc ell configuration can also enhancet he performance of aluminum-based dual-ion batteries;t his is beyond the scope of this review. [96][97][98][99] Most recently,b enefiting from the dendrite-free properties and lower platingb arrier,aroom-temperature calcium-based dual-ion battery with tin as the alloy-type anode was first introduced (Figure 8i,j,k). The dual-ion cell showed as pecific capacity of 70 mA h À1 g À1 at ac urrent density of 100 mA g À1 with ac ell voltage of 5V .T he electrolyte for this dual-ion battery was composed of two kinds of carbonates:c yclic carbonates that can dissolve CaPF 6 salts and linear carbonates that reduce the viscosity and increase the ionic conductivity.…”
Section: Aluminummentioning
confidence: 99%
“…Li et al presented a nanostructured rhodizonate salt (Na 2 C 6 O 6 ) as cathode material for Mg–organic battery in a dual‐salt electrolyte. The Mg‐storage behavior of the Mg–organic battery was based on the dual‐ion battery principle . The Mg–organic battery demonstrated a high discharge capacity of 400 mAh g −1 and an operating voltage of ≈2.2 V.…”
Section: Organic Materialsmentioning
confidence: 99%