Exfoliated Graphene Oxide/MoO<sub>2</sub> Composites as Anode Materials in Lithium-Ion Batteries: An Insight into Intercalation of Li and Conversion Mechanism of MoO<sub>2</sub>

Petnikota, Shaikshavali; Teo, Keefe Wayne; Luo, Chen; Sim, Amos; Marka, Sandeep Kumar; Reddy, M. V.; Srikanth, Vadali V. S. S.; Adams, Stefan; Chowdari, B. V. R.

doi:10.1021/acsami.6b02049

Cited by 121 publications

(87 citation statements)

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“…The capacity of the pure MoO 2 particle baseline displays a continuous decrease to 356 mAh g −1 until the 17th cycle then gradually increase afterward, the capacity reaches to 470 mAh g −1 at the 100th cycle, which is consistent with MoO 2 with the size in microscale. [25,26] As we have already discussed above, the micrometer MoO 2 /GO also exhibits an induced activation process. The discharge capacity of the micrometer MoO 2 /GO decreases to 801 mAh g −1 at the 7th cycle then continuously increases to 901 mAh g −1 at the 100th cycle.…”

Section: Resultsmentioning

confidence: 70%

“…However, owing to graphene being liable to stack together, it is difficult to prepare well distributed graphene templated metal oxide architectures. The strategies, including solid-state graphenothermal reduction method, [25] microwave-assisted hydrothermal process, [26] and soft-templated hydrothermal method, [27] have been used to synthesize MoO 2 /C nanocomposites, exhibiting promising performance for LIBs. In our present …”

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confidence: 99%

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Constructing MoO₂ Porous Architectures Using Graphene Oxide Flexible Supports for Lithium Ion Battery Anodes

Yao

et al. 2017

Global Challenges

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the theoretical capacity of graphite electrodes is 372 mAh g −1 , resulted in an obstacle for their potential applications. The strategies to develop alternative anode materials with improved capacity have been achieved for several decades. [1][2][3][4][5][6][7][8] Among them, nanoscale metal oxides, including MnO, [9] SnO 2 , [10,11] Co 3 O 4 , [12] NiO, [13] and Fe 3 O 4 , [14,15] used as anode active materials for LIBs have been paid much attention attributed to their promising theoretical capacity. However, in most cases, the capacity decays rapidly as cycled due to high electrical resistivity and mechanism failure. [16] Molybdenum oxide (MoO 2 ) is different from other metal oxides. It possesses metallic conductivity (its electrical resistivity is 8.8 × 10 −5 Ω cm at 300 K in bulk sample), with a theoretical capacity as high as 836 mAh g −1 . [17] However, the capacity of bulk MoO 2 is low due to sluggish lithiation/delithiation kinetics. [17][18][19][20] On the other hand, the nanoporous structure constructed with lots of interconnect nanounits to form numbers of nanoscale pore provides adequate spaces for electrochemical reaction and connected pathways for ion diffusion. [21,22] The nano-MoO 2 porous structures have been synthesized by using mesoporous silica as hard templates, followed removing this hard templates by hydrofluoric acid, [23] or by a sulfur-assisted decomposition process. [24] The prepared MoO 2 porous materials have displayed improved capacity for LIBs. However, the capacity fade after charge/discharge process is attributed to the pure MoO 2 skeleton that will be possibly collapsed. The cycle stability needs to be improved further. It should be desired for the MoO 2 porous structure with flexible supports via retarding the pulverization from pure MoO 2 skeleton.Carbon nanomaterials, especially, graphene with large specific surface area and high toughness, are suitable for both substrates and supports for MoO 2 electrode active materials. However, owing to graphene being liable to stack together, it is difficult to prepare well distributed graphene templated metal oxide architectures. The strategies, including solid-state graphenothermal reduction method, [25] microwave-assisted hydrothermal process, [26] and soft-templated hydrothermal method, [27] have been used to synthesize MoO 2 /C nanocomposites, exhibiting promising performance for LIBs. In our present

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Section: Resultsmentioning

confidence: 70%

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confidence: 99%

Constructing MoO₂ Porous Architectures Using Graphene Oxide Flexible Supports for Lithium Ion Battery Anodes

Yao

et al. 2017

Global Challenges

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“…The voltage plateau originally seen at 1.2 V is no longer seen. The voltage drops slowly from 3 to 1 V, and then slopes downward till 0.02 V. Moreover, the initial discharge capacity of CuFeO 2 @rGO (985 mAh g −1 ) is remarkably higher than the theoretical capacity of CuFeO 2 (708 mAh g −1 ), which have been found in other metal oxides 12, 13, 32, 47, 57 . The higher initial discharge capacity may be ascribed to structural destruction upon Li insertion and decomposition of the solvent in the electrolyte, subsequent formation of large area solid electrolyte interphase (SEI) layer and nano Cu and Fe in Li 2 O matrix.…”

Section: Resultsmentioning

confidence: 83%

“…In addition, two well-resolved bands at 1360 and 1590 cm −1 for CuFeO 2 @rGO are attributed to the D band (k-point phonon of A 1 g symmetry) and G band (E 2 g phonon of carbon) of graphene, respectively. Compared with GO ( I D / I G = 0.86), the increased ratio of the D band to G band ( I D / I G = 0.97) in CuFeO 2 @rGO suggests the reduction of graphene, which can be ascribed to smaller but more numerous sp 2 domains in carbon 57 . Moreover, the presence of 2D band at 2694 cm −1 and (D + G) band at 2953 cm −1 in Fig.…”

Section: Resultsmentioning

confidence: 99%

Copper ferrites@reduced graphene oxide anode materials for advanced lithium storage applications

Wang

Deng

et al. 2017

Sci Rep

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Copper ferrites are emerging transition metal oxides that have potential applications in energy storage devices. However, it still lacks in-depth designing of copper ferrites based anode architectures with enhanced electroactivity for lithium-ion batteries. Here, we report a facile synthesis technology of copper ferrites anchored on reduced graphene oxide (CuFeO2@rGO and Cu/CuFe2O4@rGO) as the high-performance electrodes. In the resulting configuration, reduced graphene offers continuous conductive channels for electron/ion transfer and high specific surface area to accommodate the volume expansion of copper ferrites. Consequently, the sheet-on-sheet CuFeO2@rGO electrode exhibits a high reversible capacity (587 mAh g−1 after 100 cycles at 200 mA g−1). In particular, Cu/CuFe2O4@rGO hybrid, which combines the advantages of nano-copper and reduced graphene, manifests a significant enhancement in lithium storage properties. It reveals superior rate capability (723 mAh g−1 at 800 mA g−1; 560 mAh g−1 at 3200 mA g−1) and robust cycling capability (1102 mAh g−1 after 250 cycles at 800 mA g−1). This unique structure design provides a strategy for the development of multivalent metal oxides in lithium storage device applications.

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“…The values of various circuit elements shown in the corresponding equivalent circuits are furnished in Table 6 for LIBs and Table 7 for SIBs. The circuits shown contain electrolyte-electrode contact resistance R e , resistance due to surface film formation R sf , resistance to charge transfer R ct , bulk (substrate) resistance R b , capacitance components due to surface film formation CPE sf , double layer of charge formation CPE dl , bulk phase CPE b and ionic intercalation C i [31, 39–44]. In case of LIBs cycling, R sf and R ct values varied as 13 Pa < 30 Pa < 6 Pa whilst CPE dl value varied as 30 Pa < 6 Pa < 13 Pa.…”

Section: Resultsmentioning

confidence: 99%

Amorphous Vanadium Oxide Thin Films as Stable Performing Cathodes of Lithium and Sodium-Ion Batteries

et al. 2018

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Herein, we report additive- and binder-free pristine amorphous vanadium oxide (a-VOx) for Li- and Na-ion battery application. Thin films of a-VOx with a thickness of about 650 nm are grown onto stainless steel substrate from crystalline V2O5 target using pulsed laser deposition (PLD) technique. Under varying oxygen partial pressure (pO2) environment of 0, 6, 13 and 30 Pa, films bear O/V atomic ratios 0.76, 2.13, 2.25 and 2.0, respectively. The films deposited at 6‑30 Pa have a more atomic percentage of V5+ than that of V4+ with a tendency of later state increased as pO2 rises. Amorphous VOx films obtained at moderate pO2 levels are found superior to other counterparts for cathode application in Li- and Na-ion batteries with reversible capacities as high as 300 and 164 mAh g−1 at 0.1 C current rate, respectively. At the end of the 100th cycle, 90% capacity retention is noticed in both cases. The observed cycling trend suggests that more is the (V5+) stoichiometric nature of a-VOx better is the electrochemistry.Electronic supplementary materialThe online version of this article (10.1186/s11671-018-2766-0) contains supplementary material, which is available to authorized users.

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Exfoliated Graphene Oxide/MoO₂ Composites as Anode Materials in Lithium-Ion Batteries: An Insight into Intercalation of Li and Conversion Mechanism of MoO₂

Cited by 121 publications

References 46 publications

Constructing MoO₂ Porous Architectures Using Graphene Oxide Flexible Supports for Lithium Ion Battery Anodes

Constructing MoO₂ Porous Architectures Using Graphene Oxide Flexible Supports for Lithium Ion Battery Anodes

Copper ferrites@reduced graphene oxide anode materials for advanced lithium storage applications

Amorphous Vanadium Oxide Thin Films as Stable Performing Cathodes of Lithium and Sodium-Ion Batteries

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Exfoliated Graphene Oxide/MoO2 Composites as Anode Materials in Lithium-Ion Batteries: An Insight into Intercalation of Li and Conversion Mechanism of MoO2

Cited by 121 publications

References 46 publications

Constructing MoO2 Porous Architectures Using Graphene Oxide Flexible Supports for Lithium Ion Battery Anodes

Constructing MoO2 Porous Architectures Using Graphene Oxide Flexible Supports for Lithium Ion Battery Anodes

Copper ferrites@reduced graphene oxide anode materials for advanced lithium storage applications

Amorphous Vanadium Oxide Thin Films as Stable Performing Cathodes of Lithium and Sodium-Ion Batteries

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Product

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Exfoliated Graphene Oxide/MoO₂ Composites as Anode Materials in Lithium-Ion Batteries: An Insight into Intercalation of Li and Conversion Mechanism of MoO₂

Constructing MoO₂ Porous Architectures Using Graphene Oxide Flexible Supports for Lithium Ion Battery Anodes

Constructing MoO₂ Porous Architectures Using Graphene Oxide Flexible Supports for Lithium Ion Battery Anodes