Self-standing oxygen-deficient α-MoO3-x nanoflake arrays as 3D cathode for advanced all-solid-state thin film lithium batteries

“…Except for the methods mentioned above (building exible intercalation or using interface wetting agents) used to achieve good interface contact, some other approaches are also useful, such as using a lithiophilic intercalation layer, 90 reducing the surface tension of molten lithium, 61 or constructing an electrode with a 3D structure. 92,93 In particular, in situ polymerization should be given more attention. Lynden A. Archer used aluminium triate as an initiator to initiate open-loop polymerization of DOL.…”

Toward safer solid-state lithium metal batteries: a review

“…Except for the methods mentioned above (building exible intercalation or using interface wetting agents) used to achieve good interface contact, some other approaches are also useful, such as using a lithiophilic intercalation layer, 90 reducing the surface tension of molten lithium, 61 or constructing an electrode with a 3D structure. 92,93 In particular, in situ polymerization should be given more attention. Lynden A. Archer used aluminium triate as an initiator to initiate open-loop polymerization of DOL.…”

Toward safer solid-state lithium metal batteries: a review

“…Recently,S un et al reported the fabrication of vertically alignedo xygen-deficient a-MoO 3Àx nanoflake arrays (3D MO x ) as a3 Dc athode for all-solid-state Li-ion MBs. [13] The deposition employed direct current magnetron sputtering with aM o target. The 3D MO x MB wasa ssembled from the 3D MO x cathode, amorphous lithium phosphoruso xynitride solid electrolyte, andalithium thin-film anode (Figure 18 a).…”

“…As shown in Figure 1, the configuration of microelectronic devices has developed from linear,p lanar shapes to 3D architectures. [10] At the same time, many materials, such as variouse lementary substances, [11,12] oxides, [13][14][15] sulfides, [16][17][18] hydroxides, [19,20] and organic compounds, [21][22][23] with forms ranging from 0D to 3D, [24][25][26] have been investigatedf or both MB and MSC electrode purposes. Amongt hese, 2D materials attract considerable attention due to their uniquee lectrochemical and mechanical properties when applied in energy storage.…”

“…f) Rate capability andg)cycling performancea t 500 mA g À1 of the 3D MO x MB and 2D MO x MB. Reproduced with permission [13]. Copyright 2019, Elsevier.…”

Miniaturized Energy Storage Devices Based on Two‐Dimensional Materials

“…[2][3][4][5] For thin lm batteries energy and power density can be increased by achieving 3D-structured cathodes. 6,7 Additive manufactured microbatteries are a promising technology that can handle the integration problem into electronic devices and have the potential to reach high power at high energy density levels simultaneously. To achieve this, the principle idea of 3Dmanufactured batteries is to decouple ionic and electronic transport processes.…”

Towards 3D-lithium ion microbatteries based on silicon/graphite blend anodes using a dispenser printing technique