Designing the Charge Storage Properties of Li‐Exchanged Sodium Vanadium Fluorophosphate for Powering Implantable Biomedical Devices

Lai, Chun‐Han; Ashby, David S.; Bashian, Nicholas H.; Schoiber, Jürgen; Liu, Ta Chung; Lee, Glenn S.; Chen, San‐Yuan; Wu, Pu Wei; Melot, Brent C.; Dunn, Bruce

doi:10.1002/aenm.201900226

Cited by 23 publications

(16 citation statements)

References 46 publications

(91 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In Na 1.5 VOPO 4 F 0.5 system, (a) Rate performance of with different size of particle and (b) in situ XRD results of micronbrick and nanoparticle. 350 (c) in situ XRD measurement result of 40 nm particle size of LiFePO 4 during galvanostatic charge/discharge at C/40. 351 It shows solid solution structural variation.…”

Section: Fig 28mentioning

confidence: 99%

“…host material for Na 350,355 and K 356 ) are also applied. In the case of Na 1.5 VOPO 4 F 0.5 system, for example, Lai et al 350 reported that among the various particle sizes including micronbrick, nanobrick, and nanoparticle, the smallest nanoparticle expectedly delivers superior rate performance with high capacity (Fig. 28a).…”

Section: Fig 28mentioning

confidence: 99%

“…28b). 350 The micro-scale stress within the particles, which can be originated from the local ion concentration gradient change, is also a performance degradation factor similar to intergranular crack, 339 therefore, solid solution behavior can lessen the cyclic mechanical damages because it can avoid spatial heterogeneities. However, not all the materials show enhanced battery performance by lowering particle sizes, and to fully take advantages, several prerequisites have to be met, e.g., the particles must be in good contact through an effective connection network within the electrode, 224,360,361 side reactions should be inconspicuous or mitigated via adequate engineering, etc.…”

Section: Fig 28mentioning

confidence: 99%

See 2 more Smart Citations

Multiscale factors in designing alkali-ion (Li, Na, and K) transition metal inorganic compounds for next-generation rechargeable batteries

Lee

Kim

Yun

et al. 2020

Energy Environ. Sci.

View full text Add to dashboard Cite

show abstract

Section: Fig 28mentioning

confidence: 99%

Section: Fig 28mentioning

confidence: 99%

Section: Fig 28mentioning

confidence: 99%

See 1 more Smart Citation

Multiscale factors in designing alkali-ion (Li, Na, and K) transition metal inorganic compounds for next-generation rechargeable batteries

Lee

Kim

Yun

et al. 2020

Energy Environ. Sci.

View full text Add to dashboard Cite

show abstract

“…As far as powering capability is concerned, MB for implantable bioelectronics is generally in pursuit of high volumetric energy density and stable cycling life, thus material design with biocompatibility being the key part. Recently, Dunn and co-workers [161] reported a promising cathode material with a mixed battery/capacitor electrochemical behavior. By anchoring Na 1.5 VOPO 4 F 0.5 on rGO, the cathode composed by nanoparticles exhibited a solid solution process during the charge storage behavior.…”

Section: Microbattery With Biocompatibilitymentioning

confidence: 99%

“…When the biocompatibility is concerned, an MTS assay is just a validation process while a living body implantation is needed to further Reproduced with permission. [161] Copyright 2019, Wiley-VCH. c) Schematic illustrations of MB implanted in the dorsal subcutaneous region of the SD rat.…”

Section: Microbattery With Biocompatibilitymentioning

confidence: 99%

Recent Advances in High‐Performance Microbatteries: Construction, Application, and Perspective

Zhu

Kan

et al. 2020

Small

View full text Add to dashboard Cite

considered indispensable and stimulate great upsurge in interest on relevant researches. [1-4] Through integrating with multiple functional materials or devices, the miniaturized energy-storage device can power functional systems, such as microactuators, implantable biosensors, and wearable gadgets. [5,6] As far as the performance is concerned, the shift from disposable or nonrechargeable product to a high-energy output device or even complicated system has motivated the improvement of energy storage capability during the past decade. Generally, microsupercapacitor (MSC) possesses the advantages of fast charge/discharge rate and long cycling lifetime, making it possible for some maintenance-free wearable microelectronics and biomedical devices. [7,8] However, the energy storage gap about an order of magnitude still exists in comparison with microbattery (MB), and the insufficient energy supply restricts the widespread applications of MSC in the main power systems. [9] Serving as the primary choice for powering advanced miniaturized devices, MBs ensure sufficient energy density and maintain a stable voltage output. In general, a rechargeable battery consists of cathode, anode, and electrolyte in between, therefore it is the electrode that calls for miniaturization in size ranging from microns to centimeters. The total energy available in a MB generally depends on the active materials loaded on a certain small area. Based on this, some concepts of MB have been proposed, such as ultrathin microelectrode for high volumetric specific energy and somewhat thick microelectrode for high areal specific energy. [10,11] In terms of the dimensional ratio of MB, the thickness of microelectrode gives priority to the transport distance of ions and electrons, thus favoring the improvement in power density when compared with the macro one. [12,13] The decisive factor for the performance of MB is the reaction mechanism, and multiple battery forms have been expanded into miniaturized power supply as the supplement. Among the MBs mainly represented by lithium-ion batteries (LIBs) with organic electrolyte, various alkali metal ion batteries with abundant resources have been explored for possible substitution of lithium. [14-16] From the perspective of intrinsic safety, aqueous batteries have been developed with the merits of both inexpensive electrolyte and relatively higher power density. [17] Additionally, air batteries derived from fuel cells and ideally comprised of infinite O 2 supply for cathode reaction High-performance miniaturized energy storage devices have developed rapidly in recent years. Different from conventional energy storage devices, microbatteries assume the main responsibility for micropower supply, functionalization, and characterization platforms. Evolving from the essential goals for battery design of high power density, high energy density, and long lifetime, further practical demands for microbatteries (MBs) have been raised for the microfabrication technique and device design. Numerous studies have generally...

show abstract

Localized Electron Density Redistribution in Fluorophosphate Cathode: Dangling Anion Regulation and Enhanced Na‐Ion Diffusivity for Sodium‐Ion Batteries

Wang

Kang

et al. 2021

Adv Funct Materials

View full text Add to dashboard Cite

Polyanionic transition metal polyphosphate (TMPO)-type Na 3 V 2 (PO 4 ) 2 O 2 F (NVPO 2 F) is promising as cathode for large-scale sodium-ion batteries (SIBs) on account of its considerable capacity and highly stable structure. However, the redox of transition metal and phase transitions along with the (de) intercalation of Na + lead to its slow kinetics and inferior rate performance. Herein, chlorine (Cl) is applied as a heteropical dopant to obtain Cl-doped NVPO 2 F (NVPO 2−x Cl x F) cathode material for SIBs. Density functional theory investigation reveals that Cl doping tunes the localized electronic density and structure in NVPO 2 F lattice, causing the electron redistribution on vanadium center and dangling anions. Hence, the NVPO 2−x Cl x F cathode exhibits a revised redox behavior of vanadium for Na + extraction/insertion, increases Na + diffusion rate, as well as lowers charge transfer resistance. A Na + storage mechanism of reversible transformations between three phases and V 4+ /V 5+ redox couple for NVPO 2−x Cl x F cathode is verified. The NVPO 2−x Cl x F cathode reveals a high rate capacity of ≈63 mAh g −1 at 30C and great cycle stability over 1000 cycles at 10C. More importantly, outstanding rate property (314 Wh kg −1 at 5850 W kg −1 ) and cycling capability are obtained for the NVPO 2−x Cl x F//3DC@Se full cell. This study demonstrates a brand-new strategy to prepare advanced cathode materials for superior SIBs.

show abstract

Designing the Charge Storage Properties of Li‐Exchanged Sodium Vanadium Fluorophosphate for Powering Implantable Biomedical Devices

Cited by 23 publications

References 46 publications

Multiscale factors in designing alkali-ion (Li, Na, and K) transition metal inorganic compounds for next-generation rechargeable batteries

Multiscale factors in designing alkali-ion (Li, Na, and K) transition metal inorganic compounds for next-generation rechargeable batteries

Recent Advances in High‐Performance Microbatteries: Construction, Application, and Perspective

Localized Electron Density Redistribution in Fluorophosphate Cathode: Dangling Anion Regulation and Enhanced Na‐Ion Diffusivity for Sodium‐Ion Batteries

Contact Info

Product

Resources

About