A Co‐Doped MnO<sub>2</sub> Catalyst for Li‐CO<sub>2</sub> Batteries with Low Overpotential and Ultrahigh Cyclability

Ge, Bingcheng; Sun, Yong; Guo, Jianxin; Yan, Xiaobing; Fernandez, Carlos; Peng, Qiuming

doi:10.1002/smll.201902220

Cited by 88 publications

(61 citation statements)

References 28 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Ge et al reported on Co-doped α-MnO 2 nanowires used as catalysts for Li-CO 2 batteries. [13] α-MnO 2 interstitial sites were successfully doped with Co, whose concentration directly impacted electronic conductivity where the bandgap was shortened and an impurity band was formed in α-MnO 2 . Enhanced electrical transport and optimized hierarchical channel structures enable Co-doped α-MnO 2 catalysts to exhibit a high capacity of 8160 mA h g −1 , a low overpotential of about 0.73 V, and long cycle life of >500 cycles at 100 mA g −1 .…”

Section: Enhancing Electrical Transportmentioning

confidence: 99%

Correlating Catalyst Design and Discharged Product to Reduce Overpotential in Li‐CO₂ Batteries

Dai

Amine

2021

Small

View full text Add to dashboard Cite

Li‐CO2 batteries with dual efficacy for greenhouse gas CO2 sequestration and high energy output have been regarded as a promising electrochemical energy storage technology. However, battery feasibility has been hampered by inferior electrochemical performance due to large overpotentials and low cyclability primarily caused by the difficult decomposition of ultra‐stable Li2CO3 during charge. The use of cathode catalysts has been highlighted as a promising solution and catalyst properties, as well as the nature of discharge products, are closely correlated with electrochemical performance. Here, the catalyst design strategies that include active site enrichment, electrical transport enhancement, and mass transfer improvement are summarized. Catalyst effects on product decomposition are then subsequently introduced, while product geometry and chemical composition will be explored, with an emphasis on the formation/decomposition of Li2C2O4 instead of Li2CO3. Building on previous research, future directions that facilitate improvements in catalyst design are put forward to reinforce the fundamental development of Li‐CO2 batteries.

show abstract

Section: Enhancing Electrical Transportmentioning

confidence: 99%

Correlating Catalyst Design and Discharged Product to Reduce Overpotential in Li‐CO₂ Batteries

Dai

Amine

2021

Small

View full text Add to dashboard Cite

show abstract

“…For the Lirich layered cathodes, EELS has been applied to investigate the injection of the oxygen vacancies into the bulk lattice, which is responsible for the layered-to-spinel phase transformation. [53b] Ex situ EELS has also been utilized to identify the transition products in the charge-discharge process of the metal-gas batteries, such as the Li-O 2 , [55] Li-CO 2 , [56] Na-CO 2 , [57] Li-CO 2 / O 2 , [58] Na-O 2 , [59] Na-N 2 , [60] etc. Combing the environmental TEM and the probe-type electrochemical solid-state open cell, Huang and co-workers conducted the first in situ TEM/EELS study of a Na-O 2 battery (Figure 6b).…”

Section: Intermediate State Characterizationsmentioning

confidence: 99%

Advanced Electron Energy Loss Spectroscopy for Battery Studies

Yin

Zhao

et al. 2021

Adv Funct Materials

View full text Add to dashboard Cite

As a powerful tool for chemical compositional analyses, electron energy loss spectroscopy (EELS) can reveal an abundance of information regarding the atomic-level electron state in a variety of materials, including the elemental types as well as their valence and concentration distributions, and the structure-related atom radial distribution. Benefiting from its unique capabilities and the newly developed advanced transmission electron microscope (TEM) configurations (i.e., in situ bias, in situ heating, cryo-TEM, etc.), EELS has facilitated the battery studies in various aspects. Here, a brief introduction of EELS is provided. Thereafter, a description of the recent progress in studying battery materials using EELS is provided, and finally a look ahead on the future development of EELS techniques and their applications in battery studies is provided.

show abstract

“…The superior performance of the Co/α-MnO 2 composite was ascribed to the Co interstitial doping (Figure 11b) and highly conductive hierarchical channels of the MnO 2 NW network. [105] A CNT-supported MnO 2 composite has also been demonstrated as an efficient cathode catalyst in Li-CO 2 cells. [106] The electrochemical performance of Li-CO 2 cells with the MnO 2 /CNT catalyst is comparable with other types of Mn-based catalysts.…”

Section: Nonprecious Transition Metal-based Catalystsmentioning

confidence: 99%

Recent Advances in Lithium–Carbon Dioxide Batteries

Manthiram

2020

Small Structures

View full text Add to dashboard Cite

Toward global sustainable development, lithium-carbon dioxide (Li-CO 2) batteries not only serve as an energy-storage technology but also represent a CO 2 capture system. Since the beginning of their research in this decade, Li-CO 2 batteries have attracted growing attention. However, Li-CO 2 batteries are still in their infancy and are facing many scientific and technological challenges. From a fundamental perspective, the reaction mechanism of CO 2 cathode is not yet clear enough. Technologically, the high overpotential, low power density, poor rate capability, and limited cycle life impede the development of Li-CO 2 batteries for practical applications. Herein, the recent research progress in Li-CO 2 batteries in terms of reaction mechanisms, cathode catalyst design, electrolyte management, and anode protection are first summarized. In light of the state-of-the-art research advances, future perspectives and research directions are then put forward, aiming to provide insightful information for the development of practical Li-CO 2 batteries.

show abstract

A Co‐Doped MnO₂ Catalyst for Li‐CO₂ Batteries with Low Overpotential and Ultrahigh Cyclability

Cited by 88 publications

References 28 publications

Correlating Catalyst Design and Discharged Product to Reduce Overpotential in Li‐CO₂ Batteries

Correlating Catalyst Design and Discharged Product to Reduce Overpotential in Li‐CO₂ Batteries

Advanced Electron Energy Loss Spectroscopy for Battery Studies

Recent Advances in Lithium–Carbon Dioxide Batteries

Contact Info

Product

Resources

About

A Co‐Doped MnO2 Catalyst for Li‐CO2 Batteries with Low Overpotential and Ultrahigh Cyclability

Cited by 88 publications

References 28 publications

Correlating Catalyst Design and Discharged Product to Reduce Overpotential in Li‐CO2 Batteries

Correlating Catalyst Design and Discharged Product to Reduce Overpotential in Li‐CO2 Batteries

Advanced Electron Energy Loss Spectroscopy for Battery Studies

Recent Advances in Lithium–Carbon Dioxide Batteries

Contact Info

Product

Resources

About

A Co‐Doped MnO₂ Catalyst for Li‐CO₂ Batteries with Low Overpotential and Ultrahigh Cyclability

Correlating Catalyst Design and Discharged Product to Reduce Overpotential in Li‐CO₂ Batteries

Correlating Catalyst Design and Discharged Product to Reduce Overpotential in Li‐CO₂ Batteries