O-Glycosidic bond exocyclic cleavage of difructose led by acidic proton migration: Density functional theory calculation study

Chen, Po‐Tuan; Chan, Tzu-Hsin; Wang, Juen–Kai; Wang, Yuh‐Lin; Hayashi, M.

doi:10.1016/j.cplett.2012.08.033

Cited by 3 publications

(2 citation statements)

References 28 publications

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“…[12,13] A temperature rise induces cell degradation as well as electrolyte vaporization and cell expansion, which may result in possible safety issues. [12,13] A temperature rise induces cell degradation as well as electrolyte vaporization and cell expansion, which may result in possible safety issues.…”

Section: Reviving Aged Lithium-ion Batteries and Prolonging Their Cycmentioning

confidence: 99%

“…Suppressing temperature rises during charging is a major concern for the utilization of Li-ion batteries. [12,13] A temperature rise induces cell degradation as well as electrolyte vaporization and cell expansion, which may result in possible safety issues. As listed in Table 1, using the CCÀCV method results in a maximum temperature rise of 15 8C, whereas using the sinusoidal waveform charging strategy engenders a temperature rise of 9 8C.…”

Section: Reviving Aged Lithium-ion Batteries and Prolonging Their Cycmentioning

confidence: 99%

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Reviving Aged Lithium‐Ion Batteries and Prolonging their Cycle Life by Sinusoidal Waveform Charging Strategy

Chen

Yang

Cao

et al. 2019

Batteries & Supercaps

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Traditional high power constant current-constant voltage (CCÀCV) charging leads to the degradation of Li-ion batteries. Thus, aging due to charging is a primary issue to be overcome in application technology. This study proposes the impacts of a sinusoidal waveform charging strategy for charging Li-ion batteries. Specifically, a negative voltage is introduced in the charging process to reverse passivation layer formation. After few cycles of sinusoidal waveform charging, aged cells can be revived. Tests reveal that the available capacity of an aged cell can be improved by a maximum of 18.7 % relative to the original rated power. After 600 charging-discharging cycles of new cells, the cells charged using the sinusoidal waveform strategy possess approximately 15 % more electrical capacity than do cells charged using the conventional CCÀCV method, indicating an increase in battery cycle life. The suppression of interfacial resistance is characterized by electrochemical impedance spectroscopy. Sinusoidal waveform charging can reduce charging time by half and the maximum rise in temperature by 6 8C compared with the CCÀCV charging method.The rapid increase in the use of commercial Li-ion batteries in portable electronic devices and, more recently, electric vehicles and energy storage systems has engendered an urgent demand for considerable battery performance enhancement. Battery degradation is the primary limitation of Li-ion batteries used in the aforementioned applications. A major factor in battery degradation is the continuous passivation of solid electrolyte interphases (SEIs). [1] An SEI consists of solid Li complexes that are created due to the combination of Li ions and decomposed electrolyte with excess electrons attributed to charging. [2] Constant high-power charging was suggested to accelerate aging. [3] Therefore, considerable engineering efforts have been undertaken to stabilize the SEI over time. The development of charging methods would ensure that capacity loss would not be severe in the short term and enable long-term Li-ion battery utilization. Among constant-trickle-current charging, constantcurrent (CC) charging, and CC-constant-voltage (CCÀCV) charging methods, [4] CCÀCV is most extensively used. CCÀCV charging involves charging a battery at a CC until its voltage reaches the predetermined limit, followed by CV charging until the current decreases to a predetermined low value. However, SEI formation can occur near the end of the CC-charging step during normal CCÀCV charging if the charging current rate reaches or exceeds a certain value. [5] Thus, the charging performance of the CCÀCV method cannot sufficiently satisfy the long-cycle-life requirement of the consumer. The development of charging methods that balance battery degradation and fast charging remains a challenge.Reflex charging method applies a very short discharging pulse during pulse charging and resting periods. Because passivation layers in different types of batteries are grown mainly via reduction reaction, the discharging pulse ...

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Section: Reviving Aged Lithium-ion Batteries and Prolonging Their Cycmentioning

confidence: 99%

Section: Reviving Aged Lithium-ion Batteries and Prolonging Their Cycmentioning

confidence: 99%

Reviving Aged Lithium‐Ion Batteries and Prolonging their Cycle Life by Sinusoidal Waveform Charging Strategy

Chen

Yang

Cao

et al. 2019

Batteries & Supercaps

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Moderate Energy for Charging Li‐Ion Batteries Determined by First‐Principles Calculations

Chen

Yang

Sangeetha

et al. 2018

Batteries & Supercaps

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Charging methods that were employed earlier provided constant energy to a battery, but the negative impact was the activation of chemical reactions that lead to battery passivation. Thus, in order to mitigate the battery aging, moderate energy for charging a lithium‐ion battery has been theoretically calculated using density functional theory. The charging process was associated with a Li‐ion transfer model between two electrodes. When charging, Li‐ions from the positive electrode, pass through a separator/electrolyte, transfer via a solid electrolyte interface (SEI), and intercalate into the negative electrode. Calculations provided activation energies of migration through the SEI and intercalation of graphite. The inverse reaction of electrolyte reduction was introduced in the process to prevent impedance formation. The unit of power of the external charger can be converted to voltage. Therefore, the proposed novel charging strategy used positive voltage for migration and negative voltage for the inverse reaction of reduction. The charging strategy can be approximated to a sinusoidal waveform, which is effective in reviving Li‐ion battery and prolonging the cycle life.

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Improved performance of a Zn-air fuel cell by coupling Zn particle fuel and flowing electrolyte

Chen

Sangeetha

Hsu

et al. 2019

Chemical Physics Letters

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O-Glycosidic bond exocyclic cleavage of difructose led by acidic proton migration: Density functional theory calculation study

Cited by 3 publications

References 28 publications

Reviving Aged Lithium‐Ion Batteries and Prolonging their Cycle Life by Sinusoidal Waveform Charging Strategy

Reviving Aged Lithium‐Ion Batteries and Prolonging their Cycle Life by Sinusoidal Waveform Charging Strategy

Moderate Energy for Charging Li‐Ion Batteries Determined by First‐Principles Calculations

Improved performance of a Zn-air fuel cell by coupling Zn particle fuel and flowing electrolyte

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