Accelerated aging and degradation mechanism of LiFePO4/graphite batteries cycled at high discharge rates

Accelerated aging and degradation mechanism of LiFePO4/graphite batteries cycled at high discharge rates

The effects of discharge rates (0.5C, 1.0C, 2.0C, 3.0C, 4.0C and 5.0C) on the aging of LiFePO4/graphite full cells are researched by disassembling the fresh and aged full cells. The capacity degradation mechanism is analyzed via electrochemical performance, surface morphologies and compositions, and...

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Veröffentlicht in:RSC advances 2018-01, Vol.8 (45), p.25695-25703
Hauptverfasser: Sun, Shun, Guan, Ting, Cheng, Xinqun, Zuo, Pengjian, Gao, Yunzhi, Du, Chunyu, Yin, Geping
Format: Artikel
Sprache:eng
Schlagworte:
Aging
Anodes
Chemistry
Discharge
Dismantling
Electrochemical analysis
Electrodes
Graphite
High temperature
Lithium
Lithium ions
Morphology
Performance degradation
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container_end_page 25703
container_issue 45
container_start_page 25695
container_title RSC advances
container_volume 8
creator Sun, Shun
Guan, Ting
Cheng, Xinqun
Zuo, Pengjian
Gao, Yunzhi
Du, Chunyu
Yin, Geping
description The effects of discharge rates (0.5C, 1.0C, 2.0C, 3.0C, 4.0C and 5.0C) on the aging of LiFePO4/graphite full cells are researched by disassembling the fresh and aged full cells. The capacity degradation mechanism is analyzed via electrochemical performance, surface morphologies and compositions, and the structure of the anode and cathode electrodes. The capacity fade is accelerated with increasing discharge rates. The irreversible loss of active lithium due to the generation of an SEI film is the primary aging factor for the full cells cycled at low discharge rates. However, when the discharge rate is greater than or equal to 4.0C, the performance degradation of the LiFePO4 electrode is distinct due to structure decay, which is caused by quick and repeated intercalation of lithium ions and elevated temperature during discharging. In addition, the SEI film on the anode tends to be unstable after the rapid extraction of lithium ions at high discharge rates, and this enhances the loss of active lithium. Therefore, it is indicated that the degradation mechanism is changed for the full cells aged at 4.0C and 5.0C. Besides, the high discharge rate also increases the internal resistance of the full cell, which is detrimental to high rate discharge performance.
doi_str_mv 10.1039/c8ra04074e
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The capacity degradation mechanism is analyzed via electrochemical performance, surface morphologies and compositions, and the structure of the anode and cathode electrodes. The capacity fade is accelerated with increasing discharge rates. The irreversible loss of active lithium due to the generation of an SEI film is the primary aging factor for the full cells cycled at low discharge rates. However, when the discharge rate is greater than or equal to 4.0C, the performance degradation of the LiFePO4 electrode is distinct due to structure decay, which is caused by quick and repeated intercalation of lithium ions and elevated temperature during discharging. In addition, the SEI film on the anode tends to be unstable after the rapid extraction of lithium ions at high discharge rates, and this enhances the loss of active lithium. Therefore, it is indicated that the degradation mechanism is changed for the full cells aged at 4.0C and 5.0C. 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The capacity degradation mechanism is analyzed via electrochemical performance, surface morphologies and compositions, and the structure of the anode and cathode electrodes. The capacity fade is accelerated with increasing discharge rates. The irreversible loss of active lithium due to the generation of an SEI film is the primary aging factor for the full cells cycled at low discharge rates. However, when the discharge rate is greater than or equal to 4.0C, the performance degradation of the LiFePO4 electrode is distinct due to structure decay, which is caused by quick and repeated intercalation of lithium ions and elevated temperature during discharging. In addition, the SEI film on the anode tends to be unstable after the rapid extraction of lithium ions at high discharge rates, and this enhances the loss of active lithium. Therefore, it is indicated that the degradation mechanism is changed for the full cells aged at 4.0C and 5.0C. 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The capacity degradation mechanism is analyzed via electrochemical performance, surface morphologies and compositions, and the structure of the anode and cathode electrodes. The capacity fade is accelerated with increasing discharge rates. The irreversible loss of active lithium due to the generation of an SEI film is the primary aging factor for the full cells cycled at low discharge rates. However, when the discharge rate is greater than or equal to 4.0C, the performance degradation of the LiFePO4 electrode is distinct due to structure decay, which is caused by quick and repeated intercalation of lithium ions and elevated temperature during discharging. In addition, the SEI film on the anode tends to be unstable after the rapid extraction of lithium ions at high discharge rates, and this enhances the loss of active lithium. Therefore, it is indicated that the degradation mechanism is changed for the full cells aged at 4.0C and 5.0C. Besides, the high discharge rate also increases the internal resistance of the full cell, which is detrimental to high rate discharge performance.</abstract><cop>Cambridge</cop><pub>Royal Society of Chemistry</pub><pmid>35539816</pmid><doi>10.1039/c8ra04074e</doi><tpages>9</tpages><oa>free_for_read</oa></addata></record>
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subjects Aging
Anodes
Chemistry
Discharge
Dismantling
Electrochemical analysis
Electrodes
Graphite
High temperature
Lithium
Lithium ions
Morphology
Performance degradation
title Accelerated aging and degradation mechanism of LiFePO4/graphite batteries cycled at high discharge rates
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