2020
DOI: 10.1002/celc.202000272
|View full text |Cite
|
Sign up to set email alerts
|

Towards a High‐Performance Lithium‐Metal Battery with Glyme Solution and an Olivine Cathode

Abstract: High‐performance lithium‐metal batteries are achieved by using a glyme‐based electrolyte enhanced with a LiNO3 additive and a LiFePO4 cathode. An optimal electrolyte formulation is selected upon detailed analysis of the electrochemical properties of various solutions formed by dissolving respectively lithium bis(fluorosulfonyl)imide (LiFSI), lithium bis(trifluoromethanesulfonyl)imide (LiTFSI), and lithium bis(pentafluoroethanesulfonyl)imide (LiBETI) either in diethylene glycol dimethyl ether or in triethylene … Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
2
2
1

Citation Types

2
18
0

Year Published

2020
2020
2024
2024

Publication Types

Select...
8

Relationship

5
3

Authors

Journals

citations
Cited by 15 publications
(20 citation statements)
references
References 88 publications
2
18
0
Order By: Relevance
“…Based on these observations, we can attribute the (R(lf)Q(lf)) sub-circuit (large low-frequency semicircle in Figure 6g-j) to the cathode charge transfer resistance and double layer capacitance. Besides, we ascribe the (R(hf)iQ(hf)i) sub-circuit (i = 1, 2) mostly to the passivation layers over the electrodes [59][60][61]. Negligible contribution of the anode charge transfer, and double layer capacitance in the low-frequency region is expected, considering the relatively small semicircles observed in the Nyquist plots of Figure 4.…”
Section: Figurementioning
confidence: 82%
See 1 more Smart Citation
“…Based on these observations, we can attribute the (R(lf)Q(lf)) sub-circuit (large low-frequency semicircle in Figure 6g-j) to the cathode charge transfer resistance and double layer capacitance. Besides, we ascribe the (R(hf)iQ(hf)i) sub-circuit (i = 1, 2) mostly to the passivation layers over the electrodes [59][60][61]. Negligible contribution of the anode charge transfer, and double layer capacitance in the low-frequency region is expected, considering the relatively small semicircles observed in the Nyquist plots of Figure 4.…”
Section: Figurementioning
confidence: 82%
“…In detail, the (R(hf)iQ(hf)i) sub-circuit (i = 1, 2) reflects the response of the cell at high-medium frequency (herein briefly indicated as high-frequency region), occurring as a small semicircle in the Nyquist plots of Figure 6g-j, while the (R(lf)Q(lf)) sub-circuit describes the large semicircle at medium-low frequency (herein briefly indicated as low-frequency region). Further spectra of the NiO@C and NCM electrodes performed employing the additional lithium reference probe (Figure S3a, c, e, g, and i for Li/NiO@C side and Figure S3b, d, f, h, and j for Li/NMC side) suggest a characteristic low-frequency response for NiO@C and NCM, that is, a Warburg-type diffusion for the former and a slow charge transfer for the latter after the 1 st cycle, as well as an high-frequency region mostly reflecting the lithium passivation [59][60][61]. It is noteworthy that such a high charge transfer resistance at the cathode is in full agreement with the expected low Li + content in the NCM lattice in charged condition [59].…”
Section: Figurementioning
confidence: 99%
“… 58 Furthermore, a capacity excess at high voltages during the first cycle suggests the partial occurrence of the electrolyte decomposition with the deposition of a suitable SEI film, which protects the electrode surface. 59 Accordingly, the subsequent cycles reveal only the typical high voltage signature of the Ni 4+ /Ni 2+ redox pair, that is, around 4.7–4.8 V. 60 …”
Section: Resultsmentioning
confidence: 99%
“…The decrease of cell capacity and the appearance of the slope at the end of the (de)insertion processes of LiFePO 4 may be associated with an excessive growth of the SEI layer at the electrodes surface and possibly with gradual changes in cathode crystallite size distribution and surface free energies of the lithiated and delithiated phases, which lead to a change of the biphasic potential. 11 Instead, the cell employing TREGDME_HCE shows a capacity retention increasing from 94% of the previous test ( Figure 4 d) up to 97% ( Figure 5 d), while the corresponding voltage profiles reveal only a slight slope after 50 cycles without any sign of polarization increase or deterioration ( Figure 5 c). Therefore, we may suggest the additional reduction step at low voltage during the first cycle as an actual strategy to improve the performance of the lithium–metal cell using concentrated glyme-based electrolytes with the LFP electrode, particularly those having a longer ether chain such as TREGDME.…”
Section: Resultsmentioning
confidence: 77%