Search citation statements

Order By: Relevance

Paper Sections

Select...
2
1
1

Citation Types

4
281
0
1

Year Published

2013
2013
2020
2020

Publication Types

Select...
5
3

Relationship

0
8

Authors

Journals

citations
Cited by 468 publications
(286 citation statements)
references
References 31 publications
4
281
0
1
Order By: Relevance
“…Alternatively, significant effort has been devoted to coating the LFP surfaces with electrically conductive materials, such as amorphous carbon and conducting polymers to ARTICLE enhance the electrical conductivity of LFP surfaces [27][28][29][30][31][32] . Recent studies have adopted rGO or GO to cover the LFP surfaces [16][17][18][19] . However, studies so far have only shown certain improvements in the rate capability but no report has exceeded the theoretical limit of the capacity.…”
Section: Resultsmentioning
confidence: 99%
See 2 more Smart Citations
“…Alternatively, significant effort has been devoted to coating the LFP surfaces with electrically conductive materials, such as amorphous carbon and conducting polymers to ARTICLE enhance the electrical conductivity of LFP surfaces [27][28][29][30][31][32] . Recent studies have adopted rGO or GO to cover the LFP surfaces [16][17][18][19] . However, studies so far have only shown certain improvements in the rate capability but no report has exceeded the theoretical limit of the capacity.…”
Section: Resultsmentioning
confidence: 99%
“…Figure 2c shows that the irreversible capacity of EG/cLFP-based lithium battery is vanished for the cathodes loaded with 0.8 and 1.2 wt% of EG, respectively. The outstanding cycling performance is attributed to the highly conductive few-layers graphene homogenously distributed around cLFP particles, which serve as a fast path for electron migration during the charge/discharge processes 18 . It is known that electron transfer in sp 2 carbon is more effective than in sp 3 amorphous carbon 34,35 .…”
Section: Resultsmentioning
confidence: 99%
See 1 more Smart Citation
“…TEM analysis revealed that the LFP nanowires grew along the c-axis, leading to facile Li + transport and a potentially high-rate response along the shortened b-and a-axis, while the carbon coating ensured adequate electrical conductivity and minimal aggregation throughout the electrode. LiFePO4/C/PPy Nanocrystals ~155 (0.1 C) ~155 (20) [438] LiFePO4/C Porous spheres 153 (0.1 C) ~150 (5) [439] LiFePO4/C Nanoparticles 126 (20 C) ~112 (1000) [440] LiFePO4/C Nanoplates ~165 (0.1 C) ~160 (50) [441] LiFePO4/C Nanocrystals ~160 (0.2 C) 158 (100) [442] LiFePO4/C Nanowires 150 (1 C) 146 (100) [392] LiFePO4/C Nanocomposite ~163 (0.1 C) 162 (100) [406] LiFePO4/C Nanoplates ~165 (0.1 C) ~165 (50) [402] LiFePO4/C Nanocomposite ~168 (0.1 C) ~160 (1100) [384] LiFePO4/C Nanorods ~160 (0.1 C) ~160 (30) [403] LiFePO4/CNT Nanocomposite ~160 (10 mA g -1 ) ~160 (10) [399] LiFePO4/GO Nanocomposite ~145 (1 C) ~145 (5) [443] LiFePO4/ZnO2 Particles ~140 (0.1 C) ~143 (100) [444] Li-ion performance (Fig. 32), was recorded over several discharge rates with a first discharge capacity of 169 mA h g -1 (between 2.5-4.3 V vs. Li/Li + ), and as much as 93 mA h g -1 at the high discharge rate of 10 C. Cycling of the LFP nanowires resulted in stable performance with 146 mA h g -1 obtained after 100 cycles at the C rate.…”
Section: Lifepo4 (Lfp)mentioning
confidence: 99%
“…263 The composite was prepared with LiFePO 4 NPs and graphene nanosheets by spray-drying and annealing; the NPs were embedded in micro-sized spherical secondary particles and wrapped homogeneously and loosely with a graphene 3D network.…”
Section: Lithium Ion Batteries (Libs)mentioning
confidence: 99%