guest ::
| Home > Publications database > Silicon microparticles for Li-ion batteries: Tracking Crystalline-Amorphous transition > print |
| Home > Publications database > Silicon microparticles for Li-ion batteries: Tracking Crystalline-Amorphous transition > print |
| 001 | 1021020 | ||
| 005 | 20240709082106.0 | ||
| 037 | _ | _ | |a FZJ-2024-00480 |
| 100 | 1 | _ | |a Valencia, Helen |0 P:(DE-Juel1)177677 |b 0 |
| 111 | 2 | _ | |a Microscopy Conference 2023 |g MC2023 |c Dramstadt |d 2023-02-26 - 2023-03-02 |w Fed Rep Germany |
| 245 | _ | _ | |a Silicon microparticles for Li-ion batteries: Tracking Crystalline-Amorphous transition |
| 260 | _ | _ | |c 2023 |
| 336 | 7 | _ | |a Conference Paper |0 33 |2 EndNote |
| 336 | 7 | _ | |a Other |2 DataCite |
| 336 | 7 | _ | |a INPROCEEDINGS |2 BibTeX |
| 336 | 7 | _ | |a conferenceObject |2 DRIVER |
| 336 | 7 | _ | |a LECTURE_SPEECH |2 ORCID |
| 336 | 7 | _ | |a Conference Presentation |b conf |m conf |0 PUB:(DE-HGF)6 |s 1705412180_3859 |2 PUB:(DE-HGF) |x After Call |
| 520 | _ | _ | |a The improvement of modern Li-ion batteries (LIBs) is an important step in the development of energy storage systems with regard to the growing market of electric vehicles and the realization of the European goal for climate neutrality by 2050 [1].Silicon (Si) is one of the most promising anodes for next-generation LIBs, with its bestselling point being the theoretical capacity of 3579 mAh/g which is approximately ten-fold than that of the commonly used graphite-based materials used nowadays [2-4]. However, the ~300% volume change during (de)lithiation, which also results in crystalline-amorphous transition, limits the commercialization of Si-based anodes, particularly the Si microparticles. The crystalline-amorphous transitions during (de)lithiation, caused by Li-ions that travel into and out of the crystalline Si, caused degradation. One approach to reducing the degradation is to operate the Si anode under its capacity limit, e.g., by using only ~30 % of the capacity the volume expansion is reduced to only one-third of the maximal expansion and leaving part of the crystalline Si phase unchanged during lithiation. This allows the Si anode to cycle over 200 times. [5] In order to further understand the lithiation process and the resulting capacity fading due to degradation within the Si microparticles, one needs to have an in-depth insight into the structural arrangements within the Si microparticles. Transmission electron microscopy (TEM) is the method of choice to study morphology and chemical composition of the crystalline and amorphous phases within partially lithiated polycrystalline Si microparticles. For the TEM investigation, FIB lamellas are prepared from the 5-10 µm pristine and cycled (lithiated/delithiated) particles. Bright-field (BF) imaging, selected area electron diffraction (SAED) and energy dispersive X-ray spectroscopy (EDX) revealed the presence of the crystalline phase and the complex vein-like amorphous Si phase within the cycled microparticles, the latter not being present in the pristine Si microparticles (Figure 1). This shows the complex expansion of the amorphous phase not only present at the Si microparticle shell but also along stacking faults and grain boundaries. |
| 536 | _ | _ | |a 1223 - Batteries in Application (POF4-122) |0 G:(DE-HGF)POF4-1223 |c POF4-122 |f POF IV |x 0 |
| 700 | 1 | _ | |a Rapp, Philip |0 P:(DE-HGF)0 |b 1 |
| 700 | 1 | _ | |a Graf, Maximilian |0 P:(DE-HGF)0 |b 2 |
| 700 | 1 | _ | |a Gasteiger, Hubert A. |0 P:(DE-HGF)0 |b 3 |
| 700 | 1 | _ | |a Basak, Shibabrata |0 P:(DE-Juel1)180432 |b 4 |e Corresponding author |
| 700 | 1 | _ | |a Eichel, Rüdiger-A. |0 P:(DE-Juel1)156123 |b 5 |u fzj |
| 700 | 1 | _ | |a Mayer, Joachim |0 P:(DE-Juel1)130824 |b 6 |u fzj |
| 909 | C | O | |o oai:juser.fz-juelich.de:1021020 |p VDB |
| 910 | 1 | _ | |a Forschungszentrum Jülich |0 I:(DE-588b)5008462-8 |k FZJ |b 0 |6 P:(DE-Juel1)177677 |
| 910 | 1 | _ | |a Department of Chemistry, Technical University of Munich |0 I:(DE-HGF)0 |b 1 |6 P:(DE-HGF)0 |
| 910 | 1 | _ | |a Department of Chemistry, Technical University of Munich |0 I:(DE-HGF)0 |b 2 |6 P:(DE-HGF)0 |
| 910 | 1 | _ | |a Department of Chemistry, Technical University of Munich |0 I:(DE-HGF)0 |b 3 |6 P:(DE-HGF)0 |
| 910 | 1 | _ | |a Forschungszentrum Jülich |0 I:(DE-588b)5008462-8 |k FZJ |b 4 |6 P:(DE-Juel1)180432 |
| 910 | 1 | _ | |a Forschungszentrum Jülich |0 I:(DE-588b)5008462-8 |k FZJ |b 5 |6 P:(DE-Juel1)156123 |
| 910 | 1 | _ | |a RWTH Aachen |0 I:(DE-588b)36225-6 |k RWTH |b 5 |6 P:(DE-Juel1)156123 |
| 910 | 1 | _ | |a Forschungszentrum Jülich |0 I:(DE-588b)5008462-8 |k FZJ |b 6 |6 P:(DE-Juel1)130824 |
| 910 | 1 | _ | |a RWTH Aachen |0 I:(DE-588b)36225-6 |k RWTH |b 6 |6 P:(DE-Juel1)130824 |
| 913 | 1 | _ | |a DE-HGF |b Forschungsbereich Energie |l Materialien und Technologien für die Energiewende (MTET) |1 G:(DE-HGF)POF4-120 |0 G:(DE-HGF)POF4-122 |3 G:(DE-HGF)POF4 |2 G:(DE-HGF)POF4-100 |4 G:(DE-HGF)POF |v Elektrochemische Energiespeicherung |9 G:(DE-HGF)POF4-1223 |x 0 |
| 914 | 1 | _ | |y 2023 |
| 920 | _ | _ | |l yes |
| 920 | 1 | _ | |0 I:(DE-Juel1)IEK-9-20110218 |k IEK-9 |l Grundlagen der Elektrochemie |x 0 |
| 920 | 1 | _ | |0 I:(DE-Juel1)ER-C-2-20170209 |k ER-C-2 |l Materialwissenschaft u. Werkstofftechnik |x 1 |
| 980 | _ | _ | |a conf |
| 980 | _ | _ | |a VDB |
| 980 | _ | _ | |a I:(DE-Juel1)IEK-9-20110218 |
| 980 | _ | _ | |a I:(DE-Juel1)ER-C-2-20170209 |
| 980 | _ | _ | |a UNRESTRICTED |
| 981 | _ | _ | |a I:(DE-Juel1)IET-1-20110218 |
| Library | Collection | CLSMajor | CLSMinor | Language | Author |
|---|