| dc.contributor.author |
Wang, LL |
|
| dc.contributor.author |
Mukherjee, A |
|
| dc.contributor.author |
Kuo, CY |
|
| dc.contributor.author |
Chakrabarty, S |
|
| dc.contributor.author |
Yemini, R |
|
| dc.contributor.author |
Dameron, AA |
|
| dc.contributor.author |
Dumont, JW |
|
| dc.contributor.author |
Akella, SH |
|
| dc.contributor.author |
Saha, A |
|
| dc.contributor.author |
Taragin, S |
|
| dc.contributor.author |
Aviv, H |
|
| dc.contributor.author |
Naveh, D |
|
| dc.contributor.author |
Sharon, D |
|
| dc.contributor.author |
Chan, TS |
|
| dc.contributor.author |
Lin, HJ |
|
| dc.contributor.author |
Lee, JF |
|
| dc.contributor.author |
Chen, CT |
|
| dc.contributor.author |
Liu, BY |
|
| dc.contributor.author |
Gao, XW |
|
| dc.contributor.author |
Basu, S |
|
| dc.contributor.author |
Hu, ZW |
|
| dc.contributor.author |
Aurbach, D |
|
| dc.contributor.author |
Bruce, PG |
|
| dc.contributor.author |
Noked, M |
|
| dc.date.accessioned |
2024-07-25T04:17:03Z |
|
| dc.date.available |
2024-07-25T04:17:03Z |
|
| dc.date.issued |
2024 |
|
| dc.identifier.citation |
Nature Nanotechnology, 19(2), 2024; 10.1038/s41565-023-01519-8 |
|
| dc.identifier.issn |
1748-3387 |
|
| dc.identifier.uri |
http://ore.immt.res.in/handle/2018/3451 |
|
| dc.description |
This work was supported by the US-Israel Energy Center programme managed by the US-Israel Binational Industrial Research and Development (BIRD) Foundation. In addition, the project is supported by Champion Motors Ltd, the Science and Engineering Research B; US-Israel Energy Center programme; US-Israel Binational Industrial Research and Development (BIRD) Foundation [RJN/2020/000075]; Champion Motors Ltd, the Science and Engineering Research Board for Ramanujan fellowship [MOST 110-2112-M-A49-002-MY3]; Ministry of Science and Technology in Taiwan; Max Planck-POSTECH/Hsinchu Center for Complex Phase Materials |
|
| dc.description.abstract |
A critical current challenge in the development of all-solid-state lithium batteries (ASSLBs) is reducing the cost of fabrication without compromising the performance. Here we report a sulfide ASSLB based on a high-energy, Co-free LiNiO2 cathode with a robust outside-in structure. This promising cathode is enabled by the high-pressure O-2 synthesis and subsequent atomic layer deposition of a unique ultrathin LixAlyZnzO delta protective layer comprising a LixAlyZnzO delta surface coating region and an Al and Zn near-surface doping region. This high-quality artificial interphase enhances the structural stability and interfacial dynamics of the cathode as it mitigates the contact loss and continuous side reactions at the cathode/solid electrolyte interface. As a result, our ASSLBs exhibit a high areal capacity (4.65 mAh cm(-2)), a high specific cathode capacity (203 mAh g(-1)), superior cycling stability (92% capacity retention after 200 cycles) and a good rate capability (93 mAh g(-1) at 2C). This work also offers mechanistic insights into how to break through the limitation of using expensive cathodes (for example, Co-based) and coatings (for example, Nb-, Ta-, La- or Zr-based) while still achieving a high-energy ASSLB performance. |
|
| dc.language |
en |
|
| dc.publisher |
Nature Portfolio |
|
| dc.relation.isreferencedby |
SCI |
|
| dc.rights |
Copyright [2024]. All efforts have been made to respect the copyright to the best of our knowledge. Inadvertent omissions, if brought to our notice, stand for correction and withdrawal of document from this repository. |
|
| dc.subject |
Nanoscience & Nanotechnology |
|
| dc.subject |
Materials Sciences |
|
| dc.subject |
Interdisciplinary Sciences |
|
| dc.title |
High-energy all-solid-state lithium batteries enabled by Co-free LiNiO2 cathodes with robust outside-in structures |
|
| dc.type |
Journal Article |
|
| dc.affiliation.author |
Bar Ilan Univ, Ramat Gan, Israel |
|