Kostiantyn V Kravchyk
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Explore the profile of Kostiantyn V Kravchyk including associated specialties, affiliations and a list of published articles.
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37
Citations
187
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Recent Articles
1.
Baumgartner J, Stoian D, Marshall K, Jafarpour M, Klimpel M, Zhang H, et al.
ACS Energy Lett
. 2025 Feb;
10(2):1082-1088.
PMID: 39974329
3D transition metal fluorides have long been recognized as appealing low-cost, high-energy-density cathode materials for Li-ion batteries, but their conversion-type lithiation mechanism induces structural and morphological changes, limiting their cycling...
2.
Zhang H, Klimpel M, Wieczerzak K, Dubey R, Okur F, Michler J, et al.
Chem Mater
. 2024 Dec;
36(22):11254-11263.
PMID: 39618490
Ultrafast (UF) sintering emerges as a game-changing sintering methodology for fabricating LiLaZrO (LLZO) solid-state electrolytes, representing a pivotal stride toward the advancement and prospective commercialization of Li-garnet solid-state batteries. Despite...
3.
Okur F, Zhang H, Baumgartner J, Sivavec J, Klimpel M, Wasser G, et al.
Adv Sci (Weinh)
. 2024 Nov;
12(2):e2412370.
PMID: 39555691
Ultrafast sintering (UFS) is a compelling approach for fabricating LiLaZrO (LLZO) solid-state electrolytes (SSEs), paving the way for advancing and commercializing Li-garnet solid-state batteries. Although this method is commonly applied...
4.
Kravchyk K, Zhang H, Kovalenko M
Commun Chem
. 2024 Nov;
7(1):257.
PMID: 39521928
No abstract available.
5.
Kravchyk K, Battaglia C, Siller V, Lelotte B, El Kazzi M, Morzy J, et al.
Chimia (Aarau)
. 2024 Jul;
78(6):403-414.
PMID: 38946413
This review article delves into the growing field of solid-state batteries as a compelling alternative to conventional lithium-ion batteries. The article surveys ongoing research efforts at renowned Swiss institutions such...
6.
Zhang H, Okur F, Pant B, Klimpel M, Butenko S, Karabay D, et al.
ACS Appl Mater Interfaces
. 2024 Mar;
16(10):12353-12362.
PMID: 38436097
Rechargeable garnet-based solid-state Li batteries hold immense promise as nonflammable, nontoxic, and high energy density energy storage systems, employing LiLaZrO (LLZO) with a garnet-type structure as the solid-state electrolyte. Despite...
7.
Okur F, Sheima Y, Zimmerli C, Zhang H, Helbling P, Fah A, et al.
ChemSusChem
. 2023 Dec;
17(3):e202301285.
PMID: 38051667
In the quest to replace liquid Li-ion electrolytes with safer and non-toxic solid counterparts for Li-ion batteries, polysiloxane polymers have attracted considerable attention as they offer low glass transition temperatures,...
8.
Klimpel M, Zhang H, Kovalenko M, Kravchyk K
Commun Chem
. 2023 Sep;
6(1):192.
PMID: 37689811
No abstract available.
9.
Baumgartner J, Worle M, Guntlin C, Krumeich F, Siegrist S, Vogt V, et al.
Adv Mater
. 2023 Jul;
35(49):e2304158.
PMID: 37522526
Pyrochlore-type iron (III) hydroxy fluorides (Pyr-IHF) are appealing low-cost stationary energy storage materials due to the virtually unlimited supply of their constituent elements, their high energy densities, and fast Li-ion...
10.
Kravchyk K, Kovalenko M
Commun Chem
. 2023 Jan;
3(1):120.
PMID: 36703337
In the search for sustainable energy storage systems, aluminum dual-ion batteries have recently attracted considerable attention due to their low cost, safety, high energy density (up to 70 kWh kg),...