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Öznil Budak
Öznil Budak
Material Engineer
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Year
MXene/activated-carbon hybrid capacitive deionization for permselective ion removal at low and high salinity
M Torkamanzadeh, L Wang, Y Zhang, O Budak, P Srimuk, V Presser
ACS applied materials & interfaces 12 (23), 26013-26025, 2020
1042020
Ionic liquid-based synthesis of MXene
S Husmann, Ö Budak, H Shim, K Liang, M Aslan, A Kruth, A Quade, ...
Chemical Communications 56 (75), 11082-11085, 2020
1032020
Choosing the right carbon additive is of vital importance for high-performance Sb-based Na-ion batteries
K Pfeifer, S Arnold, Ö Budak, X Luo, V Presser, H Ehrenberg, S Dsoke
Journal of Materials Chemistry A 8 (12), 6092-6104, 2020
512020
High-performance ion removal via zinc–air desalination
P Srimuk, L Wang, Ö Budak, V Presser
Electrochemistry Communications 115, 106713, 2020
342020
Carbide-derived niobium pentoxide with enhanced charge storage capacity for use as a lithium-ion battery electrode
O Budak, M Geißler, D Becker, A Kruth, A Quade, R Haberkorn, ...
ACS Applied Energy Materials 3 (5), 4275-4285, 2020
292020
In situ tracking of partial sodium desolvation of materials with capacitive, pseudocapacitive, and battery-like charge/discharge behavior in aqueous electrolytes
P Srimuk, J Lee, O Budak, J Choi, M Chen, G Feng, C Prehal, V Presser
Langmuir 34 (44), 13132-13143, 2018
262018
Titanium Niobium Oxide Ti2Nb10O29/Carbon Hybrid Electrodes Derived by Mechanochemically Synthesized Carbide for High‐Performance Lithium‐Ion Batteries
Ö Budak, P Srimuk, M Aslan, H Shim, L Borchardt, V Presser
ChemSusChem 14 (1), 398-407, 2021
242021
Electrospun vanadium sulfide/carbon hybrid fibers obtained via one-step thermal sulfidation for use as lithium-ion battery electrodes
S Husmann, Ö Budak, A Quade, A Frank, A Kruth, C Scheu, A Tolosa, ...
Journal of Power Sources 450, 227674, 2020
212020
Comparison of organic electrolytes at various temperatures for 2.8 áV–Li-ion hybrid supercapacitors
H Shim, Í Budak, V Haug, M Widmaier, V Presser
Electrochimica Acta 337, 135760, 2020
182020
Understanding interlayer deprotonation of hydrogen titanium oxide for high-power electrochemical energy storage
S Fleischmann, K Pfeifer, M Widmaier, H Shim, O Budak, V Presser
ACS Applied Energy Materials 2 (5), 3633-3641, 2019
172019
Antimony alloying electrode for high-performance sodium removal: how to use a battery material not stable in aqueous media for saline water remediation
S Arnold, L Wang, Ö Budak, M Aslan, P Srimuk, V Presser
Journal of Materials Chemistry A 9 (1), 585-596, 2021
162021
Vanadium (III) Oxide/Carbon Core/Shell Hybrids as an Anode for Lithium‐Ion Batteries
Ö Budak, P Srimuk, A Tolosa, S Fleischmann, J Lee, SW Hieke, A Frank, ...
Batteries & Supercaps 2 (1), 74-82, 2019
132019
Hybrid Anodes of Lithium Titanium Oxide and Carbon Onions for Lithium‐Ion and Sodium‐Ion Energy Storage
H Shim, S Arnold, Ö Budak, M Ulbricht, P Srimuk, V Presser
Energy Technology 8 (11), 2000679, 2020
52020
Corrigendum: Titanium Niobium Oxide Ti2Nb10O29/Carbon Hybrid Electrodes Derived by Mechanochemically Synthesized Carbide for High‐Performance Lithium‐Ion Batteries
Ö Budak, P Srimuk, M Aslan, H Shim, L Borchardt, V Presser
ChemSusChem 15 (15), 2022
2022
Titanium Niobium Oxide Ti2Nb10O29/Carbon Hybrid Electrodes Derived by Mechanochemically Synthesized Carbide for High-Performance Lithium-Ion Batteries (vol 14, pg 398, 2021)
O Budak, P Srimuk, M Aslan, H Shim, L Borchardt, V Presser
CHEMSUSCHEM 15 (15), 2022
2022
Metal oxide/carbon hybrid anode materials for lithium-ion batteries
Ö Budak
Saarländische Universitäts-und Landesbibliothek, 2020
2020
LiCu0. 5Mn1. 5O4 and LiNi0. 25Cu0. 25Mn1. 5O4 spinel electrodes for lithium-ion batteries
Ö Budak
Fen Bilimleri Enstitüsü, 0
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Articles 1–17