{"id":258,"date":"2016-07-06T17:52:02","date_gmt":"2016-07-06T15:52:02","guid":{"rendered":"http:\/\/wordpress1996948.home.pl\/autoinstalator\/wordpressplugins\/?page_id=2"},"modified":"2026-01-19T14:39:39","modified_gmt":"2026-01-19T13:39:39","slug":"home-pl","status":"publish","type":"page","link":"https:\/\/home.agh.edu.pl\/~xi\/","title":{"rendered":"Strona Domowa – Konrad \u015awierczek"},"content":{"rendered":"

O mnie<\/h2>\n<\/div>

Informacje zawodowe<\/h3>\n<\/div>
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Pracuj\u0119 w Katedrze Energetyki Wodorowej<\/a> na Wydziale Energetyki i Paliw<\/a> Akademii G\u00f3rniczo-Hutniczej im. Stanis\u0142awa Staszica w Krakowie<\/a>.<\/h4>\n

Moja kariera zawodowa jest \u015bci\u015ble zwi\u0105zana z AGH, gdzie uzyska\u0142em stopie\u0144 doktora (praca doktorska \u201eStruktura, w\u0142a\u015bciwo\u015bci transportowe i elektrochemiczne spineli Li-Mn-O oraz Li-Mn-Co-O. Zastosowanie w ogniwach litowych o napi\u0119ciu 3 V i 4 V<\/em>\u201d, Wydzia\u0142 In\u017cynierii Materia\u0142owej i Ceramiki<\/a>), doktora habilitowanego (monografia \u201eProjektowanie w\u0142a\u015bciwo\u015bci fizykochemicznych tlenkowych materia\u0142\u00f3w katodowych dla ogniw IT-SOFC oraz Li-ION<\/em>\u201d) oraz tytu\u0142 profesora. W latach 2016-2020 oraz 2020-2024 pe\u0142ni\u0142em na Wydziale Energetyki i Paliw funkcj\u0119 prodziekana. Obecnie jestem kierownikiem Katedry Energetyki Wodorowej<\/a>, a tak\u017ce zosta\u0142em wybrany do Rady Uczelni<\/a> na kadencj\u0119 2025-2028.<\/h4>\n

Moje zainteresowania naukowe dotycz\u0105 bada\u0144 nad korelacj\u0105 pomi\u0119dzy struktur\u0105 krystaliczn\u0105, a w\u0142a\u015bciwo\u015bciami transportowymi i elektrokatalitycznymi materia\u0142\u00f3w tlenkowych, obejmuj\u0105ce poza tematyk\u0105 ogniw paliwowych SOFC, elektrolizer\u00f3w SOEC i baterii Li-ion, tak\u017ce badania nad materia\u0142ami do magazynowania tlenu oraz na membrany ceramiczne o mieszanym przewodnictwie jonowo-elektronowym.<\/h4>\n

Badania te realizowane s\u0105 w ramach mi\u0119dzynarodowych i krajowych projekt\u00f3w badawczych, w ramach \u015bcis\u0142ej wsp\u00f3\u0142pracy mi\u0119dzynarodowej i krajowej.<\/h4>\n<\/div>
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Zainteresowania<\/h3>\n<\/div>

Podr\u00f3\u017ce, kultura i sztuka Azji, numizmatyka (okres staro\u017cytny).<\/h4>\n<\/div>
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<\/i>Nauka<\/span><\/a><\/div>
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Nauka<\/span><\/h2>\n<\/div>

Dzia\u0142alno\u015b\u0107 naukowo-badawcza<\/h3>\n<\/div>

Dane bibliometryczne:<\/strong><\/h4>\n

ORCID: 0000-0003-4519-389X<\/a><\/h4>\n

ResearcherID: S-7666-2016<\/a><\/h4>\n

Scopus: 6603619667<\/a><\/h4>\n

Polska Bibliografia Naukowa<\/a><\/h4>\n

Ludzie Nauki<\/a><\/h4>\n<\/div>

Liczba publikacji z bazy Journal Citation Reports: 207<\/strong><\/span>
\nSumaryczna warto\u015b\u0107 wsp\u00f3\u0142czynnika oddzia\u0142ywania IF: > 1100<\/strong><\/span>
\nLiczba cytowa\u0144 bez autocytowa\u0144: > 6100<\/strong><\/span>
\nIndeks Hirscha: 46<\/strong><\/span><\/p>\n

Prezentacja tematyki badawczej<\/strong><\/a><\/span><\/h4>\n<\/div>
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<\/i>Projekty badawcze<\/span><\/a><\/div>
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Lista wa\u017cniejszych publikacji<\/h3>\n<\/div>

<\/i><\/i><\/span>2026<\/span><\/a><\/h4><\/div>
\n

1. M. Nowakowska, J. D\u0105browa, J. Adamczyk, M. Zajusz, K. Berent, R. Merkle, G. Gazdowicz, K. \u015awierczek
\u201eExploiting Zn and Zr synergy in co-doped Sr(Fe1-xMox)O3-\u03b4 – versatile Co-free electrode materials for Solid Oxide Fuel Cells\u201d
Journal of Materials Chemistry A (2026), accepted
IF (2024) 9.5<\/p>\n

2. Z. Sun, Z. Du, K. \u015awierczek, J. Zeng, H. Zhao
\u201eHigh-entropy Engineering Tuning Electrochemical Activity and Stability of Layered Double Perovskite Oxygen Electrode for High-Performance Protonic Ceramic Cells\u201d
Journal of Materials Chemistry A (2026), accepted
IF (2024) 9.5<\/p>\n

3. K. Liao, Z. Wang, X. Xin, K. Zheng, K. \u015awierczek, Z. Mandic, R. Liu, X. Yan, S. Sun, M. Zhou
\u201eA high-energy-density, long-cycling lithium-ion battery with a unique current collector-free integrated cathode\u201d
Electrochimica Acta 545 (2026) 147756
IF (2024) 5.6<\/p>\n<\/div><\/div><\/div>

<\/i><\/i><\/span>2025<\/span><\/a><\/h4><\/div>
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1. K. \u015awierczek, K. Zheng, L. Zhang, Y. Ling, M. Zhou
\u201eEditorial for special issue on high-entropy and multicomponent-doped materials for energy applications: Innovations in energy conversion and storage\u201d
International Journal of Minerals, Metallurgy and Materials 32(11) (2025) 2593-2597
IF (2024) 7.2<\/p>\n

2. J. Winiarski, P. Winiarz, K. \u015awierczek
\u201eMulticomponent Gd1-xSmxBa0.5Sr0.5CoCuO5+\u03b4 double perovskites as oxygen electrodes for solid oxide cells: Effect of chemical composition and electrospun morphology\u201d
International Journal of Minerals, Metallurgy and Materials 32(11) (2025) 2628-2638
IF (2024) 7.2<\/p>\n

3. K. Zieli\u0144ska, J. D\u0105browa, M. Zajusz, M. Gajewska, K. \u015awierczek
\u201eRole of 4d\/5d dopants in designing SrCoO3-\u03b4-based air electrodes for Solid Oxide Fuel Cells\u201d
Journal of Alloys and Compounds 1036 (2025) 181795
IF (2024) 6.3<\/p>\n

4. M. Mo\u017adzierz, T. Holstun, Z. Cai, G.-H. Lee, H.-M. Hau, X. Yang, Y. Chen, P. Czaja, W. Yang, K. \u015awierczek, G. Ceder
\u201eTuning cation (dis)order in Cr-based Li-excess oxide cathode materials to improve Li+ transport properties\u201d
Advanced Energy Materials 15(33) (2025) 2502157
IF (2024) 26.0<\/p>\n

5. Z. Luo, Y. Cai, Y. Zhou, X. Xin, M. Zhou, Y. Liu, Z. Wu, W. Sun, L. Jonghee, K. Zheng, K. \u015awierczek, S. Papovi\u0107
\u201eSynergistic electrolyte design for dual-interface stability in sodium-ion batteries\u201d
Journal of Materials Chemistry A 13(23) (2025) 17519-17527
IF (2024) 9.5<\/p>\n

6. K. Zhou, S. Gao, S. Papovi\u0107, K. Zheng, K. \u015awierczek, Z. Mandic, M. Zhou, X. Xin
\u201eLithiated zeolite-enhanced gel electrolytes for lithium metal batteries with diverse cathodes including LiFePO4, LiMn2O4, and O2\u201d
Electrochimica Acta 532 (2025) 146482
IF (2024) 5.6<\/p>\n

7. K. Zhou, Z. Fan, S. Papovi\u0107, K. Zheng, K. \u015awierczek, Z. Mandic, M. Zhou, X. Xin
\u201eEnhancing stability PVDF-HFP-based ternary gel electrolyte for dendrite-free lithium metal anodes\u201d
Journal of Power Sources 647 (2025) 237368
IF (2024) 7.9<\/p>\n

8. Y. Cai, Z. Luo, K. Liao, X. Xin, M. Zhou, Y.-J. Cheng, R. Liu, X. Yan, S. Papovi\u0107, K. Zheng, K. \u015awierczek
\u201eDual-site Zn doping boosts longevity and air stability of O3-type NaNi1\/3Fe1\/3Mn1\/3O2 cathode for high-performance sodium-ion batteries\u201d
Journal of Power Sources 631 (2025) 236272
IF (2024) 7.9<\/p>\n

9. A. Kulka, K. Walczak, J. P\u0142otek, B. Fu, A. Arifiadi, K. \u015awierczek, A. Hanc, M. Kasprzyk, M. Ihsan Ul Haq, G.-H. Lee, W. Yang., M. Winter, J. Kasnatscheew, R. Kostecki
\u201eEvaluating the influence of surface reconstruction layers in Li\/Mn-Rich layered oxide (LMR) electrodes on the anionic redox reactions and electrochemical properties of LMR || Li Cells\u201d
Energy Storage Materials 75 (2025) 104001
IF (2024) 20.2<\/p>\n

10. M. Mo\u017adzierz, M. Gajewska, P. Czaja, B. Fu, J. D\u0105browa, K. \u015awierczek
\u201eElectrochemically-induced amorphization in multicomponent spinel oxide Li-ion cell anodes: Non-equimolarity enables improved electrochemical performance\u201d
Chemical Engineering Journal 504 (2025) 159046
IF (2024) 13.2<\/p>\n

11. K. Zieli\u0144ska, J. D\u0105browa, M. Zajusz, M. Szymczak, K. Li, P. Winiarz, M. Gajewska, K. \u015awierczek
\u201eAlkali free perovskites – Exploiting B-site synergies in Sr-free, high-entropy cathodes for intermediate-temperature Solid-Oxide fuel cells\u201d
Chemical Engineering Journal 504 (2025) 158974
IF (2024) 13.2<\/p>\n

12. Z. Du, X. Dong, T. Wang, K. \u015awierczek, H. Zhao
\u201eFluorine doping for the enhanced electrochemical performance of SrCo0.8Ti0.2O3-based perovskite cathode for Solid Oxide Cells\u201d
International Journal of Hydrogen Energy 99 (2025) 35-44
IF (2024) 8.3<\/p>\n

13. M. Zhang, J. Liu, Z. Du, Y. He, Y. Gong, Z. Sun, B. Fu, K. \u015awierczek, J. Zeng, H. Zhao
\u201eHighly active and stable oxygen electrode PrBaCo2O5+\u03b4-Ba2CoWO6 enabled by In Situ formed misfit dislocation interface for reversible solid oxide cell\u201d
Applied Catalysis B: Environment and Energy 361 (2025) 124669
IF (2024) 21.1<\/p>\n<\/div><\/div><\/div>

<\/i><\/i><\/span>2024<\/span><\/a><\/h4><\/div>
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1. Z. Wei, X. Wang, M. Zhou, S. Papovi\u0107, K. Zheng, K. \u015awierczek, J. Wu, X. Xin
\u201eRevitalizing lithium metal batteries: Strategies for tackling dead lithium formation and reactivation\u201d
Small 20(51) (2024) 2407395
IF 12.1<\/p>\n

2. S. Jia, K. Liao, M. Zhou, X. Xin, Y. Luo, Y.-J. Cheng, R. Liu, X. Yan, J. Lee, S. Papovi\u0107, K. Zheng, K. \u015awierczek
\u201ePrussian white\/reduced graphene oxide composite as cathode material to enhance the electrochemical performance of sodium-ion battery\u201d
Langmuir 40(39) (2024) 20485-20494
IF 3.9<\/p>\n

3. K. Machaj, P. Winiarz, A. Niemczyk, Y. Naumovich, R. Kluczowski, K. Li, K. Zheng, K. \u015awierczek
\u201eA study of the novel Cu-based materials as a potential air electrode for high-temperature reversible solid oxide cells\u201d
International Journal of Hydrogen Energy 95 (2024) 1222-1234
IF 8.3<\/p>\n

4. P. Winiarz, E.A. Sroczyk, A. Brzoza-Kos, P. Czaja, K. Kapusta, K. \u015awierczek
\u201eSmBa0.5Sr0.5CoCuO5+\u03b4 and Sm0.5Ba0.25Sr0.25Co0.5Cu0.5O3-\u03b4 oxygen electrode materials for Solid Oxide Fuel Cells: Crystal structure and morphology influence on the electrocatalytic activity\u201d
Acta Materialia 277 (2024) 120186
IF 9.3<\/p>\n

5. Q. Ren, Y. Zhang, H. Tao, L. Qin, K. \u015awierczek, W. Guan, J. Wang, C. Xia, L. Zhu
\u201eAn innovative and facile synthesis route of (La,Sr)2FeO4+\u03b4-La0.4Sr0.6FeO3-\u03b4 composite as a highly stable air electrode for reversible solid oxide cell applications\u201d
Journal of Advanced Ceramics 13(9) (2024) 1337-1348
IF 16.6<\/p>\n

6. B. Fu, M. Mo\u017adzierz, A. Kulka, K. \u015awierczek
\u201eRecent progress in Ni-rich layered oxides and related cathode materials for Li-ion cells\u201d
International Journal of Minerals, Metallurgy and Materials 31(11) (2024) 2345-2367
IF 7.2<\/p>\n

7. B. Fu, A. Kulka, B. Wang, M. Mo\u017adzierz, A. Brzoza-Kos, P. Czaja, K. \u015awierczek
\u201eNi-rich LiNi0.905Co0.043Al0.052O2 cathode material for high-energy density Li-ion cells: Tuning lithium content, structural evolution, and full-cell performance\u201d
Electrochimica Acta 494 (2024) 144455
IF 5.6<\/p>\n

8. J. Zhao, B. Wang, Z. Zhan, M. Hu, F. Cai, K. \u015awierczek, K. Yang, J. Ren, Z. Guo, Z. Wang
\u201eBoron-doped three-dimensional porous carbon framework\/carbon shell encapsulated silicon composites for high-performance lithium-ion battery anodes\u201d
Journal of Colloid and Interface Science 664 (2024) 790-800
IF 9.7<\/p>\n

9. Z. Sun, Z. Shen, Z. Du, Y. Zhang, Y. Gong, M. Zhang, K. Wang, K. \u015awierczek, J. Zeng, H. Zhao
\u201eAtomic-scale engineering for new generation air electrode materials of Solid Oxide Cells: Quintuple perovskite Sm2Ba3Co2Fe3O15-\u03b4 with twinned crystal structure\u201d
Advanced Functional Materials 34(39) (2024) 2403312
IF 19.0<\/p>\n

10. K.A. Bogdanowicz, A. Iwan, K. Dysz, W. Przybyl, M. Marzec, K. Cichy, K. \u015awierczek
\u201eAir-stable and eco-friendly symmetrical imine with thiadiazole moieties in neutral and protonated form for perovskite photovoltaics\u201d
Materials 17(8) (2024) 1909
IF 3.2<\/p>\n

11. J. Bai, Z. Li, X. Wang, K. \u015awierczek, C. Wu, H. Zhao
\u201eLimitations and strategies towards high-performance red phosphorus materials for Li\/Na-ion batteries\u201d
Energy Material Advances 6 (2024) 86
IF 15.9<\/p>\n

12. B. Wang, F. Cai, C. Chu, B. Fu, K. \u015awierczek, L. Li, H. Zhao
\u201eModification of the Ni-rich layered cathode material by Hf addition: Synergistic microstructural engineering and surface stabilization\u201d
ACS Applied Materials & Interfaces 16(10) (2024) 12599-12611
IF 8.2<\/p>\n

13. J. Wang, S. Zhang, H. Zhao, J. Liu, M.-A. Yang, Z. Li, K. \u015awierczek
\u201eConstruction of an intimately riveted Li\/garnet interface with ultra-low interfacial resistance for solid-state batteries\u201d
Journal of Materials Chemistry A 12(8) (2024) 4903-4911
IF 9.5<\/p>\n

14. H. Yang, A. Wu, Z. Liu, Y. Su, X. Hu, K. \u015awierczek, J. Luo, A. Meng, Y. Lu, Z. Lu, Y. Li, Y. Zhang, W. Guan
\u201eA power-to-hydrogen nearby consumption system based on a flat-tube rSOC coupled with local photovoltaics and Yellow River water\u201d
International Journal of Hydrogen Energy 57 (2024) 1111-1117
IF 8.3<\/p>\n

15. Z. Du, L. Shen, Y. Gong, M. Zhang, J. Zhang, J. Feng, K. Li, K. \u015awierczek, H. Zhao
\u201eSelf-assembled perovskite nanocomposite with beneficial lattice tensile strain as high active and durable cathode for low temperature Solid Oxide Fuel Cell\u201d
Advanced Functional Materials 34(4) (2024) 2310790
IF 19.0<\/p>\n<\/div><\/div><\/div>

<\/i><\/i><\/span>2023<\/span><\/a><\/h4><\/div>
1. M. Mo\u017adzierz, Z. Feng, A. Brzoza-Kos, P. Czaja, B. Fu, K. \u015awierczek
\n\u201eUnderstanding the electrochemical reaction mechanism to achieve excellent performance of the conversion-alloying Zn2SnO4 anode for Li-ion batteries\u201d
\nJournal of Materials Chemistry A 11(38) (2023) 20686-20700
\nIF 10.7<\/p>\n

2. J. Suchanicz, D. Sitko, K. Stanuch, K. \u015awierczek, G. Jag\u0142o, A. Kruk, K. Kluczewska-Chmielarz, K. Konieczny, P. Czaja, J. Aleksandrowicz, W. Wieczorek, J. Grygierek, M. Sokolowski, G. Stachowski, M. Antonova, A. Sternberg
\n\u201eTemperature and E-poling evolution of structural, thermal, vibrational, dielectric and ferroelectric properties of Ba1-xSrxTiO3 ceramics (x = 0, 0.1, 0.2, 0.3, 0.4 and 0.45)\u201d
\nMaterials 16(18) (2023) 6316
\nIF 3.1<\/p>\n

3. K. Li, K. \u015awierczek, P. Winiarz, A. Brzoza-Kos, A. St\u0119pie\u0144, Z. Du, Y. Zhang, K. Zheng, K. Cichy, A. Niemczyk, Y. Naumovich
\n\u201eUnveiling the electrocatalytic activity of the GdBa0.5Sr0.5Co2-xCuxO5+\u03b4 (x \u2265 1) oxygen electrodes for Solid Oxide Cells\u201d
\nACS Applied Materials & Interfaces 15(33) (2023) 39578-39593
\nIF 8.3<\/p>\n

4. W. Skubida, D. Jaworski, A. Mielewczyk-Gry\u0144, S. Wachowski, T. Miruszewski, K. Cichy, K. \u015awierczek, M. Gazda
\n\u201eCharge transport in high-entropy oxides\u201d
\nThe Journal of Physical Chemistry C 127(29) (2023) 14534-14544
\nIF 3.3<\/p>\n

5. Z. Yang, Z. Li, Y. Yang, Q. Zhang, H. Xie, J. Wang, K. \u015awierczek, H. Zhao
\n\u201eWell-dispersed Fe nanoclusters for effectively increasing the initial Coulombic efficiency of the SiO anode\u201d
\nACS Nano 17(8) (2023) 7806-7812
\nIF 15.8<\/p>\n

6. A. Kusior, P. Jele\u0144, M. Sitarz, K. \u015awierczek, M. Radecka
\n\u201e3D flower-like TiO2 nanostructures: Anatase-to-rutile phase transformation and photoelectrochemical application\u201d
\nCatalysts 13(4) (2023) 671
\nIF 3.8<\/p>\n

7. Y. Zhang, H. Zhao, M. Zhang, Z. Du, W. Guan, S.C. Singhal, K. \u015awierczek
\n\u201eBoosting electrode reaction kinetics of SSOFCs by synergistic effect of nanoparticles co-decoration on both cathode and anode\u201d
\nChemistry of Materials 35(2) (2023) 499-510
\nIF 7.2<\/p>\n

8. J. Su\u0142owska, M. Szumera, D. Madej, B. Handke, K. \u015awierczek
\n\u201eMelting behavior of sulfur-bearing silicate-phosphate glass batches\u201d
\nJournal of Thermal Analysis and Calorimetry 148(4) (2023) 1463-1480
\nIF 3.0<\/p>\n

9. M. Lubszczyk, T. Brylewski, P. Rutkowski, K. \u015awierczek, A. Kruk
\n\u201ePreparation and physicochemical properties of K0.5Na0.5NbO3 ceramics obtained using a modified wet chemistry method\u201d
\nMaterials Science & Engineering B 288 (2023) 116135
\nIF 3.9<\/div><\/div><\/div>

<\/i><\/i><\/span>2022<\/span><\/a><\/h4><\/div>
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1. J. D\u0105browa, A. St\u0119pie\u0144, M. Szymczak, M. Zajusz, P. Czaja, K. \u015awierczek
\n\u201eHigh-entropy approach to double perovskite cathode materials for Solid Oxide Fuel Cells: is multicomponent occupancy in (La,Pr,Nd,Sm,Gd)BaCo2O5+\u03b4 affecting physicochemical and electrocatalytic properties?\u201d
\nFrontiers in Energy Research 10 (2022) 899308
\nIF 3.4<\/p>\n

2. J. D\u0105browa, J. Adamczyk, A. St\u0119pie\u0144, M. Zajusz, K. Bar, K. Berent, K. \u015awierczek
\n\u201eSynthesis and properties of the gallium-containing Ruddlesden-Popper oxides with high-entropy B-site arrangement\u201d
\nMaterials 15(18) (2022) 6500
\nIF 3.4<\/p>\n

3. A. Szymaszek-Wawryca, U. D\u00edaz, D. Duraczy\u0144ska, K. \u015awierczek, B. Samojeden, M. Motak
\n\u201eCatalytic performance and sulfur dioxide resistance of one-pot synthesized Fe-MCM-22 in selective catalytic reduction of nitrogen oxides with ammonia (NH3-SCR) – The effect of iron content\u201d
\nInternational Journal of Molecular Sciences 23(18) (2022) 10754
\nIF 5.6<\/p>\n

4. M. Mo\u017adzierz, K. \u015awierczek, J. D\u0105browa, M. Gajewska, A. Hanc, Z. Feng, J. Cie\u015blak, M. K\u0105dzio\u0142ka-Gawe\u0142, J. P\u0142otek, M. Marzec, A. Kulka
\n\u201eHigh-entropy Sn0.8(Co0.2Mg0.2Mn0.2Ni0.2Zn0.2)2.2O4 conversion-alloying anode material for Li-ion cells: Altered lithium storage mechanism, activation of Mg, and origins of the improved cycling stability\u201d
\nACS Applied Materials & Interfaces 14(37) (2022) 42057-42070
\nIF 9.5<\/p>\n

5. D. Cai, Z. Liu, J. Yang, Y. Zhang, M. Chai, J. Wang, W. Guan, K. \u015awierczek
\n\u201eEnhanced performance and durability of lanthanum strontium cobalt ferrite by in-situ solvothermal modification\u201d
\nJournal of the European Ceramic Society 42(12) (2022) 5008-5014
\nIF 5.7<\/p>\n

6. K. Li, A. Niemczyk, K. \u015awierczek, A. St\u0119pie\u0144, Y. Naumovich, J. D\u0105browa, M. Zajusz, K. Zheng, B. Dabrowski
\n\u201eCo-free triple perovskite La1.5Ba1.5Cu3O7\u00b1\u03b4 as a promising air electrode material for Solid Oxide Fuel Cells\u201d
\nJournal of Power Sources 532 (2022) 231371
\nIF 9.2<\/p>\n

7. N. Yao, Y. Zhang, X. Rao, Z. Yang, K. Zheng, K. \u015awierczek, H. Zhao
\n\u201eA review on the critical challenges and progress of SiOx-based anodes for lithium-ion batteries\u201d
\nInternational Journal of Minerals, Metallurgy and Materials 29(4) (2022) 876-895
\nIF 4.8<\/p>\n

8. C. Sun, P. Summa, Y. Wang, K. \u015awirk, A. Mir\u00f3 i Rovira, S. Casale, K. \u015awierczek, C. Hu, M. R\u00f8nning, P. Da Costa
\n\u201eBoosting CO2 reforming of methane via the metal-support interaction in mesostructured SBA-16-derived Ni nanoparticles\u201d
\nApplied Materials Today 26 (2022) 101354
\nIF 8.3<\/p>\n

9. B. Wang, H. Zhao, F. Cai, Z. Liu, G. Yang, X. Qin, K. \u015awierczek
\n\u201eSurface engineering with ammonium niobium oxalate: A multifunctional strategy to enhance electrochemical performance and thermal stability of Ni-rich cathode materials at 4.5 V cutoff potential\u201d
\nElectrochimica Acta 403 (2022) 139636
\nIF 6.6<\/p>\n

10. A. Niemczyk, R. Merkle, J. Maier, K. \u015awierczek
\n\u201eDefect chemistry and proton uptake of La2-xSrxNiO4\u00b1\u03b4 and La2-xBaxNiO4\u00b1\u03b4 Ruddlesden-Popper phases\u201d
\nJournal of Solid State Chemistry 306 (2022) 122731
\nIF 3.3<\/p>\n

11. K. Cichy, M. Zaj\u0105c, K. \u015awierczek
\n\u201eEvaluation of applicability of Nd- and Sm-substituted Y1-xRxMnO3+\u03b4 in temperature swing absorption for energy-related technologies\u201d
\nEnergy 239(E) (2022) 122429
\nIF 9.0<\/p>\n

12. P. Summa, B. Samojeden, M. Motak, D. Wierzbicki, I. Alxneit, K. \u015awierczek, P. Da Costa
\n\u201eInvestigation of Cu promotion effect on hydrotalcite-based nickel catalyst for CO2 methanation\u201d
\nCatalysis Today 384-386 (2022) 133-145
\nIF 5.3<\/p>\n<\/div><\/div><\/div>

<\/i><\/i><\/span>2021<\/span><\/a><\/h4><\/div>
\n

1. J. D\u0105browa, K. Zieli\u0144ska, A. St\u0119pie\u0144, M. Zajusz, M. Nowakowska, M. Mo\u017adzierz, K. Berent, M. Szymczak, K. \u015awierczek
\n\u201eFormation of solid solutions and physicochemical properties of the high-entropy
\nLn1-xSrx(Co,Cr,Fe,Mn,Ni)O3-\u03b4 (Ln = La, Pr, Nd, Sm or Gd) perovskites\u201d
\nMaterials 14(18) (2021) 5264
\nIF 3.748<\/p>\n

2. K. Cichy, K. \u015awierczek
\n\u201eInfluence of doping on the transport properties of Y1-xLnxMnO3+\u03b4 (Ln: Pr, Nd)\u201d
\nCrystals 11(5) (2021) 510
\nIF 2.670<\/p>\n

3. M. Mo\u017adzierz, J. D\u0105browa, A. St\u0119pie\u0144, M. Zajusz, M. Stygar, W. Zaj\u0105c, M. Danielewski, K. \u015awierczek
\n\u201eMixed ionic-electronic transport in the high-entropy (Co,Cu,Ni,Mg,Zn)1-xLixO oxides\u201d
\nActa Materialia 208 (2021) 116735
\nIF 9.209<\/p>\n

4. L. Zhao, H. Zhao, J. Wang, Y. Zhang, Z. Li, Z. Du, K. \u015awierczek, Y. Hou
\n\u201eMicro\/nano Na3V2(PO4)3\/N-doped carbon composites with a hierarchical porous structure for high-rate pouch-type sodium-ion full-cell performance\u201d
\nACS Applied Materials & Interfaces 13(7) (2021) 8445-8454
\nIF 10.383<\/p>\n

5. A. Niemczyk, A. St\u0119pie\u0144, K. Cichy, J. D\u0105browa, Z. Zhang, B. G\u0119dziorowski, K. Zheng, H. Zhao, K. \u015awierczek
\n\u201eModification of Ruddlesden-Popper-type Nd2-xNi0.75Cu0.2M0.05O4\u00b1\u03b4 by the Nd-site cationic deficiency and doping with Sc, Ga or In: crystal structure, oxygen content, transport properties and oxygen permeability\u201d
\nJournal of Solid State Chemistry 296 (2021) 121982
\nIF 3.656<\/p>\n

6. J. D\u0105browa, J. Cie\u015blak, M. Zajusz, M. Mo\u017adzierz, K. Berent, A. Miku\u0142a, A. St\u0119pie\u0144, K. \u015awierczek
\n\u201eStructure and transport properties of the novel (Dy,Er,Gd,Ho,Y)3Fe5O12 and (Dy,Gd,Ho,Sm,Y)3Fe5O12 high entropy garnets\u201d
\nJournal of the European Ceramic Society 41(6) (2021) 3844-3849
\nIF 6.364<\/p>\n

7. K. Cichy, K. \u015awierczek, K. Jarosz, A. Klimkowicz, M. Marzec, M. Gajewska, B. Dabrowski
\n\u201eTowards efficient oxygen separation from air: Influence of the mean rare-earth radius on thermodynamics and kinetics of reactivity with oxygen in hexagonal Y1-xRxMnO3+\u03b4\u201d
\nActa Materialia 205 (2021) 116544
\nIF 9.209<\/p>\n

8. W. Skubida, K. Zheng, A. St\u0119pie\u0144, K. \u015awierczek, A. Klimkowicz
\n\u201eSrCe0.9In0.1O3-\u03b4-based reversible symmetrical Protonic Ceramic Cell\u201d
\nMaterials Research Bulletin 135 (2021) 111154
\nIF 5.600<\/p>\n

9. T. Polczyk, W. Zaj\u0105c, M. Zi\u0105bka, K. \u015awierczek
\n\u201eMitigation of grain boundary resistance in La2\/3-xLi3xTiO3 perovskite as an electrolyte for solid state Li-ion batteries\u201d
\nJournal of Materials Science 56(3) (2021) 2435-2450
\nIF 4.682<\/p>\n

10. Y. Zhang, B. Zhang, H. Zhao, K. \u015awierczek, Z. Du, Y. Li, L. Xu, H. Li
\n\u201eElectrochemical performance and structural durability of Mg-doped SmBaMn2O5+\u03b4 layered perovskite electrode for symmetrical solid oxide fuel cell\u201d
\nCatalysis Today 364 (2021) 80-88
\nIF 6.562<\/p>\n<\/div><\/div><\/div>

<\/i><\/i><\/span>2020<\/span><\/a><\/h4><\/div>
1. J. D\u0105browa, A. Olszewska, A. Falkenstein, C. Schwab, M. Szymczak, M. Zajusz, M. Mo\u017adzierz, A. Miku\u0142a, K. Zieli\u0144ska, K. Berent, T. Czeppe, M. Martin, K. \u015awierczek
\n\u201eInnovative approach to design SOFC air electrode materials: high entropy La1-xSrx(Co,Cr,Fe,Mn,Ni)O3-\u03b4 (x = 0, 0.1, 0.2, 0.3) perovskites synthesized by the sol-gel method\u201d
\nJournal of Materials Chemistry A 8(46) (2020) 24455-24468
\nIF 12.732<\/p>\n

2 A. Klimkowicz, T. Hashizume, K. Cichy, Y. Tamura, K. \u015awierczek, A. Takasaki, T. Motohashi, B. Dabrowski
\n\u201eOxygen separation from air by the combined temperature- and pressure-swing processes using oxygen storage materials Y1-x(Tb\/Ce)xMnO3+\u03b4\u201d
\nJournal of Materials Science 55(33) (2020) 15653-15666
\nIF 4.220<\/p>\n

3. A. Niemczyk, K. Zheng, K. Cichy, K. Berent, K. K\u00fcsterd, U. Starke, B. Poudel, B. Dabrowski, K. \u015awierczek
\n\u201eHigh Cu content LaNi1-xCuxO3-\u03b4 perovskites as candidate air electrode materials for reversible Solid Oxide Cells\u201d
\nInternational Journal of Hydrogen Energy 45(53) (2020) 29449-29464
\nIF 5.816<\/p>\n

4. J. D\u0105browa, M. Szymczak, M. Zajusz, A. Miku\u0142a, M. Mo\u017adzierz, K. Berent, M. Wytrwal-Sarna, A. Bernasik, M. Stygar, K. \u015awierczek
\n\u201eStabilizing fluorite structure in ceria-based high-entropy oxides: Influence of Mo addition on crystal structure and transport properties\u201d
\nJournal of the European Ceramic Society 40(15) (2020) 5870-5881
\nIF 5.302<\/p>\n

5. Z. Du, K. Li, H. Zhao, X. Dong, Y. Zhang, K. \u015awierczek
\n\u201eSmBaCo2O5+\u03b4 double perovskite with epitaxially grown Sm0.2Ce0.8O1.9 nanoparticles as the promising cathode for solid oxide fuel cells\u201d
\nJournal of Materials Chemistry A 8(28) (2020) 14162-14170
\nIF 12.732<\/p>\n

6. A. Mielewczyk-Gry\u0144, S. Wachowski, A. Witkowska, K. Dzierzgowski, W. Skubida, K. \u015awierczek, A. Regoutz, D.J. Payne, S. Hull, H. Zhang, I. Abrahams, M. Gazda
\n\u201eAntimony substituted lanthanum orthoniobate proton conductor \u2013 Structure and electronic properties\u201d
\nJournal of the American Ceramic Society 103(11) (2020) 6575-6585
\nIF 3.784<\/p>\n

7. K.A. Bogdanowicz, B. Jew\u0142oszewicz, A. Iwan, K. Dysz, W. Przyby\u0142, A. Januszko, M. Marzec, K. Cichy, K. \u015awierczek, L. Kavan, M. Zukalov\u00e1, V. Nadazdy, R. Subair, E. Majkova, M. Mi\u010du\u0161\u00edk, M. Omastov\u00e1, M.D. \u00d6zeren, K. Kamar\u00e1s, D.Y. Heo, S.Y. Kim
\n\u201eSelected electrochemical properties of 4,4′-((1E,1’E)-((1,2,4-thiadiazole-3,5-diyl)bis(azaneylylidene))bis(methaneylylidene))bis(N,N-di-p-tolylaniline) towards perovskite solar cells with 14.4% efficiency\u201d
\nMaterials 13(11) (2020) 2440
\nIF 3.623<\/p>\n

8. B. G\u0119dziorowski, A. Niemczyk, A. Olszewska, K. Cichy, K. \u015awierczek
\n\u201eInsight into physicochemical properties of Nd2CuO4\u00b1\u03b4 and the A-site cation deficient Nd1.9CuO4\u00b1\u03b4 layered oxides\u201d
\nFunctional Materials Letters 13(6) (2020) 2051034
\nIF 2.170<\/p>\n

9. B. G\u0119dziorowski, K. Cichy, A. Niemczyk, A. Olszewska, Z. Zhang, S. Kope\u0107, K. Zheng, M. Marzec, M. Gajewska. Z. Du, H. Zhao, K. \u015awierczek
\n\u201eRuddlesden-Popper-type Nd2-xNi1-yCuyO4\u00b1\u03b4 layered oxides as candidate materials for MIEC-type ceramic membranes\u201d
\nJournal of the European Ceramic Society 40(12) (2020) 4056-4066
\nIF 5.302<\/p>\n

10. A. Olszewska, K. \u015awierczek, A. Niemczyk
\n\u201ePeculiar properties of electrochemically oxidized SmBaCo2-xMnxO5+\u03b4 (x = 0; 0.5 and 1) A-site ordered perovskites\u201d
\nCrystals 10(3) (2020) 205
\nIF 2.589<\/p>\n

11. W. Skubida, K. Zheng, K. \u015awierczek, M. Michna, \u0141. Kondracki
\n\u201eIndium doping in SrCeO3 proton-conducting perovskites\u201d
\nJournal of Solid State Chemistry 284 (2020) 121210
\nIF 3.498<\/p>\n

12. G. Zhang, Q. Xu, Y. Liu, Q. Qin, J. Zhang, K. Qi, J. Chen, Z. Wang, K. Zheng, K. S\u0301wierczek, W. Zheng
\n\u201eRed phosphorus as self-template to hierarchical nanoporous nickel phosphides toward enhanced electrocatalytic activity for oxygen evolution reaction\u201d
\nElectrochimica Acta 332 (2020) 135500
\nIF 6.901<\/p>\n

13. J. Cebulski, D. Pasek, M. Bik, K. \u015awierczek, P. Jele\u0144, K. Mroczka, J. D\u0105browa, M. Zajusz, J. Wyrwa, M. Sitarz
\n\u201eIn-situ XRD investigations of FeAl intermetallic phase-based alloy oxidation\u201d
\nCorrosion Science 164 (2020) 108344
\nIF 7.205<\/p>\n

14. M. Stygar, J. D\u0105browa, M. Mo\u017adzierz, M. Zajusz, W. Skubida, K. Mroczka, K. Berent, K. \u015awierczek, M. Danielewski
\n\u201eFormation and properties of high entropy oxides in Co-Cr-Fe-Mg-Mn-Ni-O system: novel (Cr,Fe,Mg,Mn,Ni)3O4 and (Co,Cr,Fe,Mg,Mn)3O4 high entropy spinels\u201d
\nJournal of the European Ceramic Society 40(4) (2020) 1644-1650
\nIF 5.302<\/p>\n

15. Z. Grzesik, G. Smo\u0142a, M. Miszczak, M. Stygar, J. D\u0105browa, M. Zajusz, K. \u015awierczek, M. Danielewski
\n\u201eDefect structure and transport properties of (Co,Cr,Fe,Mn,Ni)3O4 spinel-structured high entropy oxide\u201d
\nJournal of the European Ceramic Society 40(3) (2020) 835-839
\nIF 5.302<\/div><\/div><\/div>

<\/i><\/i><\/span>2019<\/span><\/a><\/h4><\/div>
\n

1. A. Niemczyk, Z. Du, A. Olszewska, M. Marzec, M. Gajewska, K. \u015awierczek, H. Zhao, B. Poudel, B. Dabrowski
\n\u201eEffective oxygen reduction on A-site substituted LaCuO3-\u03b4: Toward air electrodes for SOFCs based on perovskite-type copper oxides\u201d
\nJournal of Materials Chemistry A 7(48) (2019) 27403-27416
\nIF 11.301<\/p>\n

2. A. Olszewska, Y. Zhang, Z. Du, M. Marzec, K. \u015awierczek, H. Zhao, B. Dabrowski
\n\u201eMn-rich SmBaCo0.5Mn1.5O5+\u03b4 double perovskite cathode material for SOFCs\u201d
\nInternational Journal of Hydrogen Energy 44(50) (2019) 27587-27599
\nIF 4.939<\/p>\n

3. Y. Zhang, H. Zhao, Z. Du, K. \u015awierczek, Y. Li
\n\u201eHigh-performance SmBaMn2O5+\u03b4 electrode for symmetrical solid oxide fuel cell\u201d
\nChemistry of Materials 31(10) (2019) 3784-3793
\nIF 9.567<\/p>\n

4. Z. Liu, K. Li, H. Zhao, K. \u015awierczek
\n\u201eHigh-performance oxygen permeation membranes: cobalt-free Ba0.975La0.025Fe1-xCuxO3-\u03b4 ceramics\u201d
\nJournal of Materiomics 5(2) (2019) 264-272
\nIF 5.797<\/p>\n

5. S. Zhang, H. Zhao, J. Guo, Z. Du, J. Wang, K. \u015awierczek
\n\u201eCharacterization of Sr-doped lithium lanthanum titanate with improved transport properties\u201d
\nSolid State Ionics 336 (2019) 39-46
\nIF 3.107<\/p>\n

6. L. Zhao, H. Zhao, Z. Du, J. Wang, X. Long, Z. Li, K. \u015awierczek
\n\u201eDelicate lattice modulation enables superior Na storage performance of Na3V2(PO4)3 as both an anode and cathode material for sodium-ion batteries: understanding the role of calcium substitution for vanadium\u201d
\nJournal of Materials Chemistry A 7(16) (2019) 9807-9814
\nIF 11.301<\/p>\n

7. K. Kornaus, R. Lach, M. Szumera, K. \u015awierczek, A. Gubernat
\n\u201eSynthesis of aluminium titanate by means of isostructural heterogeneous nucleation\u201d
\nJournal of the European Ceramic Society 39(7) (2019) 2535-2544
\nIF 4.495<\/p>\n

8. A. Klimkowicz, K. Cichy, O. Chmaissem, B. Dabrowski, B. Poudel, K. \u015awierczek, K.M. Taddei, A. Takasaki
\n\u201eReversible oxygen intercalation in hexagonal Y0.7Tb0.3MnO3+\u03b4: Toward the oxygen production by temperature-swing absorption in air\u201d
\nJournal of Materials Chemistry A 7(6) (2019) 2608-2618
\nIF 11.301<\/p>\n

9. A. Olszewska, K. \u015awierczek, W. Skubida, Z. Du, H. Zhao, B. Dabrowski
\n\u201eVersatile application of redox processes for REBaCoMnO5+\u03b4 (RE: La, Pr, Nd, Sm, Gd and Y) oxides\u201d
\nJournal of Physical Chemistry C 123(1) (2019) 48-61
\nIF 4.189<\/p>\n

10. T. Yang, H. Zhao, M. Fang, K. \u015awierczek, J. Wang, Z. Du
\n\u201eA new family of Cu-doped lanthanum silicate apatites as electrolyte materials for SOFCs: synthesis, structural and electrical properties\u201d
\nJournal of the European Ceramic Society 39(2-3) (2019) 424-431
\nIF 4.495<\/p>\n

11. M. Odziomek, F. Chaput, F. Lerouge, A. Rutkowska, K. \u015awierczek, D. Carlier, M. Sitarz, S. Parola
\n\u201eImpact of the synthesis parameters on the microstructure of nano-structured LTO prepared by glycothermal routes and 7Li NMR structural investigations\u201d
\nJournal of Sol-Gel Science and Technology 89(1) (2019) 225-233
\nIF 2.008<\/p>\n<\/div><\/div><\/div>

<\/i><\/i><\/span>2018<\/span><\/a><\/h4><\/div>
\n

1. A. Milewska, K. \u015awierczek, W. Zaj\u0105c, J. Molenda
\n\u201eOvercoming transport and electrochemical limitations in the high-voltage
\nNa0.67Ni0.33Mn0.67-yTiyO2 (0 \u2264 y \u2264 0.33) cathode materials by Ti-doping\u201d
\nJournal of Power Sources 404 (2018) 39-46
\nIF 7.467<\/p>\n

2. Z. Du, Z. Zhang, A. Niemczyk, A. Olszewska, N. Chen, K. \u015awierczek, H. Zhao
\n\u201eUnveiling the effects of A-site substitutions on the oxygen ions migration in A2-xA\u2019xNiO4+\u03b4 by first principles calculations\u201d
\nPhysical Chemistry Chemical Physics 20(33) (2018) 21685-21692
\nIF 3.567<\/p>\n

3. A. Niemczyk, A. Olszewska, Z. Du, Z. Zhang, K. \u015awierczek, H. Zhao
\n\u201eAssessment of layered La2-x(Sr,Ba)xCuO4-\u03b4 oxides as potential cathode materials for SOFCs\u201d
\nInternational Journal of Hydrogen Energy 43(32) (2018) 15492-15504
\nIF 4.084<\/p>\n

4. L. Zhao, H. Zhao, Z. Du, N. Chen, X. Chang, Z. Zhang, F. Gao, A. Trenczek-Zaj\u0105c,
\nK. \u015awierczek
\n\u201eComputational and experimental understanding of Al-doped Na3V2-xAlx(PO4)3 cathode material for sodium ion batteries: electronic structure, ion dynamics and electrochemical properties\u201d
\nElectrochimica Acta 282 (2018) 510-519
\nIF 5.383<\/p>\n

5. A. Olszewska, Z. Du, K. \u015awierczek, H. Zhao, B. Dabrowski
\n\u201eNovel ReBaCo1.5Mn0.5O5+\u03b4 (Re = La, Pr, Nd, Sm, Gd and Y) perovskite oxide: influence of manganese doping on crystal structure, oxygen nonstoichiometry, thermal expansion, transport properties, and application as cathode materials in Solid Oxide Fuel Cells\u201d
\nJournal of Materials Chemistry A 6(27) (2018) 13271-13285
\nIF 10.733<\/p>\n

6. K. Zheng, K. \u015awierczek
\n\u201ePossibility of determination of transport coefficients D and K from relaxation experiments for sphere-shaped powder samples\u201d
\nSolid State Ionics 323 (2018) 157-165
\nIF 2.886<\/p>\n

7. W. Skubida, A. Niemczyk, K. Zheng, X. Liu, K. \u015awierczek
\n\u201eCrystal structure, hydration and two-fold\/single-fold diffusion kinetics in proton-conducting Ba0.9La0.1Zr0.25Sn0.25In0.5O3-a oxide\u201d
\nCrystals 8(3) (2018) 136
\nIF 2.061<\/p>\n

8. K. Cichy, W. Skubida, K. \u015awierczek
\n\u201eStructural transformations, water incorporation and transport properties of tin-substituted barium indate\u201d
\nJournal of Solid State Chemistry 262 (2018) 58-67
\nIF 2.291<\/p>\n

9. Z. Du, H. Zhao, S. Li, Y. Zhang, X. Chang, Q. Xia, N. Chen, L. Gu, K. \u015awierczek, Y. Li, T. Yang, K. An
\n\u201eExceptionally high performance anode material based on lattice structure decorated double perovskite Sr2FeMo2\/3Mg1\/3O6-\u03b4 for Solid Oxide Fuel Cells\u201d
\nAdvanced Energy Materials 8(18) (2018) 1800062
\nIF 24.884<\/p>\n

10. Z. Zhang, Z. Du, A. Niemczyk, K. Li, H. Zhao, K. \u015awierczek
\n\u201eA-site nonstoichiometry and B-site doping with selected M3+ cations in
\nLa2-xCu1-y-zNiyMzO4-\u03b4 layered oxides\u201d
\nSolid State Ionics 317 (2018) 26-31
\nIF 2.886<\/p>\n

11. A. Klimkowicz, K. \u015awierczek, S. Kobayashi, A. Takasaki, W. Allahyani, B. Dabrowski
\n\u201eImprovement of oxygen storage properties of hexagonal YMnO3+\u03b4 by microstructural modifications\u201d
\nJournal of Solid State Chemistry 258 (2018) 471-476
\nIF 2.291<\/p>\n

12. Z. Zhang, H. Zhao, Y. Teng, X. Chang, Q. Xia, Z. Li, J. Fang, Z. Du, K. \u015awierczek
\n\u201eCarbon-sheathed MoS2 nanothorns epitaxially grown on CNTs: electrochemical application for highly-stable and ultrafast lithium storage\u201d
\nAdvanced Energy Materials 8(7) (2018) 1700174
\nIF 24.884<\/p>\n

13. G. Grabowski, R. Lach, Z. P\u0119dzich, K. \u015awierczek, A. Wojteczko
\n\u201eAnisotropy of thermal expansion of 3Y-TZP, \u03b1-Al2O3 and composites from 3Y-TZP\/\u03b1-Al2O3 system\u201d
\nArchives of Civil and Mechanical Engineering 18(1) (2018) 188-197
\nIF 2.846<\/p>\n<\/div><\/div><\/div>

<\/i><\/i><\/span>2017<\/span><\/a><\/h4><\/div>
1. Z. Du, C. Yan, H. Zhao, Y. Zhang, C. Yang, S. Yi, Y. Lu, K. \u015awierczek
\n\u201eEffective Ca-doping in Y1-xCaxBaCo2O5+\u03b4 cathode materials for Intermediate Temperature Solid Oxide Fuel Cells\u201d
\nJournal of Materials Chemistry A 5(48) (2017) 25641-25651
\nIF 9.931<\/p>\n

2. Z. Zhang, H. Zhao, Z. Du, X. Chang, L. Zhao, X. Du, Z. Li, Y. Teng, J. Fang,
\nK. \u015awierczek
\n\u201e(101) plane-oriented SnS2 nanoplates with carbon coating: a high-rate and cycle-stable anode material for lithium ion batteries\u201d
\nACS Applied Materials & Interfaces 9(41) (2017) 35880-35887
\nIF 8.097<\/p>\n

3. \u0141. Kondracki, A. Kulka, K. \u015awierczek, M. Zi\u0105bka, J. Molenda
\n\u201eOperando X-ray diffraction studies as a tool for determination of transport parameters of mobile ions in electrode materials\u201d
\nJournal of Power Sources 369 (2017) 1-5
\nIF 6.945<\/p>\n

4. J. Suchanicz, K. \u015awierczek, D. Sitko, P. Czaja, P. Marchet, H. Czternastek, D. Majda
\n\u201eThe effects of PbZn1\/3Nb2\/3O3-doping on structural, thermal, optical, dielectric and ferroelectric properties of BaTiO3 ceramics\u201d
\nJournal of Applied Physics 122(12) (2017) 124105-1-7
\nIF 2.176<\/p>\n

5. K. \u015awierczek, A. Klimkowicz, K. Nishihara, S. Kobayashi, A. Takasaki, M. Alanizy,
\nS. Kolesnik, B. Dabrowski, S. Seong, J. Kang
\n\u201eOxygen storage properties of hexagonal HoMnO3+\u03b4\u201d
\nPhysical Chemistry Chemical Physics 19(29) (2017) 19243-19251
\nIF 3.906<\/p>\n

6. K. \u015awierczek, W. Skubida, A. Niemczyk, A. Olszewska, K. Zheng
\n\u201eStructure and transport properties of proton-conducting BaSn0.5In0.5O2.75 and A-site substituted Ba0.9Ln0.1Sn0.5In0.5O2.8 (Ln = La, Gd) oxides\u201d
\nSolid State Ionics 307 (2017) 44-50
\nIF 2.751<\/p>\n

7. Y. Teng, H. Zhao, Z. Zhang, L. Zhao, Y. Zhang, Z. Li, Q. Xia, Z. Du, K. \u015awierczek
\n\u201eMoS2 nanosheets vertically grown on reduced graphene oxide via oxygen bonds with carbon coating as ultrafast sodium ion batteries anodes\u201d
\nCarbon 119 (2017) 91-100
\nIF 7.082<\/p>\n

8. J. Suchanicz, K. Konieczny, K. \u015awierczek, M. Lipi\u0144ski, M. Karpierz, D. Sitko,
\nH. Czternastek, K. Kluczewska
\n\u201eElectrical transport in low-lead (1-x)BaTiO3-xPbMg1\/3Nb2\/3O3 ceramics\u201d
\nJournal of Advanced Ceramics 6(3) (2017) 207-219
\nIF 1.605<\/p>\n

9. M. Odziomek, F. Chaput, A. Drobniak, K. \u015awierczek, D. Olszewska, M. Sitarz,
\nF. Lerouge, S. Parola
\n\u201eHierarchically-structured lithium titanate for ultrafast charging in long-life high capacity batteries\u201d
\nNature Communications 8 (2017) 15636
\nIF 12.353<\/p>\n

10. Y. Lu, H. Zhao, K. Li, X. Du, Y. Ma, X. Chang, N. Chen, K. Zheng, K. \u015awierczek
\n\u201eEffective calcium doping at the B-site of BaFeO3-\u03b4 perovskite: towards low-cost and high-performance oxygen permeation membranes\u201d
\nJournal of Materials Chemistry A 5(17) (2017) 7999-8009
\nIF 9.931<\/p>\n

11. J. Molenda, J. Kupecki, R. Baron, M. Blesznowski, G. Brus, T. Brylewski, M. Bu\u0107ko,
\nJ. Chmielowiec, K. \u0106wieka, M. Gazda, A. Gil, P. Jasi\u0144ski, Z. Jaworski, J. Karczewski,
\nM. Kawalec, R. Kluczowski, M. Krauz, F. Krok, B. \u0141ukasik, M. Ma\u0142ys, A. Mazur,
\nA. Mielewczyk-Gry\u0144, J. Milewski, S. Molin, G. Mordarski, M. Mosia\u0142ek, K. Motylinski, E.N. Naumovich, P. Nowak, G. Pa\u015bciak, P. Pianko-Oprych, D. Pomykalska, M. R\u0119kas,
\nA. \u015aci\u0105\u017cko, K. \u015awierczek, J. Szmyd, S. Wachowski, T. Wejrzanowski, W. Wr\u00f3bel,
\nK. Zagorski, W. Zaj\u0105c, A. \u017burawska
\n\u201eStatus report on high temperature fuel cells in Poland – Recent advances and achievements\u201d
\nInternational Journal of Hydrogen Energy 42(7) (2017) 4366-4403
\nIF 4.229<\/p>\n

12. A. Klimkowicz, K. \u015awierczek, K. Zheng, D. Wallacher, A. Takasaki
\n\u201eOxygen release from BaLnMn2O6 (Ln: Pr, Nd, Y) under reducing conditions as studied by neutron diffraction\u201d
\nJournal of Materials Science 52(11) (2017) 6476-6485
\nIF 2.993<\/p>\n

13. X. Du, H. Zhao, Y. Lu, Z. Zhang, A. Kulka, K. \u015awierczek
\n\u201eSynthesis of core-shell-like ZnS\/C nanocomposite as improved anode material for lithium ion batteries\u201d
\nElectrochimica Acta 228 (2017) 100-106
\nIF 5.116<\/p>\n

14. X. Du, H. Zhao, Z. Zhang, Y. Lu, C. Gao, Z. Li, Y. Teng, L. Zhao, K. \u015awierczek
\n\u201eCore-shell structured ZnS-C nanoparticles with enhanced electrochemical properties for high-performance lithium-ion battery anodes\u201d
\nElectrochimica Acta 225 (2017) 129-136
\nIF 5.116<\/p>\n

15. A. Trenczek-Zaj\u0105c, J. Bana\u015b, K. \u015awierczek, K. Zazakowny, M. Radecka
\n\u201ePhotosensitization of TiO2 P25 with CdS nanoparticles for photocatalytic applications\u201d
\nArchives of Metallurgy and Materials 62(2) (2017) 841-849
\nIF 0.625<\/div><\/div><\/div>

<\/i><\/i><\/span>2016<\/span><\/a><\/h4><\/div>
1. A. Klimkowicz, K. \u015awierczek, T. Yamazaki, A. Takasaki
\n\u201eEnhancement of the oxygen storage properties of BaPrMn2O5+\u03b4 and BaSmMn2O5+\u03b4 oxides by a high-energy milling\u201d
\nSolid State Ionics 298 (2016) 66-72
\nIF 2.354<\/p>\n

2. Y. Teng, H. Zhao, Z. Zhang, Z. Li, Q. Xia, Y. Zhang, L. Zhao, X. Du, Z. Du, P. Lv,
\nK. \u015awierczek
\n\u201eMoS2 nanosheets vertically grown on graphene sheets for lithium ion battery anodes\u201d
\nACS Nano 10(9) (2016) 8526-8535
\nIF 13.942<\/p>\n

3. Z. Du, H. Zhao, S. Yi, Q. Xia, Y. Gong, Y. Zhang, X. Cheng, Y. Li, L. Gu, K. \u015awierczek
\n\u201eHigh performance anode material Sr2FeMo0.65Ni0.35O6-\u03b4 with in situ exsolved nanoparticle catalyst\u201d
\nACS Nano 10(9) (2016) 8660-8669
\nIF 13.942<\/p>\n

4. K. Zheng, K. \u015awierczek
\n\u201eEvaluation of La2Ni0.5Cu0.5O4+\u03b4 and Pr2Ni0.5Cu0.5O4+\u03b4 Ruddlesden-Popper-type layered oxides as cathode materials for Solid Oxide Fuel Cells\u201d
\nMaterials Research Bulletin 84 (2016) 259-266
\nIF 2.446<\/p>\n

5. Z. Zhang, H. Zhao, Q. Xia, J. Allen, Z. Zeng, C. Gao, Z. Li, X. Du, K. \u015awierczek
\n\u201eHigh performance Ni3S2\/Ni film with three dimensional porous architecture as binder-free anode for lithium ion batteries\u201d
\nElectrochimica Acta 211 (2016) 761-767
\nIF 4.798<\/p>\n

6. Y. Lu, H. Zhao, X. Chang, X. Du, K. Li, Y. Ma, S. Yi, Z. Du, K. Zheng, K. \u015awierczek
\n\u201eNovel cobalt-free BaFe1-xGdxO3-\u03b4 perovskite membranes for oxygen separation\u201d
\nJournal of Materials Chemistry A 4(27) (2016) 10454-10466
\nIF 8.867<\/p>\n

7. W. Skubida, K. \u015awierczek
\n\u201eStructural properties and presence of protons in Ba0.9Gd0.1Zr1-x-ySnxInyO3-(y-0.1)\/2 perovskites\u201d
\nFunctional Materials Letters 9(4) (2016) 1641005
\nIF 1.234<\/p>\n

8. K. Zheng, K. \u015awierczek
\n\u201eA- and B-site doping effect on physicochemical properties of Sr2-xBaxMMoO6
\n(M = Mg, Mn, Fe) double perovskites – candidate anode materials for SOFCs\u201d
\nFunctional Materials Letters 9(4) (2016) 1641002
\nIF 1.234<\/p>\n

9. M.A. Macias, M.V. Sandoval, N.G. Martinez, S. V\u00e1zquez-Cuadriello, L. Suescun,
\nP. Roussel, K. \u015awierczek, G.H. Gauthier
\n\u201eSynthesis and preliminary study of La4BaCu5O13+\u03b4 and La6.4Sr1.6Cu8O20\u00b1\u03b4 ordered perovskites as SOFC\/PCFC electrode materials\u201d
\nSolid State Ionics 288 (2016) 68-75
\nIF 2.354<\/p>\n

10. A. Klimkowicz, K. \u015awierczek, T. Rz\u0105sa, A. Takasaki, B. Dabrowski
\n\u201eOxygen storage properties and catalytic activity of layer-ordered perovskites
\nBaY1-xGdxMn2O5+\u03b4\u201d
\nSolid State Ionics 288 (2016) 43-47
\nIF 2.354<\/p>\n

11. A. Kulka, K. \u015awierczek, K. Walczak, A. Braun, J. Molenda
\n\u201eCorrelation between transport properties and lithium extraction\/insertion mechanism
\nin Fe-site substituted phospholivine\u201d
\nSolid State Ionics 288 (2016) 184-192
\nIF 2.354<\/p>\n

12. O.L. Pineda, Z.L. Moreno, P. Roussel, K. \u015awierczek, G.H. Gauthier
\n\u201eSynthesis and preliminary study of the double perovskite NdBaMn2O5+\u03b4 as symmetric SOFC electrode material\u201d
\nSolid State Ionics 288 (2016) 61-67
\nIF 2.354<\/p>\n

13. K. Zheng, K. \u015awierczek
\n\u201eEvaluation of W-containing Sr1-xBaxFe0.75W0.25O3-\u03b4 (x = 0, 0.5, 1) anode materials for Solid Oxide Fuel Cells\u201d
\nSolid State Ionics 288 (2016) 124-129
\nIF 2.354<\/p>\n

14. Q. Xia, H. Zhao, Z. Du, Z. Zhang, S. Li, C. Gao, K. \u015awierczek
\n\u201eDesign and synthesis of 3-D hierarchical molybdenum dioxide\/nickel\/carbon structured composite with superior cycling performance for lithium ion batteries\u201d
\nJournal of Materials Chemistry A 4(2) (2016) 605-611
\nIF 8.867<\/div><\/div><\/div>

<\/i><\/i><\/span>2015<\/span><\/a><\/h4><\/div>
1. Q. Xia, H. Zhao, Z. Du, Z. Zeng, C. Gao, Z. Zhang, X. Du, A. Kulka, K. \u015awierczek
\n\u201eFacile synthesis of MoO3\/carbon nanobelts as high-performance anode material for lithium ion batteries\u201d
\nElectrochimica Acta 180 (2015) 947-956
\nIF 4.803<\/p>\n

2. X. Liu, Y. Dai, J. Xie, H. Zhao, P. Lv, K. Wang, K. \u015awierczek
\n\u201eImprovement of silicon-based electrode for Li-ion batteries by formation of Si-TiB2-C nanocomposites\u201d
\nSolid State Ionics 281 (2015) 60-67
\nIF 2.380<\/p>\n

3. D. Baster, W. Maziarz, K. \u015awierczek, A. Stok\u0142osa, J. Molenda
\n\u201eStructural and electrochemical properties of Na0.72CoO2 as cathode material for sodium-ion batteries\u201d
\nJournal of Solid State Electrochemistry 19(12) (2015) 3605-3612
\nIF 2.327<\/p>\n

4. K. Zheng, K. \u015awierczek, J.M. Polfus, M.F. Sunding, M. Pishahang, T. Norby
\n\u201eCarbon deposition and sulfur poisoning in SrFe0.75Mo0.25O3-\u03b4 and SrFe0.5Mn0.25Mo0.25O3-\u03b4 electrode materials for symmetrical SOFCs\u201d
\nJournal of the Electrochemical Society 162(9) (2015) F1078-F1087
\nIF 3.014<\/p>\n

5. K. Zheng, A. Klimkowicz, K. \u015awierczek, A. Malik, Y. Ariga, T. Tominaga, A. Takasaki
\n\u201eChemical diffusion and surface exchange in selected Ln-Ba-Sr-Co-Fe perovskite-type oxides\u201d
\nJournal of Alloys and Compounds 645(S1) (2015) S357-S360
\nIF 3.014<\/p>\n

6. T. Tominaga, A. Takasaki, T. Shibato, K. \u015awierczek
\n\u201eHREM observation and high-pressure composition isotherm measurement of Ti45Zr38Ni17 quasicrystal powders synthesized by mechanical alloying\u201d
\nJournal of Alloys and Compounds 645(S1) (2015) S292-S294
\nIF 3.014<\/p>\n

7. Y. Ariga, A. Takasaki, T. Kimijima, K. \u015awierczek
\n\u201eElectrochemical properties of Ti49Zr26Ni25-xPdx (x = 0-6) quasicrystal electrodes produced by mechanical alloying\u201d
\nJournal of Alloys and Compounds 645(S1) (2015) S152-S154
\nIF 3.014<\/p>\n

8. A. Klimkowicz, A. Takasaki, \u0141. Gondek, H. Figiel, K. \u015awierczek
\n\u201eHydrogen desorption properties of magnesium hydride catalyzed multiply with carbon and silicon\u201d
\nJournal of Alloys and Compounds 645(S1) (2015) S80-S83
\nIF 3.014<\/p>\n

9. F. Yang, H. Zhao, J. Yang, M. Fang, Y. Lu, Z. Du, K. \u015awierczek, K. Zheng
\n\u201eStructure and oxygen permeability of BaCo0.7Fe0.3-xInxO3-\u03b4 ceramic membranes\u201d
\nJournal of Membrane Science 492 (2015) 559-567
\nIF 5.557<\/p>\n

10. K. \u015awierczek, W. Zaj\u0105c, A. Klimkowicz, K. Zheng, N. Malikova, B. Dabrowski
\n\u201eCrystal structure and proton conductivity in highly oxygen-deficient
\nBa1-xLax(In,Zr,Sn)O3-\u03b4 perovskites\u201d
\nSolid State Ionics 275 (2015) 58-61
\nIF 2.380<\/p>\n

11. Y. Lu, H. Zhao, X. Cheng, Y. Jia, X. Du, M. Fang, Z. Du, K. Zheng, K. \u015awierczek
\n\u201eInvestigation of In-doped BaFeO3-\u03b4 perovskite-type oxygen permeable membranes\u201d
\nJournal of Materials Chemistry A 3(11) (2015) 6202-6214
\nIF 8.262<\/p>\n

12. A. Klimkowicz, K. \u015awierczek, A. Takasaki, J. Molenda, B. Dabrowski
\n\u201eCrystal structure and oxygen storage properties of BaLnMn2O5+\u03b4 (Ln: Pr, Nd, Sm, Gd, Dy, Er and Y) oxides\u201d
\nMaterials Research Bulletin 65 (2015) 116-122
\nIF 2.435<\/p>\n

13. J. Suchanicz, K. \u015awierczek, E. Nogas-\u0106wikiel, K. Konieczny, D. Sitko
\n\u201ePbMg1\/3Nb2\/3O3 -doping effects on structural, thermal, Raman, dielectric and ferroelectric properties of BaTiO3 ceramics\u201d
\nJournal of the European Ceramic Society 35(6) (2015) 1777-1783
\nIF 2.933<\/p>\n

14. B. \u0141yso\u0144-Sypie\u0144, M. Radecka, M. R\u0119kas, K. \u015awierczek, K. Michalow-Mauke, T. Graule, K. Zakrzewska
\n\u201eGrain-size-dependent gas-sensing properties of TiO2 nanomaterials\u201d
\nSensors and Actuators B-Chemical 211 (2015) 67-76
\nIF 4.758<\/p>\n

15. J. Molenda, D. Baster, A. Milewska, K. \u015awierczek, D.K. Bora, A. Braun, J. Tobo\u0142a
\n\u201eElectronic origin of difference in discharge curve between LixCoO2 and NaxCoO2 cathodes\u201d
\nSolid State Ionics 271 (2015) 15-27
\nIF 2.380<\/p>\n

16. A. Kulka, A. Braun, T.-W. Huang, A. Wolska, M.T. Klepka, A. Szewczyk, D. Baster,
\nW. Zaj\u0105c, K. \u015awierczek, J. Molenda
\n\u201eEvidence for Al doping in lithium sublattice of LiFePO4\u201d
\nSolid State Ionics 270 (2015) 33-38
\nIF 2.380<\/p>\n

17. X. Liu, J. Xie, H. Zhao, P. Lv, K. Wang, Z. Feng, K. \u015awierczek
\n\u201eElectrochemical properties of mechanochemically synthesized CoSn2-C nanocomposite-type anode material for Li-ion batteries\u201d
\nSolid State Ionics 269 (2015) 86-92
\nIF 2.380<\/p>\n

18. X. Liu, H. Zhao, A. Kulka, A. Trenczek-Zaj\u0105c, J. Xie, N. Chen, K. \u015awierczek
\n\u201eCharacterization of physicochemical properties of novel SnS2 with cubic structure and diamond-like Sn sublattice\u201d
\nActa Materialia 82 (2015) 212-223
\nIF 5.058<\/div><\/div><\/div>

<\/i><\/i><\/span>2014<\/span><\/a><\/h4><\/div>
1. K. \u015awierczek, A. Klimkowicz, A. Niemczyk, A. Olszewska, T. Rz\u0105sa, J. Molenda,
\nA. Takasaki
\n\u201eOxygen storage-related properties of substituted BaLnMn2O5+\u03b4 A-site ordered manganites\u201d
\nFunctional Materials Letters 7(6) (2014) 1440004
\nIF 1.606<\/p>\n

2. K. Zheng, K. \u015awierczek
\n\u201ePhysicochemical properties of rock salt-type ordered Sr2MMoO6 (M = Mg, Mn, Fe, Co, Ni) double perovskites\u201d
\nJournal of the European Ceramic Society 34(16) (2014) 4273-4284
\nIF 2.947<\/p>\n

3. J. Molenda, D. Baster, M. Molenda, K. \u015awierczek, J. Tobo\u0142a
\n\u201eAnomaly in electronic structure of NaxCoO2-y cathode as a source of its step-like discharge curve\u201d
\nPhysical Chemistry Chemical Physics 16(28) (2014) 14845-14857
\nIF 4.493<\/p>\n

4. A. Milewska, K. \u015awierczek, J. Tobola, F. Boudoire, Y. Hu, D.K. Bora, B.S. Mun,
\nA. Braun, J. Molenda
\n\u201eThe nature of the nonmetal-metal transition in LixCoO2 oxide\u201d
\nSolid State Ionics 263 (2014) 110-118
\nIF 2.561<\/p>\n

5. B. G\u0119dziorowski, \u0141. Kondracki, K. \u015awierczek, J. Molenda
\n\u201eStructural and transport properties of Li1+xV1-xO2 anode materials for Li-ion batteries\u201d
\nSolid State Ionics 262 (2014) 124-127
\nIF 2.561<\/p>\n

6. D. Baster, K. Dybko, M. Szot, K. \u015awierczek, J. Molenda
\n\u201eSodium intercalation in NaxCoO2-y – correlation between crystal structure, oxygen nonstoichiometry and electrochemical properties\u201d
\nSolid State Ionics 262 (2014) 206-210
\nIF 2.561<\/p>\n

7. K. Zheng, K. \u015awierczek, J. Bratek, A. Klimkowicz
\n\u201eCation-ordered perovskite-type anode and cathode materials for Solid Oxide Fuel Cells\u201d
\nSolid State Ionics 262 (2014) 354-358
\nIF 2.561<\/p>\n

8. A. Klimkowicz, K. \u015awierczek, K. Zheng, M. Baranowska, A. Takasaki, B. Dabrowski
\n\u201eEvaluation of BaY1-xPrxMn2O5+\u03b4 oxides for oxygen storage technology\u201d
\nSolid State Ionics 262 (2014) 659-663
\nIF 2.561<\/p>\n

9. K. \u015awierczek, N. Yoshikura, K. Zheng, A. Klimkowicz
\n\u201eCorrelation between crystal and transport properties in LnBa0.5Sr0.5Co1.5Fe0.5O5+\u03b4
\n(Ln – selected lanthanides, Y)\u201d
\nSolid State Ionics 262 (2014) 645-649
\nIF 2.561<\/p>\n

10. Z. Du, H. Zhao, Y. Shen, L. Wang, M. Fang, K. \u015awierczek, K. Zheng
\n\u201eEvaluation of La0.3Sr0.7Ti1-xCoxO3 as potential cathode material for Solid Oxide Fuel Cells\u201d
\nJournal of Materials Chemistry A 2(26) (2014) 10290-10299
\nIF 7.443<\/p>\n

11. K. Zheng, K. \u015awierczek, W. Zaj\u0105c, A. Klimkowicz
\n\u201eRock salt ordered-type double perovskite anode materials for Solid Oxide Fuel Cells\u201d
\nSolid State Ionics 257 (2014) 9-16
\nIF 2.561<\/p>\n

12. A. Klimkowicz, K. \u015awierczek, A. Takasaki, B. Dabrowski
\n\u201eOxygen storage capability in Co- and Fe-containing perovskite-type oxides\u201d
\nSolid State Ionics 257 (2014) 23-28
\nIF 2.561<\/p>\n

13. Y. Shen, H. Zhao, J. Xu, X. Zhang, K. Zheng, K. \u015awierczek
\n\u201eEffect of ionic size of dopants on the lattice structure, electrical and electrochemical
\nproperties of La2-xMxNiO4+\u03b4 (M = Ba, Sr) cathode materials\u201d
\nInternational Journal of Hydrogen Energy 39(2) (2014) 1023-1029
\nIF 3.313<\/div><\/div><\/div>

<\/i><\/i><\/span>2013<\/span><\/a><\/h4><\/div>
1. H. Zhao, Y. Zheng, C. Yang, Y. Shen, Z. Du, K. \u015awierczek
\n\u201eElectrochemical performance of Pr1-xYxBaCo2O5+\u03b4 layered perovskites as cathode materials for intermediate-temperature solid oxide fuel cells\u201d
\nInternational Journal of Hydrogen Energy 38(36) (2013) 16365-16372
\nIF 2.930<\/p>\n

2. D. Baster, A. Takasaki, C. Kuroda, E. Hanc, S.-H. Lee, K. \u015awierczek, J.S. Szmyd,
\nJ.-Y. Kim, J. Molenda
\n\u201eEffect of mechanical milling on electrochemical properties of Ti45Zr38-xNi17+x (x = 0, 8) quasicrystals produced by rapid-quenching\u201d
\nJournal of Alloys and Compounds 580(S1) (2013) S238-S242
\nIF 2.726<\/p>\n

3. A. Kulka, D. Baster, M. Dudek, M. Kie\u0142basa, A. Milewska, W. Zaj\u0105c, K. \u015awierczek,
\nJ. Molenda
\n\u201eElectrochemical properties of chemically modified phosphoolivines as cathode materials
\nfor Li-ion batteries\u201d
\nJournal of Power Sources 244 (2013) 565-569
\nIF 5.211<\/p>\n

4. Y. Shen, H. Zhao, K. \u015awierczek, Z. Du, Z. Xie
\n\u201eLattice structure, sintering behavior and electrochemical performance of
\nLa1.7Ca0.3Ni1-xCuxO4+\u03b4 as cathode material for intermediate-temperature solid oxide fuel cell\u201d
\nJournal of Power Sources 240 (2013) 759-765
\nIF 5.211<\/p>\n

5. A. Kusior, J. Klich-Kafel, A. Trenczek-Zaj\u0105c, K. \u015awierczek, M. Radecka, K. Zakrzewska
\n\u201eTiO2-SnO2 nanomaterials for gas sensing and photocatalysis\u201d
\nJournal of the European Ceramic Society 33(12) (2013) 2285-2290
\nIF 2.307<\/p>\n

6. K. \u015awierczek, A. Klimkowicz, K. Zheng, B. Dabrowski
\n\u201eSynthesis, crystal structure and electrical properties of A-site cation ordered BaErMn2O5 and BaErMn2O6\u201d
\nJournal of Solid State Chemistry 203 (2013) 68-73
\nIF 2.200<\/p>\n

7. J. Molenda, A. Kulka, A. Milewska, W. Zaj\u0105c, K. \u015awierczek
\n\u201eStructural, transport and electrochemical properties of LiFePO4 substituted in lithium and iron sublattices (Al, Zr, W, Mn, Co and Ni)\u201d
\nMaterials 6 (2013) 1656-1687
\nIF 1.879<\/p>\n

8. D. Baster, K. Zheng, W. Zaj\u0105c, K. \u015awierczek, J. Molenda
\n\u201eToward elucidation of delithiation mechanism of zinc-substituted LiFePO4\u201d
\nElectrochimica Acta 92 (2013) 79-86
\nIF 4.086<\/p>\n

9. C. Kuroda, K. Zheng, K. \u015awierczek
\n\u201eCharacterization of novel GdBa0.5Sr0.5Co2-xFexO5+\u03b4 perovskites for application in
\nIT-SOFC cells\u201d
\nInternational Journal of Hydrogen Energy 38(2) (2013) 1027-1038
\nIF 2.930<\/div><\/div><\/div>

<\/i><\/i><\/span>2012<\/span><\/a><\/h4><\/div>
1. K. Zheng, A. Gorzkowska-Soba\u015b, K. \u015awierczek
\n\u201eEvaluation of Ln2CuO4 (Ln: La, Pr, Nd) oxides as cathode materials for IT-SOFCs\u201d
\nMaterials Research Bulletin 47(12) (2012) 4089-4095
\nIF 1.913<\/p>\n

2. B. G\u0119dziorowski, K. \u015awierczek, J. Molenda
\n\u201eLa1-xBaxCo0.2Fe0.8O3-\u03b4 perovskites for application in intermediate temperature SOFCs\u201d
\nSolid State Ionics 225 (2012) 437-442
\nIF 2.046<\/p>\n

3. W. Zaj\u0105c, E. Hanc, A. Gorzkowska-Soba\u015b, K. \u015awierczek, J. Molenda
\n\u201eNd-doped Ba(Ce,Zr)O3-\u03b4 proton-conductors for application in conversion of CO2 into liquid fuels\u201d
\nSolid State Ionics 225 (2012) 297-303
\nIF 2.046<\/p>\n

4. A. Kulka, A. Milewska, W. Zaj\u0105c, K. \u015awierczek, E. Hanc, J. Molenda
\n\u201ePossibility of modification of phosphoolivine by substitution in Li sublattice\u201d
\nSolid State Ionics 225 (2012) 575-579
\nIF 2.046<\/p>\n

5. S. Kolesnik, B. Dabrowski, O. Chmaissem, S. Avci, J.P. Hodges, M. Avdeev,
\nK. \u015awierczek
\n\u201eEnhancement of the Curie temperature in NdBaCo2O5.5 by A-site Ca substitution\u201d
\nPhysical Review B 86(6) (2012) 064434
\nIF 3.767<\/p>\n

6. S. Kolesnik, B. Dabrowski, O. Chmaissem, K. Wojciechowski, K. \u015awierczek
\n\u201eComparison of magnetic and thermoelectric properties of (Nd,Ca)BaCo2O5.5 and (Nd,Ca)CoO3\u201d
\nJournal of Applied Physics 111(7) (2012) 07D727-1-3
\nIF 2.210<\/div><\/div><\/div>

<\/i><\/i><\/span>2011<\/span><\/a><\/h4><\/div>
1. K. \u015awierczek
\n\u201ePhysico-chemical properties of Ln0.5A0.5Co0.5Fe0.5O3-\u03b4 (Ln: La, Sm; A: Sr, Ba) cathode materials and their performance in electrolyte-supported intermediate temperature solid oxide fuel cell\u201d
\nJournal of Power Sources 196(17) (2011) 7110-7116
\nIF 4.951<\/p>\n

2. M. Kimura, K. \u015awierczek, J. Marzec, J. Molenda
\n\u201eInfluence of aluminum on physico-chemical properties of lithium iron phosphate\u201d
\nFunctional Materials Letters 4(2) (2011) 123-127
\nIF 0.724<\/p>\n

3. J. Han, K. Zheng, K. \u015awierczek
\n\u201eNickel-based layered perovskite cathode materials for application in Intermediate-Temperature Solid Oxide Fuel Cells\u201d
\nFunctional Materials Letters 4(2) (2011) 151-155
\nIF 0.724<\/p>\n

4. K. \u015awierczek
\n\u201eElectrolyte-supported IT-SOFC with LSCF – SCFN composite cathode\u201d
\nSolid State Ionics 192(1) (2011) 486-490
\nIF 2.646<\/div><\/div><\/div>

<\/i><\/i><\/span>Prace wcze\u015bniejsze<\/span><\/a><\/h4><\/div>
1. W. Zaj\u0105c, L. Suescun, K. \u015awierczek, J. Molenda
\n\u201eStructural and electrical properties of grain boundaries in Ce0.85Gd0.15O1.925 solid electrolyte modified by addition of transition metal ions\u201d
\nJournal of Power Sources 194(1) (2009) 2-9
\nIF 3.792<\/p>\n

2. M. Gozu, K. \u015awierczek, J. Molenda
\n\u201eStructural and transport properties of layered Li1+x(Mn1\/3Co1\/3Ni1\/3)1-xO2 oxides prepared by a soft chemistry method\u201d
\nJournal of Power Sources 194(1) (2009) 38-44
\nIF 3.792<\/p>\n

3. K. \u015awierczek
\n\u201eOxygen nonstoichiometry and transport properties of selected La1-xSrxCo1-y-zFeyNizO3-\u03b4 perovskites\u201d
\nPolish Journal of Chemistry 83(8) (2009) 1437-1442
\nIF 0.523<\/p>\n

4. K. \u015awierczek, J. Marzec
\n\u201eStructural properties of SrCo0.2Fe0.8O3-\u03b4 oxide: oxygen nonstoichiometry, vacancy ordering and broken local symmetry\u201d
\nPolish Journal of Chemistry 83(8) (2009) 1489-1496
\nIF 0.523<\/p>\n

5. J. Molenda, J. Krupi\u0144ski, W. Zaj\u0105c, K. \u015awierczek
\n\u201eEvaluation of La0.5Sr0.5Co0.5Fe0.25Mn0.25O3-\u03b4 perovskite-type oxide as the cathode material for Solid Oxide Fuel Cells\u201d
\nPolish Journal of Chemistry 83(8) (2009) 1497-1506
\nIF 0.523<\/p>\n

6. J.-S. Kang, H.J. Lee, D.H. Kim, S. Kolesnik, B. Dabrowski, K. \u015awierczek, J. Lee, B. Kim, B.I. Min
\n\u201eValence and spin states, and the metal-insulator transition in ferromagnetic
\nLa2-xSrxMnNiO6 (x = 0, 0.2)\u201d
\nPhysical Review B 80(4) (2009) 045115
\nIF 3.475<\/p>\n

7. K. \u015awierczek, B. Dabrowski, L. Suescun, S. Kolesnik
\n\u201eCrystal structure and magnetic properties of high oxygen pressure annealed
\nSr1-xLaxCo0.5Fe0.5O3-\u03b4 (0 \u2264 x \u2264 0.5)\u201d
\nJournal of Solid State Chemistry 182(2) (2009) 280-288
\nIF 2.340<\/p>\n

8. K. \u015awierczek
\n\u201eThermoanalysis, nonstoichiometry and thermal expansion of La0.4Sr0.6Co0.2Fe0.8O3-\u03b4, La0.2Sr0.8Co0.2Fe0.8O3-\u03b4, La0.9Sr0.1Co1\/3Fe1\/3Ni1\/3O3-\u03b4 and La0.6Sr0.4Co0.2Fe0.6Ni0.2O3-\u03b4 perovskites\u201d
\nSolid State Ionics 179(1-6) (2008) 126-130
\nIF 2.425<\/p>\n

9. M. Gateshki, L. Suescun, S. Kolesnik, J. Mais, K. \u015awierczek, S. Short, B. Dabrowski \u201eStructural, magnetic and electronic properties of LaNi0.5Fe0.5O3 in the temperature range 5 – 1000 K\u201d
\nJournal of Solid State Chemistry 181(8) (2008) 1833-1839
\nIF 1.910<\/p>\n

10. J. Molenda, K. \u015awierczek, W. Zaj\u0105c
\n\u201eFunctional materials for the IT-SOFC\u201d
\nJournal of Power Sources 173(2) (2007) 657-670
\nIF 2.809<\/p>\n

11. K. \u015awierczek, M. Gozu
\n\u201eStructural and electrical properties of selected La1\u2212xSrxCo0.2Fe0.8O3 and La0.6Sr0.4Co0.2Fe0.6Ni0.2O3 perovskite type oxides\u201d
\nJournal of Power Sources 173(2) (2007) 695-699
\nIF 2.809<\/p>\n

12. W. Zaj\u0105c, K. \u015awierczek, J. Molenda
\n\u201eThermochemical compatibility between selected (La,Sr)(Co,Fe,Ni)O3 cathodes and rare earth doped ceria electrolytes\u201d
\nJournal of Power Sources 173(2) (2007) 675-680
\nIF 2.809<\/p>\n

13. W. Ojczyk, J. Marzec, K. \u015awierczek, W. Zaj\u0105c, M. Molenda, R. Dziembaj, J. Molenda, \u201eStudies of selected synthesis procedures of the conducting LiFePO4 – based composite cathode materials for Li – ion batteries\u201d
\nJournal of Power Sources 173(2) (2007) 700-706
\nIF 2.809<\/p>\n

14. J. Molenda, W. Ojczyk, K. \u015awierczek, W. Zaj\u0105c, F. Krok, J. Dygas, R. S. Liu
\n\u201eDiffusional mechanism of deintercalation in LiMnyFe1-yPO4 cathode material\u201d
\nSolid State Ionics 177(26-32) (2006) 2617-2624
\nIF 2.190<\/p>\n

15. K. \u015awierczek, J. Marzec, D. Pa\u0142ubiak, W. Zaj\u0105c, J. Molenda
\n\u201eLFN and LSCFN perovskites – structure and transport properties\u201d
\nSolid State Ionics 177(19-25) (2006) 1811-1817
\nIF 2.190<\/p>\n

16. K. \u015awierczek, J. Marzec, J. Molenda
\n\u201eLa1-xSrxCo1-y-zFeyNizO3 perovskites – possible new cathode materials for an intermediate temperature Solid Oxide Fuel Cells\u201d
\nMaterials Science – Poland 24(1) (2006) 115-122
\nIF 0.334<\/p>\n

17. J. Molenda, K. \u015awierczek, W. Zaj\u0105c
\n\u201eWysokotemperaturowe tlenkowe ogniwa paliwowe – nowe kierunki bada\u0144\u201d
\nPrzemys\u0142 Chemiczny 84(11) (2005) 845-852
\nIF 0.104<\/p>\n

18. J. Molenda, M. Ziemnicki, K. \u015awierczek, J. Marzec
\n\u201eTransport and electrochemical properties of LiyNixMn2-xO4 (0.1 \u2264 x \u2264 0.5) cathode materials\u201d
\nDefects and Diffusion in Ceramics – An Annual Retrospective VII, Defect and Diffusion Forum 242-244 (2005) 65-76
\nIF 0.483<\/p>\n

19. W. Ojczyk, J. Marzec, K. \u015awierczek, J. Molenda
\n\u201eLithium diffusion in LiMnyFe1-yPO4 cathode material\u201d
\nDefect and Diffusion Forum 237-240 (2005) 1299-1305
\nIF 0.483<\/p>\n

20. K. \u015awierczek, J. Marzec, W. Ojczyk, J. Molenda
\n\u201eStructural and transport properties of La1-xSrxCo1-y-zFeyNizO3-\u03b4 perovskites\u201d
\nDefect and Diffusion Forum 237-240 (2005) 1293-1298
\nIF 0.483<\/p>\n

21. J. Molenda, J. Marzec, K. \u015awierczek, D. Pa\u0142ubiak, W. Ojczyk, M. Ziemnicki
\n\u201eThe effect of 3d substitutions in the manganese sublattice on the electrical and electrochemical properties of manganese spinel\u201d
\nSolid State Ionics 175(1-4) (2004) 297-304
\nIF 1.862<\/p>\n

22. J. Molenda, J. Marzec, K. \u015awierczek, W. Ojczyk, M. Ziemnicki, M. Molenda,
\nM. Drozdek, R. Dziembaj
\n\u201eThe effect of 3d substitutions in the manganese sublattice on the charge transport mechanism and electrochemical properties of manganese spinel\u201d
\nSolid State Ionics 171(3-4) (2004) 215-227
\nIF 1.862<\/p>\n

23. J. Molenda, K. \u015awierczek, J. Marzec, R.S. Liu
\n\u201eCharge transport mechanism in LiCoyMn2-yO4 cathode material\u201d
\nSolid State Ionics 157(1-4) (2003) 101-108
\nIF 1.599<\/p>\n

24. K. \u015awierczek, J. Marzec, M. Marzec, J. Molenda
\n\u201eCrystallographic and electronic properties of Li1+\u03b4Mn2-\u03b4O4 spinels prepared by HT synthesis\u201d
\nSolid State Ionics 157(1-4) (2003) 89-93
\nIF 1.599<\/p>\n

25. J. Marzec, K. \u015awierczek, J. Przewo\u017anik, J. Molenda, D.R. Simon, E.M. Kelder,
\nJ. Schoonman
\n\u201eConduction mechanism in operating a LiMn2O4 cathode\u201d
\nSolid State Ionics 146(3-4) (2002) 225-237
\nIF 1.768<\/p>\n

26. J. Molenda, K. \u015awierczek, M. Molenda, J. Marzec
\n\u201eElectronic structure and reactivity of Li1-xMn2O4 cathode\u201d
\nSolid State Ionics 135(1-4) (2000) 53-59
\nIF 1.529<\/p>\n

27. J. Molenda, K. \u015awierczek, W. Kucza, J. Marzec, A. Stok\u0142osa
\n\u201eElectrical properties of LiMn2O4-\u03b4 at temperatures 220 – 1100K\u201d
\nSolid State Ionics 123(1-4) (1999) 155-163
\nIF 1.439<\/div><\/div><\/div><\/div><\/div>

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Projekty badawcze<\/h2>\n<\/div>

Obecnie realizowana tematyka badawcza<\/strong><\/span><\/h3>\n<\/div>
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Projekt badawczy NCN (2020\/37\/B\/ST8\/02097) \u201eNowa generacja elektrod powietrznych opartych o zwi\u0105zki miedzi dla sta\u0142otlenkowych ogniw paliwowych i elektrolizer\u00f3w wysokotemperaturowych\u201d<\/strong><\/span><\/h4>\n

Projekt badawczy AGH (IDUB dzia\u0142anie D4 nr 9880) \u201eNowa generacja katalizator\u00f3w dla ko-elektrolizy H2O i CO2 w odwracalnych wysokotemperaturowych ogniwach ceramicznych typu SOC\u201d<\/strong><\/span><\/h4>\n

Projekt badawczy AGH (IDUB dzia\u0142anie D4 nr 6354) \u201eNowa generacja ogniw litowo-jonowych o wysokiej g\u0119sto\u015bci energii z katod\u0105 opart\u0105 o modyfikowany powierzchniowo wysokoniklowy tlenek warstwowy oraz anod\u0105 pracuj\u0105c\u0105 w oparciu o \u0142\u0105czony mechanizm konwersji i stopowania\u201d<\/strong><\/span><\/h4>\n

\u2022<\/span> Projektowanie, badania w\u0142a\u015bciwo\u015bci fizykochemicznych i optymalizacja materia\u0142\u00f3w elektrodowych dla ogniw paliwowych typu SOFC oraz elektrolizer\u00f3w wysokotemperaturowych SOEC, ze szczeg\u00f3lnym uwzgl\u0119dnieniem aspektu strukturalnego, mikrostruktury elektrod, mechanizmu transferu \u0142adunku, stabilno\u015bci i w\u0142a\u015bciwo\u015bci termochemicznych. Modyfikacja zwi\u0105zk\u00f3w kationami 4d\/5d oraz wykorzystanie wielosk\u0142adnikowych materia\u0142\u00f3w o wysokiej entropii. Okre\u015blenia zjawisk polaryzacyjnych na elektrodach oraz badania w\u0142a\u015bciwo\u015bci elektrochemicznych ogniw. Projektowanie materia\u0142\u00f3w dla procesu ko-elektrolizy H2<\/sub>O i CO2<\/sub> w wysokich temperaturach.<\/span><\/h4>\n

\u2022<\/span> Projektowanie i optymalizacja nowej generacji materia\u0142\u00f3w anodowych (tlenki wysokoentropowe, materia\u0142y bazuj\u0105ce na konwersji i stopowaniu) oraz katodowych (warstwowe tlenki o du\u017cej zawarto\u015bci litu, tlenki DRX o strukturze rozporz\u0105dkowanej soli kamiennej) dla ogniw litowych cechuj\u0105cych si\u0119 wysok\u0105 g\u0119sto\u015bci\u0105 mocy i zgromadzonej energii. Aktywno\u015b\u0107 badawcza dotyczy pomiar\u00f3w struktury krystalicznej i okre\u015bleniu jej modyfikacji w procesach elektrodowych, bada\u0144 mechanizmu transferu \u0142adunku jonowego i elektronowego oraz okre\u015blenia w\u0142a\u015bciwo\u015bci elektrochemicznych w zakresie pojemno\u015bci elektrod oraz odwracalno\u015bci cykli \u0142adowania\/roz\u0142adowania.<\/span><\/h4>\n

\u2022<\/span> Uczenie maszynowe w przewidywaniu w\u0142a\u015bciwo\u015bci ogniw Li-ion. Analiza krzywych \u0142adowania\/roz\u0142adowania oraz morfologii elektrod z wykorzystaniem technik sztucznej inteligencji.<\/span><\/h4>\n<\/div>
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Wypromowani doktorzy<\/span><\/h3>\n<\/div>

dr in\u017c. Boyang Fu<\/span><\/strong>
\ntytu\u0142 pracy: \u201eDevelopment of Ni-rich and Li-rich layered oxides as cathode materials for high-energy-density Li-ion cells\u201d<\/span>
\ntytu\u0142 pracy w j\u0119zyku polskim: \u201eOpracowanie warstwowych tlenk\u00f3w bogatych w nikiel oraz bogatych w lit jako materia\u0142\u00f3w katodowych do ogniw litowo-jonowych o wysokiej g\u0119sto\u015bci energii\u201d<\/span><\/h4>\n

dr in\u017c. Keyun Li<\/span><\/strong>
\ntytu\u0142 pracy: \u201eFunctional oxygen electrodes for Solid Oxide Cells based on Cu-containing perovskite-type oxides\u201d<\/span>
\ntytu\u0142 pracy w j\u0119zyku polskim: \u201eFunkcjonalne elektrody tlenowe dla sta\u0142otlenkowych ogniw Solid Oxide Cells bazuj\u0105ce na zawieraj\u0105cych Cu tlenkach typu perowskitu\u201d<\/span><\/h4>\n

dr in\u017c. Maciej Mo\u017adzierz<\/span><\/strong>
\ntytu\u0142 pracy: \u201eHigh-entropy oxides as candidate anode materials for Li-ion cells\u201d<\/span>
\ntytu\u0142 pracy w j\u0119zyku polskim: \u201eTlenki wysokoentropowe jako potencjalne materia\u0142y anodowe dla ogniw Li-ion\u201d<\/span><\/h4>\n

dr in\u017c. Kacper Cichy<\/span><\/strong>
\ntytu\u0142 pracy: \u201eRedox processes in energy-related technologies – use of mixed ionic-electronic conductors for oxygen production\u201d<\/span>
\ntytu\u0142 pracy w j\u0119zyku polskim: \u201eProcesy redoks w technologiach energetycznych <\/span>– wykorzystanie materia\u0142\u00f3w o mieszanym przewodnictwie jonowo-elektronowym do produkcji tlenu\u201d<\/span><\/h4>\n

dr in\u017c. Tomasz Polczyk
\n<\/span><\/strong>tytu\u0142 pracy: \u201eNowa generacja ogniw litowych – odwracalne ogniwa z ceramicznym elektrolitem sta\u0142ym\u201d<\/span><\/h4>\n

dr in\u017c. Anna Niemczyk<\/span><\/strong>
\ntytu\u0142 pracy: \u201eOpracowanie wysokoefektywnych materia\u0142\u00f3w elektrodowych bazuj\u0105cych na zwi\u0105zkach miedzi dla sta\u0142otlenkowych ogniw paliwowych i wysokotemperaturowych elektrolizer\u00f3w pary wodnej\u201d<\/span><\/h4>\n

dr in\u017c. Anna Olszewska<\/strong><\/span>
\ntytu\u0142 pracy: \u201eKorelacja pomi\u0119dzy struktur\u0105 a w\u0142a\u015bciwo\u015bciami transportowymi w warstwowych perowskitach LnBaCo2-x<\/sub>Mnx<\/sub>O5+\u03b4<\/sub> dla wysokotemperaturowych ogniw paliwowych\u201d<\/span><\/h4>\n

dr in\u017c. Wojciech Skubida<\/span><\/strong>
\ntytu\u0142 pracy: \u201eCorrelation between structure and transport properties in proton-conducting oxides in the design of electrodes and electrolytes for Protonic Ceramic Fuel Cells\u201d<\/span>
\ntytu\u0142 pracy w j\u0119zyku polskim: \u201eKorelacja pomi\u0119dzy struktur\u0105 a w\u0142a\u015bciwo\u015bciami transportowymi w protonowo przewodz\u0105cych tlenkach w aspekcie projektowania elektrod i elektrolit\u00f3w dla ogniw paliwowych typu PCFC\u201d<\/span><\/h4>\n

dr in\u017c. Alicja Klimkowicz<\/span><\/strong>
\ntytu\u0142 pracy: \u201ePerovskite-based oxygen storage materials\u201d<\/span>
\ntytu\u0142 pracy w j\u0119zyku polskim: \u201eMateria\u0142y o strukturze perowskitu do magazynowania tlenu\u201d<\/span><\/h4>\n

dr in\u017c. Kun Zheng<\/strong><\/span>
\ntytu\u0142 pracy: \u201eNovel electrode materials for IT-SOFC fueled by syngas\u201d<\/span>
\ntytu\u0142 pracy w j\u0119zyku polskim: \u201eNowe materia\u0142y elektrodowe dla ogniw IT-SOFC zasilanych gazem syntezowym\u201d<\/span><\/h4>\n<\/div>
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Tematyka obecnie realizowanych prac doktorskich <\/span><\/h3>\n<\/div>

\u2022<\/span> Tlenki wysokoentropowe jako potencjalne materia\u0142y anodowe dla ogniw Li-ion<\/span><\/h4>\n

\u2022<\/span> Materia\u0142y funkcjonalne dla odwracalnych ogniw sta\u0142otlenkowych<\/span><\/h4>\n

\u2022<\/span> In\u017cynieria powierzchni bogatych w nikiel tlenk\u00f3w warstwowych dla ogniw Li-ion o wysokiej g\u0119sto\u015bci energii<\/span><\/h4>\n

\u2022<\/span> Modyfikowane kationami 4d\/5d wysokoentropowe materia\u0142y elektrodowe o strukturze perowskitu<\/span><\/h4>\n

\u2022<\/span> Bazuj\u0105ce na stroncie wysoko- i \u015brednioentropowe materia\u0142y elektrodowe o strukturze perowskitu do zastosowania w technologii ceramicznych ogniw paliwowych<\/span><\/h4>\n

Osoby zainteresowane podj\u0119ciem studi\u00f3w doktoranckich w roku akademickim 2025\/2026 proszone s\u0105 o kontakt.
\nProponowana tematyka prac doktorskich:<\/em><\/strong><\/span><\/h4>\n

\u2022<\/span> Opracowanie nieuporz\u0105dkowanych kationowo materia\u0142\u00f3w katodowych o strukturze typu soli kamiennej (DRX) do zastosowa\u0144 elektrochemicznych<\/span><\/h4>\n

\u2022<\/span> Prognozowanie w\u0142a\u015bciwo\u015bci ogniw Li-ion z zastosowaniem uczenia maszynowego<\/span><\/h4>\n

\u2022<\/span> Materia\u0142y elektrodowe do wysokotemperaturowej ko-elektrolizy H2<\/sub>O i CO2<\/sub> w symetrycznych elektrolizerach sta\u0142otlenkowych<\/span><\/h4>\n<\/div>
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Oferty pracy w ramach projekt\u00f3w badawczych<\/span><\/h3>\n<\/div>

Na chwil\u0119 obecn\u0105 brak jest mo\u017cliwo\u015bci zatrudnienia w ramach realizowanych projekt\u00f3w badawczych.
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Oferty sta\u017cy naukowo-badawczych<\/span><\/h3>\n<\/div>

Istnieje mo\u017cliwo\u015b\u0107 odbycia sta\u017cu naukowo-badawczego o czasie trwania 1-3 miesi\u0105ce w Katedrze Energetyki Wodorowej na Wydziale Energetyki i Paliw AGH lub u zagranicznego partnera naukowego.<\/span><\/h4>\n<\/div>
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<\/i>Dydaktyka<\/span><\/a><\/div>
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Dydaktyka<\/h2>\n<\/div>

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Materia\u0142y dydaktyczne dla doktorant\u00f3w i student\u00f3w (rok akademicki 2024\/2025) – dost\u0119pne indywidualnie po uprzednim skontaktowaniu si\u0119.<\/strong><\/h4>\n