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DATA
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[autor] => Filip Antončík
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[obsah] => The advanced composite materials group was formed in 2017. The main research fields are advanced superconducting ceramics based on mixed copper oxides, thermoelectric materials based on mixed cobalt oxides, carbon nanomaterials, and composite materials based on rective magnesia. Such materials are used in construction, transportation, energy industry, and ecology.
Research and development are being done as a part of both primary and applied research with the cooperation of both domestic and international industrial partners and the academic sphere.
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[platne_od] => 09.06.2023 14:45:00
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[obsah] => 2022:
- Filip Antončík Jean-Marie Lehn Prize for Chemistry - 2nd place
- Inorganic Non-metallic Materials Competition - 3rd place
- Anna Marie Lauermannova Inorganic Non-metallic Materials Competition - 1th place
2021:
- Michal Lojka Josef Hlávka Awardq
- Anna Marie Lauermannova Crytur Award for Best Master's Thesis - 1th place
- Czech Ceramic Society - Best master's thesis award
- Ivana Faltysová TVIP Conference Hustopeče - Best Poster Award
2020:
- Filip Antončík Crytur Award for Best Master's Thesis - 2nd place
- Czech Ceramic Society - Best master's thesis award
XRD
X’Pert PRO, Bruker D2 Phaser, and Bruker D8 Discover enabling powder XRD up to 1400°C, reciprocal space mapping, GI SAXS, WAXS, SAXS, rotational capillary, X-ray reflectance for chemical and mineralogical determination.
Calorimetry
TG, DSC, DTA and drop calorimetry covering the temperature range ‑150 ‑ 1750°C under controlled atmosphere and vacuum (STA PT High-Pressure TGA-DSC Linseis PT1600, Setaram Multidetector HTC-96 including drop calorimetry, Setaram Themys including highly accurate TGA measurements combined with MS analysis of gaseous products, Netzsch DSC404C Pegasus for accurate heat capacity measurements in dynamical regime).
PPMS
(Quantum Design) measurements of physical properties at low temperatures (2 – 320 K) and magnetic fields 0-9 T – magnetic moment (VSM module), heat capacity (HC module – relaxation method), thermopower and thermal conductivity (TTO module), resistivity and Hall effect (ETO module).
LFA
Thermal conductivity at elevated temperatures (Linseis).
Raman
Confocal Raman spectrometer (Renishaw InVia) with DPSS laser (532 nm, 50 mW), ARL 9400 XP (Thermo ARL, central laboratories) sequential WD-XRF spectrometer equipped with an Rh anode end-window X-ray tube type 4GN fitted with 50 μm Be window for XRF, and FT-IR, iS50R FTIR (Thermo Scientific) equipped with diamond ATR crystal, DLaTGS detector and KBr beamsplitter in the range 4000 – 400 cm-1.
BET
A sorption analyzer (BET) NOVAtouch LX2 (Quantachrome Instruments) using nitrogen-cooled (77 K) detector
DLS
Zetasizer Nano ZS (Malvern Instruments) and LD Malvern Panalytical Mastersizer 3000 device with 4 mW He-Ne 632.8 nm Red light source and 10 mW LED 470 nm Blue light source for surface area determination and particle size distribution.
OM
Navitar with optical zoom up to 110X and digital camera Sony 2/3”, with a resolution of 5 Mpix
SEM/EDS
SEM with a FEG electron source (Tescan Lyra with a dual-beam microscope or Tescan Maia3). EDS with a 20 mm2 SDD detector (Oxford Instruments) using AZtecEnergy software.
AFM
AMF - Ntegra Spectra from NT‑MDT). This AFM is equipped with a cantilever with a strain constant of 1.5 kN·m-1
Confocal microscopy
Confocal microscope Sensofar S neox with 5 Mpx camera, four LED sources: Red (630 nm); green (530 nm); blue (460 nm) and white (575 nm) and Ai focus variation.
XPS
XPS SPECS spectrometer equipped with an XR 50 MF monochromatic X‐ray radiation source (1486.7 eV).
DCS (SPS)
FCT Systeme HP-D 10 ( up to 2400°C, Vacuum: 5 x 10-2 mbar, Ar / N2 working gasses
Superconducting properties
such as levitation force (test bench based on PT4000-50kg load cell and 24-bit ADC Data Acquisition system with NdFeB magnet, d=15 mm, h=15 mm) and trapped magnetic field based on scanning Hall probe technique where samples are field-cooled at the excitation field about 1.5 T) measurements are evalible
Software/calculations
Two calculation clusters (4 nodes - 16 CPU and 3 nodes - 16 CPU) and Altix supercomputer (192 CPU, 1.5 TB shared RAM) with Wien2k, Medea VASP and Phonon software installed are available for ab-initio calculations. FactSage thermochemical program and databases are avalible for thermodynamic modeling.
ALD
PicoSun, thermal and plasma-enhanced ALD with the possibility of heating the substrate up to a temperature of 500 ° C
HR-TEM
Central laboratories of UCT Prague are also equipped by HR-TEM EFTEM Jeol 2200 FS with SDD detector X-MaxN from Oxford Instruments and AAS Agilent 280FS AA device using a flame-atomization technique with neon-filled hollow-cathode lamp.
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TACR EPSILON 2017-2021
GA17-13161S The role of nonstoichimetry and nanosizing in material properties of metal oxides
GAČR 2017-2019
GA17-02815S Research and development of high-performance composites containing biomass ash
GAČR 2017-2019
TJ01000072 Nanoobjects for water decontamination
TAČR ZÉTA 2018-2020
TK01030200 Advanced superconducting ceramics for energy applications
TACR THÉTA 2018-2024
GA19-00262S Reactive magnesia cements-based composites with selected admixtures and additives
GAČR 2019-2021
FV40201 Research and development of primary materials for the deposition of superconducting thin films
GAČR 2020-2022
GA20-01866S High-value composites containing layered materials
GAČR 2020-2022
TJ04000022 Composite ceramics filters used for water treatment of water polluted by pesticides and heavy metals
TACR ZETA 2020-2022
High-strength and water-resistant MOC composites with secondary fillers: contribution of 2D carbon-based nanomaterials and their combinations
GAČR - JUNIOR STAR 2023-2027
CZ.02.01.01/00/22_008/0004631 Materials and technologies for sustainable development
Jan Amos Komensky Operational Program
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Ing. Michal Lojka Michal.Lojka@vscht.cz
Ing. Filip Antončík Filip.Antoncik@vscht.cz
Ing. Anna-Marie Lauermannová lauermaa@vscht.cz
Ing. Adéla Jiříčková
Ivana Faltysová
Jan Sklenka
(Since 2017)
1) J. Pinc, O. Jankovský, V. Bartůněk, Preparation of manganese oxide nanoparticles by thermal decomposition of nanostructured manganese carbonate, Chem. Pap., 2017, 71, 1031–1035.
2) M. Pižl, O. Jankovský, P. Ulbrich, N. Szabo, I. Hoskovcova, D. Sedmidubský, V. Bartůněk, Facile preparation of nanosized yttrium oxide by the thermal decomposition of amorphous Schiff base yttrium complex precursor, J. Organomet. Chem., 2017, 830, 146-149.
3) V. Bartůněk, Š. Huber, J. Luxa, Z. Sofer, M. Kuchař, K. Dobrovolný, O. Jankovský, Facile Synthesis of Magnetic Cobalt Nano-foam by Low-temperature Thermal Decomposition of Cobalt Glycerolate, Micro & Nano Letters, 2017, 12, 278 – 280.
4) M. Nováček, O.Jankovský, J. Luxa, D. Sedmidubský, M. Pumera, V. Fila, M. Lhotka, K. Klímová, S. Matějková, Z. Sofer, Tuning of graphene oxide composition by multiple oxidations for carbon dioxide storage and capture of toxic metals, J. Mater. Chem. A, 2017, 5, 2739-2748.
5) O. Jankovský, M. Nováček, J. Luxa, D. Sedmidubský, M. Boháčová, M. Pumera, Z. Sofer, Concentration of Nitric Acid Strongly Influences Chemical Composition of Graphite Oxide, Chem. Eur. J., 2017, 23, 6432-6440.
6) O. Jankovský, M. Lojka, J. Luxa, D.Sedmidubský, O.Tomanec, R.Zbořil, M.Pumera, Z. Sofer, Selective Bromination of Graphene Oxide by the Hunsdiecker Reaction, Chem. Eur. J., 2017, 23, 10473–10479.
7) O. Jankovský, V. Rach, D. Sedmidubský, Š. Huber, P. Ulbrich, M. Švecová, V. Bartůněk, Simple synthesis of free surface nanostructured spinel NiFe2O4 with a tunable particle size, J. Alloy. Comp., 2017, 723, 58-63.
8) O. Jankovský, Z. Sofer, J. Kovařík, K. Růžička, J. Leitner, D. Sedmidubský, Thermodynamic properties of misfit cobaltite [Bi2-xCa2O4][CoO2]1.7. Thermochim. Acta, 2017, 656, 129-134.
9) O. Jankovský, M. Pavlíková, D. Sedmidubský, D. Bouša, M. Lojka, J. Pokorný, M. Záleská, Z.Pavlík, Study on pozzolana activity of wheat straw ash as potential admixture for blended cements, Ceramics-Silikáty, 2017, 61, 327-339.
10) O. Jankovský, A. Jiříčková, J. Luxa, D. Sedmidubský, M. Pumera, Z. Sofer, Z.. Fast Synthesis of Highly Oxidized Graphene Oxide, ChemistrySelect, 2017, 2, 9000-9006.
11) O. Jankovský, M. Lojka, J. Luxa, D. Sedmidubský, M. Pumera, Z. Sofer, Introduction of sulfur to graphene oxide by Friedel-Crafts reaction, FlatChem 2017, 6, 28-36.
12) O. Jankovský, D. Sedmidubský, Phase equilibria modelling in Bi–Sr–Co–O system—Towards crystal growth and melt-assisted material processing, J. Eur. Ceram. Soc., 2018, 38, 131-135.
13) M. Záleská, M. Pavlíková, Z. Pavlík, O. Jankovský, J. Pokorný, V. Tydlitát, P. Svora, R. Černý, Physical and chemical characterization of technogenic pozzolans for the application in blended cements, Constr. Build. Mater. 2018, 160, 106–116.
14) J. Leitner, V. Bartůněk, D. Sedmidubský, O. Jankovský, Thermodynamic properties of nanostructured ZnO, Appl. Mater. Today 2018, 10, 1–11.
15) M. Záleská, Z. Pavlík, M. Pavlíková, L. Scheinherrová, J. Pokorný, A. Trník, P. Svora, J. Fořt, O. Jankovský, Z. Suchorab, R. Černý, Biomass ash-based mineral admixture prepared from municipal sewage sludge and its application in cement composites, Clean Technol. Environ. Policy, 2018, 20, 159–171
16) O. Jankovský, F. Antončík, T. Hlásek, V. Plecháček, D. Sedmidubský, Š. Huber, M. Lojka, V. Bartůněk, Synthesis and properties of YBa2Cu3O7-δ – Y2Ba4CuWO10.8 superconducting composites, J. Eur. Ceram. Soc., 2018, 38, 2541-2546.
17) V. Bartůněk, D. Sedmidubský, D. Bouša, O. Jankovský, Production of pure amorphous silica from wheat straw ash, Green Mater., 2018, 6, 1-5.
18) M. Záleská, M. Pavlíková, O. Jankovský, J. Pokorný, Z. Pavlík, Lightweight Concrete Made With Waste Expanded Polypropylene-Based Aggregate And Synthetic Coagulated Amorphous Silica, Ceramics-Silikáty, 2018, 62 (3) 221-232.
19) D. Bousa, V. Mazanek, D. Sedmidubsky, O. Jankovsky, M. Pumera, Z. Sofer, Hydrogenation of Fluorographite and Fluorographene: an Easy Way to Produce Highly Hydrogenated Graphene, Chem. Eur. J., 2018, 24(33) 8350-8360.
20) E. Storti, O. Jankovský, P. Colombo, Ch. G. Aneziris, Effect of heat treatment conditions on magnesium borate fibers prepared via electrospinning, J. Eur. Ceram. Soc., 2018, 38, 4109-4117.
21) O. Jankovský, E. Storti, K. Moritz, B. Luchini, A. Jiříčková, Ch. G. Aneziris, Nano-functionalization of carbon-bonded alumina using graphene oxide and MWCNTs, J. Eur. Ceram. Soc., 2018, 38 (14) 4732-4738
20) M. Pižl, O. Jankovský, M. Guricová, I. Hoskovcová, D. Sedmidubský, V.Bartůněk, Mixed Yttrium–Ytterbium–Erbium Schiff Base Complex as a Model Precursor for Mixed Nanosized Rare Earths Oxides, J. Cluster. Sci., 2018, 29, 549–553.
21) M. Záleská, M. Pavlíková, J. Pokorný, O. Jankovský, Z. Pavlík, R. Černý, Structural, mechanical and hygrothermal properties of lightweight concrete based on the application of waste plastics, Constr. Build. Mater. 2018, 180, 1–11.
22) M. Záleská, M. Pavlíková, O. Jankovský, M. Lojka, A. Pivák, Z. Pavlík, Experimental Analysis of MOC Composite with a Waste-Expanded Polypropylene-Based Aggregate, Materials, 2018, 11(6), 931-936.
23) J. Leitner, D. Sedmidubský, O. Jankovský, Effect of ZnO Nanosizing on its Solubility in Aqueous Media, Micro Nano Let., 2018, 13(11),1585 – 1589.
24) V. Bartůněk, D. Sedmidubský, Š. Huber, M. Švecová, P. Ulbrich, O. Jankovský, Synthesis and Properties of Nanosized Stoichiometric Cobalt Ferrite Spinel, Materials 2018, 11(7), 1241.
25) O. Jankovský, E. Storti, G. Schmidt, S. Dudczig, Z. Sofer, Ch. G. Aneziris, Unique Wettability Phenomenon of Carbon-bonded Alumina with Advanced Nanocoating, Applied Materials Today, 2018, 13, 24-31.
26) M. Lojka, O. Jankovský, D. Sedmidubsky, V. Mazanek, D. Bouša, M. Pumera, S. Matějková, Z. Sofer, Synthesis and Properties of Phosphorous and Sulfur Co-Doped Graphene , New J. Chem., 2018, 42(19), 16093-16102.
27) M. Pavlíková, J. Pokorný, O. Jankovský, M. Záleská, M. Vavro, K. Souček, Z. Pavlík, The effect of the sodium sulphate solution exposure on properties and mechanical resistance of different kinds of renders, Ceramics Silikaty, 2018, 62 (4), 311-324.
28) M. Pavlíková, L. Zemanová, J. Pokorný, M. Záleská, O. Jankovský, M. Lojka, D. Sedmidubský, Z. Pavlík, Valorization of Wood Chips Ash as an Eco-Friendly Mineral Admixture in Mortar Mix Design, Waste Management, 2018, 80, 89-100.
29) K. Rubešová, T. Thoř, V. Jakeš, D. Mikolášová, J. Maixner, O. Jankovský, J. Cajzl, L. Nádherný, A. Beitlerová, M. Nikl, Lanthanide-doped Y2O3 – The Photoluminescent and Radioluminescent Properties of Sol-Gel Prepared Samples, Ceramics-Silikáty, 2018, 62 (4), 411-417.
30) V. Bartůněk, P. Ulbrich, J. Pinc, D. Sedmidubský, O. Jankovský, Fine fluorite nanoparticles synthesized from biomass ash, Journal of Fluorine Chemistry, 2018, 216, 112–117.
31) T. Hlásek, Y. Shi, J. H. Durrell, A. R. Dennis, D. K. Namburi, V. Plecháček, K. Rubešová, D. A. Cardwell, O. Jankovský, Cost-effective Isothermal Top-Seeded Melt-growth of Single-domain YBCO Superconducting Ceramics, Solid State Sciences, 2019, 88, 74-80.
32) V. Doležal, L. Nádherný, K. Rubešová, V. Jakeš, A. Michalcová, O. Jankovský, M. Poupon, LaMgAl11O19 synthesis using non-hydrolytic sol-gel methods, Ceram. Int., 2019, 45, 1233-11240.
33) M. Pavlíková, L. Zemanová, M. Záleská, J. Pokorný, M. Lojka, O. Jankovský, Z. Pavlík, Z, Ternary Blended Binder for Production of a Novel Type of Lightweight Repair Mortar, Materials, 2019, 12(6), 996.
34) O. Jankovský, V. Bartůněk, F. Antončík, A. Jiříčková, A. M. Lauermannová, M. Záleská, M. Pavlíková, J. Pokorný, Z. Pavlík, Wood chips ash processing and its utilization in magnesium phosphate cement composites, Ceramics Silikaty, 2019, 63 , 267-276
35) K. Jilkova, M. Mika, P. Kostka, F. Lahodny, P. Nekvindova, O. Jankovsky, R. Bures, M. Kavanova, Electro-optic glass for light modulators, Journal of Non-Crystalline Solids, 2019, 518, 51-56
36) V. F. Rahhal, M. A. Trezza, A. Tironi, C. C. Castellano, M. Pavlíková, J. Pokorný, E. F. Irassar, O. Jankovský, Z. Pavlík, Complex characterization and behaviour of sintered ceramic waste powder-Portland cement system, Materials, 2019, 12, 1650.
37) M. Pavlíková, L. Zemanová, J. Pokorný, M. Záleská, O. Jankovský, M. Lojka, Z. Pavlík, Influence of wood-based biomass ash admixing on the structural, mechanical, hygric, and thermal properties of air lime mortars, Materials, 2019, 12, 2227.
38) M. Lojka, B. Lochman, O. Jankovský, A. Jiříčková, Z. Sofer, D. Sedmidubský, Synthesis, composition and properties of partially oxidized graphite oxides, Materials, 2019, 12, 2367.
39) M. Záleská, Z. Pavlík, D. Čítek, O. Jankovský, M. Pavlíková, Eco-friendly concrete with scrap-tyre-rubber-based aggregate - properties and thermal stability, Construction and Building Materials 2019, 225, 709–722
40) F. Antončík, D. Sedmidubský, A. Jiříčková, M. Lojka, T. Hlásek, K. Růžička and O. Jankovský, Thermodynamic properties of stoichiometric non superconducting phase Y2BaCuO5, Materials, 2019, 12 (19), 3163.
41) V. Bartůněk, J. Luxa, D. Sedmidubský, T. Hlásek, and O. Jankovský, Microscale and Nanoscale Pinning Centres in Single-domain REBCO Superconductors, J Mater. Chem C, 2019, 7, 13010 – 13019.
42) J. Leitner, D. Sedmidubský, O. Jankovský, Size and shape-dependent solubility of CuO nanostructures, Materials, 2019, 12 (20), 3355.
43) M. Záleská, M. Pavlíková, O. Jankovský, M. Lojka, F. Antončík, A. Pivák, Z. Pavlík, Influence of Waste Plastic Aggregate and Water-Repellent Additive on the Properties of Lightweight Magnesium Oxychloride Cement Composite, Appl. Sci., 2019, 9, 5463.
44) E. Storti, O. Jankovský, D. Sedmidubský, S. Dudczig, Ch. G. Aneziris, Filter coatings based on combination of nanomaterials for steel melt filtration, Adv. Eng. Mater., 2020, 22, 1900457.
45) K. Skrbek, O, Jankovský, D. Sedmidubský, V. Bartůněk, Flame aerosol transport method for assembling CeO2-SiO2 nanocomposites, Ceram. Int., 46 (4), 5495-5499.
46) F. Antončík, M. Lojka, T. Hlásek, V. Bartůněk, I. Valiente, J. Pérez-Díaz and O. Jankovský, Radial and axial stiffness of superconducting bearings based on YBCO single-domain bulks processed with artificial holes, Supercond. Sci. Technol., 2020, 33, 045010.
47) M. Lojka, O. Jankovský, A.Jiříčková, A.-M. Lauermannová, F. Antončík, D. Sedmidubský, Z. Pavlík, M. Pavlíková, Thermal Stability and Kinetics of Formation of Magnesium Oxychloride Phase 3Mg(OH)2∙MgCl2∙8H2O, Materials 2020, 13(3), 767.
48) A. Jiříčková, M. Lojka, A.-M. Lauermannová, F. Antončík, D. Sedmidubský, M. Pavlíková, M. Záleská, Z. Pavlík, O. Jankovský, Synthesis, Structure and Thermal Stability of Magnesium Oxychloride 5Mg(OH)2∙MgCl2∙8H2O, Appl. Sci. 2020, 10, 1683.
49) O. Jankovský, M. Lojka, A.-M. Lauermannová, F.Antončík, M. Pavlíková, Z. Pavlík, D. Sedmidubský, Carbon dioxide uptake by MOC-based materials Appl. Sci. 2020, Appl. Sci. 2020, 10, 2254.
50) O. Jankovský, M.Lojka, A. Jiříčková, Ch. G. Aneziris, E. Storti, D. Sedmidubský, Carbon-bonded alumina filters coated by graphene oxide for water treatment, Materials 2020, 13, 2006,
51) F. Antončík, M. Lojka, T. Hlásek, I.Valiente-Blanco, J.L. Perez-Diaz, O. Jankovský, Artificially perforated single-grain YBCO bulks: Dependence of superconducting properties on the bulk thickness, Journal of the American Ceramic Society, 2020, 103, 5169-5177.
52) A. Pivák, M. Pavlíková, M.Záleská, M. Lojka, O. Jankovský, Z. Pavlík, MOC Composites with Silica Filler and Coal Fly Ash Admixture, Materials 2020, 13, 2537
53) A-M. Lauermannová, M. Lojka, F. Antončík, D. Sedmidubský, M. Pavlíková, Z. Pavlík, O.Jankovský, Magnesium oxybromides MOB-318 and MOB-518: brominated analogues of magnesium oxychlorides, Appl. Sci.2020, 10(11), 4032.
54) J. Leitner, D. Sedmidubský, M. Lojka, O. Jankovský, The effect of nanosizing on the oxidation of partially oxidized copper nanoparticles, Materials 2020, 13(12), 2878.
55) A. Pivák, M. Pavlíková, M. Záleská, M. Lojka, A.-M.Lauermannová, O. Jankovský, Z. Pavlík, Low-Carbon Composite Based on MOC, Silica Sand and Ground Porcelain Insulator Waste, Processes, 2020, 8, 829.
56) O. Jankovský, M. Lojka, A.-M. Lauermannová, F. Antončík, M. Pavlíková, M. Záleská, Z. Pavlík, A. Pivák and D. Sedmidubský, Towards novel building materials: high-strength nanocomposites based on graphene, graphite oxide and magnesium oxychloride, Appl. Mater. Today, 2020, 20, 100766
57) F. Antončík, O. Jankovský, T. Hlásek, V. Bartůněk, Nanosized pinning centers in the rare earth-barium-copper-oxide thin-films superconductors, Nanomaterials, 2020, 10, 1429.
58) K. Skrbek, V. Bartůněk, M. Lojka, D. Sedmidubský, O. Jankovský, Synthesis and characterization of the properties of ceria nanoparticles with a tunable particle size for the decomposition of chlorinated pesticides, Appl. Sci.2020, 10, Appl. Sci. 2020, 10(15), 5224.
59) M. Lojka, F. Antončík, D. Sedmidubský, T. Hlásek, J. Wild, J. Pavlů, O. Jankovský, V. Bartůněk, Phase-stable segmentation of BSCCO high-temperature superconductor into micro-, meso-, and nano-size fractions, J. Mater. Res. Technol., 2020, 9, 12071-12079.
60) M. Pavlíková, A. Pivák, M. Záleská, O. Jankovský, P. Reiterman, Z. Pavlík, Magnesium Oxychloride Cement Composites Lightened with Granulated Scrap Tires and Expanded Glass, Materials 2020, 13, 4828.
61) A.-M. Lauermannová, I. Paterová, J. Patera, K. Skrbek, O. Jankovský, V. Bartůněk, Hydrotalcites in construction materials, Appl. Sci. 2020, 10, 7989.
62) F. Antončík, M. Lojka, T. Hlásek, D. Sedmidubský, O. Jankovský, V. Bartůněk*, The effective synthesis of large volumes of the ultrafine BaZrO3 nanoparticles, Materials Chemistry and Physics 2021, 259, 124047.
63) M. Lojka, A.-M. Lauermannová, D. Sedmidubský, M. Pavlíková, M. Záleská, Z. Pavlík, A. Pivák, O. Jankovský*, Magnesium oxychloride cement composites with MWCNT for the construction applications, Materials, 2021, 14, 484.
64) A.-M. Lauermannová, M. Lojka, O. Jankovský, I. Faltysová, M. Pavlíková, A. Pivák, M. Záleská and Z. Pavlík*, High-performance Magnesium oxychloride composites with silica sand and diatomite, Journal of Materials Research and Technology, 2021, 11, 957-969.
65) A.-M. Lauermannová, M. Lojka, M. Pavlíková, A. Pivák, M. Záleská, Z. Pavlík, O. Zmeškal and O. Jankovský*, Graphene- and graphite oxide-reinforced magnesium oxychloride cement composites for the construction use, Ceramics-Silikaty, 2021, 65 (1), 38-47.
66) A.-M. Lauermannová, I. Faltysová, M. Lojka, F. Antončík, D. Sedmidubský, Z. Pavlík, M. Pavlíková, M. Záleská, A. Pivák, O. Jankovský, Regolith-based magnesium oxychloride composites doped by graphene: novel high-performance building materials for lunar constructions, FlatChem, 2021, 26, 100234.
67) A.Pivák, M. Pavlíková, M. Záleská, M. Lojka, A.-M. Lauermannová, I. Faltysová, O. Jankovský, Z. Pavlík*, Foam Glass Lightened Sorel’s Cement Composites Doped with Coal Fly Ash, Materials, 2021, 14, 1103.
68) Antončík, Filip, et al. "Influence of RE-Based Liquid Source (RE= Sm, Gd, Dy, Y, Yb) on EuBCO/Ag Superconducting Bulks." IEEE Transactions on Applied Superconductivity 31.5 (2021): 1-5.
69) Skočdopole, Jakub, et al. "Transport Coefficients in Y-Ba-Cu-O System for Ionized Jet Deposition Method." IEEE Transactions on Applied Superconductivity 31.5 (2021): 1-3.
70) Lojka, Michal, et al. "Effect of Target Density on the Surface Morphology of Y-Ba-Cu-O Thin Films Prepared by Ionized Jet Deposition." IEEE Transactions on Applied Superconductivity 31.5 (2021): 1-5.
71) M. Záleská, M. Pavlíková, A. Pivák, Š. Marušiak, O. Jankovský, A.-M. Lauermannová, M. Lojka, F. Antončík, Z. Pavlík, MOC Doped with Graphene Nanoplatelets: The Influence of the Mixture Preparation Technology on its Properties, Materials, 2021, 14(6), 1450.
72) M. Záleská, M. Pavlíková, A. Pivák, A.-M. Lauermannová, O. Jankovský, Z. Pavlík, Lightweight vapor-permeable plasters for building repair – detailed experimental analysis of the functional properties, Materials 2021, 14, 2613.
73) M. Pavlíková, A. Kapicová, A. Pivák, M. Záleská, M. Lojka, O. Jankovský, Z. Pavlík*, Zeolite lightened repair renders: effect of binder type on properties and salt crystallization resistence, Materials 2021, 14, 3760.
74) K. Skrbek, O. Jankovský, M. Lojka, F. Antončík, V. Bartunek*, Synthesis of nanosized LaFeAl11O19 hexaaluminate by mixed metal glycerolate method, Ceramics international, 2021, https://doi.org/10.1016/j.ceramint.2021.07.135.
75) F. Antončík, M. Lojka, D. Sedmidubský and O. Jankovský*, High-density YBCO Targets for Sputtering with Defect-free Microstructure Prepared by Novel Infiltration Method, J. Eur. Ceram. Soc., 2021, ttps://doi.org/10.1016/j.jeurceramsoc.2021.07.038.
76) M. Pavlíková*, M. Záleská, A. Pivák, O. Jankovský, A.-M. Lauermannová, M. Lojka, F. Antončík, and Zbyšek Pavlík, MOC-Diatomite Composites Filled with Multi-Walled Carbon Nanotubes, Materials, 2021, 14, 4576.
77) A.-M. Lauermannová, M. Lojka, O. Jankovský, I. Faltysová, D. Sedmidubský, M. Pavlíková, A. Pivák, M. Záleská, Š. Marušiak and Z. Pavlík, The influence of graphene specific surface on material properties of MOC-based composites for construction use, Journal of Building Engineering, 43 (2021): 103193.
78) A.-M. Lauermannová, M. Lojka, J. Sklenka, M. Záleská, M.Pavlíková, A. Pivák, Z. Pavlík, O.Jankovský, Magnesium oxychloride-graphene composites: towards high strength and water resistant materials for construction industry, FlatChem, 2021, 29, 100284.
79)F. Antončík, M. Lojka, T. Hlásek, V. Plecháček and O. Jankovský*, Tuning the top-seeded melt growth of REBCO single-domain superconducting bulks by a pyramid-like buffer stack , Ceram. Int., 2022, 48, 5377-5385.
80) E. Storti, J. Fruhstorfer, B. Luchini, A. Jiříčková, O. Jankovský, Ch. G. Aneziris, Graphene-reinforced carbon-bonded coarse-grained refractories, Materials, 2022, 15, 186.
81)A.-M. Lauermannová, O. Jankovský, M. Lojka, I. Faltysová, J. Slámová, M. Pavlíková, A. Pivák, Š. Marušiak, Z. Pavlík, M. Záleská*, Co-doped magnesium oxychloride composites with unique flexural strength for construction use, Materials, 2022, 15, 604.
82)A. Jiříčková, O. Jankovský, Z. Sofer, D. Sedmidubský, Synthesis and Applications of Graphene Oxide, Materials, 2022, 15, 920.
83)M. Pavlíková, A. Kapicová, M. Záleská, A. Pivák, O. Jankovský, A.-M. Lauermannová, M. Lojka, I. Faltysová, J. Slámová, Z. Pavlík, Ultra-high strength multicomponent composites based on reactive magnesia: tailoring of material properties by addition of 1D and 2D Carbon nanoadditives, J. Build. Eng., 2022, 50, 104122.
84)K. Rubešová, V. Jakeš, O. Jankovský, M. Lojka, D. Sedmidubský, Bismuth calcium cobaltite thermoelectrics: a study of precursor reactivity and its influence on the phase formation, J. Phys. Chem. Solids, 2022, 164, 110631.
85)M. Pavlíková, A. Pivák, M. Záleská, A.-M. Lauermannová, F. Antončík, M. Lojka, O. Jankovský, Z. Pavlík, Assessment of Wood Chips Ash as Efficient Admixture in Foamed Glass-MOC Composites , J. Mater. Res. Technol., 2022, 19, 2287-2300.
86)L. Spejchalová O. Jankovský, K. Rubešová. V. Jakeš, A.-M. Lauermannová, D. Sedmidubský, Solid-Liquid Equilibria in the Bi-Ca-Co-O System, J. Eur. Ceram. Soc., 2022, 42, 5756-5761.
87)A.-M. Lauermannová, M. Pavlíková, Z. Pavlík, A. Pivák, A. Jiříčková, J. Sklenka, M. Záleská, K. Růžička, O. Jankovský, Magnesium Oxychloride Cement with Phase Change Material: Novel Environmentally-friendly Composites for Heat Storage, J. Mater. Res. Technol., 2022, 21, 3327-3342.
88)A.-M. Lauermannová, A. Jiříčková, D. Sedmidubský, M. Pavlíková, M. Záleská, A. Pivák, Z. Pavlík, O. Jankovský, Graphene and MWCNT reinforced magnesium oxychloride composite modified by tannic acid, FlatChem, 2023, 37, 100459.
89) A.-M.Lauermannová, O. Jankovský, D. Sedmidubský, M. Lojka, M. Pavlíková, A. Pivák, M. Záleská, Z. Pavlík, Case Study on MOC Composites Enriched by Foamed Glass and Ground Glass Waste: Experimental Assessment of Material Properties and Performance, Case Studies, 2023, 18, e01836.
90)M. Záleská, M. Pavlíková, M. Keppert, A.-M. Lauermannová, O.Jankovský, M. Lojka, A. Jiříčková, G. Łagód and Z. Pavlík, Thermally Treated Coal Mining Waste as a Supplementary Cementitious Material - Case Study from Bogdanka Mine, Poland, Journal of Building Engineering, 2023, 68, 106036.
91)J. Skočdopole, F. Antončík, M. Lojka, O. Jankovský, T. Hlásek, L. Kalvoda, Influence of substrate temperature on the morphology and phase composition of thin films prepared from Y-123 targets by the IJD method, IEEE Transactions On Applied Superconductivity, 2023, 33, IEEE Transactions On Applied Superconductivity, 2023, 33, 7500604.
92)F. Antončík, M. Lojka, T. Hlásek, J. Sklenka, O. Jankovský, D. Sedmidubský, Silver recycling from defective GdBCO/Ag high-temperature superconducting bulks, IEEE Transactions On Applied Superconductivity, 2023, 33, 6800805.
93)V. Doležal, V. Jakeš, J. Petrášek, P. Ctibor, O. Jankovský, K. Rubešová, D. Sedmidubský, Dielectric properties of (Eu,Ca)Cu3Ti4O12 ceramics prepared by a sol-gel method, Journal of Physics and Chemistry of Solids, 2023, 178, 111334.
94)A.-M. Lauermannová, M. Lojka, M. Záleská, M. Pavlíková, A. Pivák, Z. Pavlík, K. Růžička and Ondřej Jankovský, Magnesium oxychloride cement-based composites for latent heat storage: the effect of the introduction of multi-walled carbon nanotubes, J. Build. Eng., 2023, 72, 106604
95)O. Jankovský, A.-M. Lauermannová, M. Lojka, E. Storti, Be. Bock-Seefeld, M. Neumann, Ch. G. Aneziris, Towards a new generation of environmentally-friendly ceramic foam filters: contribution of graphene nanoadditives in calcium aluminate-rich coatings, J. Eur. Ceram. Soc., 2023, 43, 6504-6515
96)O. Jankovský, A.-M. Lauermannová, M. Lojka, E. Storti, Be. Bock-Seefeld, M. Neumann, Ch. G. Aneziris, Towards a new generation of environmentally-friendly ceramic foam filters: contribution of graphene nanoadditives in calcium aluminate-rich coatings, J. Eur. Ceram. Soc., 2023, 43, 6504-6515
97)E. Storti, M. Lojka, S. Lencová, J. Hubálková, O. Jankovský, Ch. G. Aneziris, Synthesis and characterization of nanoplatelets-containing fibers by electrospinning, Open Ceramics, 2023, 15, 100395.
98)A. Jiříčková, A.-M. Lauermannová, O. Jankovský, J. Fathi, M. Záleská, A. Pivák, M. Pavlíková, M. Jeremiáš, Z. Pavlík, Utilization of waste carbon spheres in Magnesium Oxychloride Cement, Case Studies in Construction Materials, 2023, 19, e02374.
99)A.-M. Lauermannová, O. Jankovský, M. Lojka, E. Storti, B. Bock-Seefeld, Christos G. Aneziris, Lactose/tannin-based calcium aluminate coatings for carbon-bonded alumina foam filters: a novel approach in environment-friendly steel melt filtration, Ceramics International, 2023,49(22),35574-35584.
100)O. Jankovský, A.-M. Lauermannová, F. Antončík, M. Záleská, M. Pavlíková, A. Pivák, Z. Pavlík, Case Study on nanoscale modification of MOC-based construction composites: Introduction of molybdenum disulfide for increased water resistance, Case Studies in Construction Materials, 2023, 19, e02495.
101)T. M.J. Stadtmüller, E. Storti, N. Brachhold, A.-M. Lauermannová, O. Jankovský, T. Schemmel, J. Hubálková, P. Gehre, Christos G. Aneziris, MgO–C refractories based on refractory recyclates and environmentally friendly binders, Open Ceramics, 2023, 16, 100469.
102)A. Mašláni, M. Hlína , M. Hrabovský, P. Křenek, V. S. Sikarwar, J. Fathi, S. Raman, S. Skoblia, O. Jankovský, A. Jiříčková, S. Sharma, T. Mates, R. Mušálek, F. Lukáč, M. Jeremiáš, Impact of natural gas composition on steam thermal plasma assisted pyrolysis for hydrogen and solid carbon production, Energy Conversion and Management, 2023, 297, 117748.
103)A.-M. Lauermannová, O. Jankovský, A. Jiříčková, D. Sedmidubský, M. Záleská, A. Pivák, M. Pavlíková, Z. Pavlík, MOC Composites for Constructions: Improvement of Water Resistance by Addition of Nanodopants and Polyphenol, Polymers, 2023, 15(21), 4300.
104)F. Antončík, M. Lojka, T. Hlásek , D. Sedmidubský, J. Baumann, John H. Durrell, D. Cardwell, O. Jankovský , Novel Approach for Manufacture of Single-Grain EuBCO/Ag Bulk Superconductors via Modified Single-Direction Melt Growth, Journal of the American Ceramic Society, In press.
105) J. Sklenka, O. Jankovský, T. Hlásek, F. Antončík, Novel Chemical Recycling Process of REBCO Materials Showcased on TSMG Waste, Journal of Materials Chemistry C, 2023, In press.
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Thin films
Thin films (with a thickness of low nanometers, up to multiple microns) can be prepared from various bulk materials and generally retain the properties of bulk material while improving other properties such as flexibility. Such films can be prepared by a wide variety of approaches and are used in many modern technologies, such as LEDs, semiconductors, optics, energy generation, and storage, etc.
Advanced Composites for the Construction Industry
Portland cement is has a significant CO2 footprint, and also requires a long curing time. Alternatives based on magnesium oxychloride (MOC) and oxybromide (MOB) are promising a solution to both of these problems. Both MOC and MOB are carbon neutral while having various superior properties compared to Portland cement. They have better compressive and flexural strength, superior resistance to fire and abrasion, and good thermal properties. This makes them a promising alternative to portland cement in the future.