Personal detail [2125]

E-mail:		maca@fme.vutbr.cz

Dept.:		Institute of Materials Science and Engineering
Position:		Institute Secretary for R&D Activities
Room:		A2/205

Dept.:		Institute of Materials Science and Engineering Dept. of Ceramics and Polymers
Position:		Head of Department
Room:		A2/205

Dept.:		Institute of Materials Science and Engineering Dept. of Ceramics and Polymers
Position:		Professor
Room:		A2/205

Education and academic qualification

1987, RNDr., Faculty of Science MU Brno, speciality Physics of Solid States
1997, Dr., Faculty of Mechanical Engineering BUT Brno, speciality Physical and Material Engineering
2006, Associate Professor, Faculty of Mechanical Engineering BUT Brno, speciality Physical and Material Engineering
2011, Professor, Faculty of Mechanical Engineering BUT Brno, speciality Physical and Material Engineering

Career overview

1987-1992, PhD student, Department of Foundry Engineering, FME BUT Brno
1992-2006, researcher, Institute of Materials Science and Engineering, Department of Ceramics, FME BUT Brno
2006-2011, associate professor, Institute of Materials Science and Engineering, Department of Ceramics and Polymers, FME BUT Brno
2010-so far, Head of Department of Ceramics and Polymers, IMSE FME BUT Brno
2011-so far, professor, Institute of Materials Science and Engineering, Department of Ceramics and Polymers, FME BUT Brno
2011-so far, senior researcher, CEITEC BUT
2018-2022, Deputy Director of Institute of Materials Science and Engineering FME BUT Brno
2022-so far, Research goup leader, Advanced multifunctional group, CEITEC BUT

Pedagogic activities

Basics of chemical thermodynamics and kinetics (BTK), lectures and exercises, magister study of Materials Engineering
Non-metallic materials (WNE), lectures and exercises, bachelor study of Materials Engineering
Sintering of ceramic materials (9SKE), lectures, PhD. study of Physical and Materials Engineering, Faculty of Mechanical Engineering, BUT
High-temperature processes in inorganic materials, lectures, PhD. study of Advanced Materials and Nanosciences, CEITEC BUT
Study of sintering of nanoceramic materials, tutor-specialist of PhD. thesis (ing. Petr Dobšák, ing. Eva Bartoníčková - both defended in 2010, ing. Jakub Roleček - defended in 2018), tutor of PhD. thesis (ing. Václav Pouchlý - defended in 2012, ing. Martin Kachlík - defended in 2015, ing. Tomáš Spusta - defended in 2020, ing. Vladimir Prajzler-defended in 2022, ing. Ilya Sokolov)
Leading of bachelors and diploma thesis in the field of advanced ceramics

Scientific activities

High-temperature processes in advanced ceramic materials
High-temperature interaction between alloys and ceramics
Nanoceramics processing
Processing and properties of functional ceramics (electrical, magnetical, optical,...)
98 publications within ISI Web of Knowledge, h-index 26

Academic internships abroad

1993 Birmingham University, UK
1994 Rolls&Royce, Bristol, UK
1995 Rolls&Royce, Bristol, UK
1995 Birmingham University, UK
1995 NATO ASI Course, Sesimbra, Portugal
2007 Stockholm University, Sweden
2010 University of Novi Sad, Serbien
2011 IMSNCSR “Demokritos”, Athens, Greece
2012 Stockholm University, Sweden
2018 Trondheim University, Norway

University activities

2011 - 2017, member, Academic Senate of the Faculty of Mechanical Engineering, BUT Brno
2014 - so far, member, Scientific Board of the Faculty of Mechanical Engineering, BUT Brno
2018 - 2024, vice-chair, Council of Ph.D. study Physical and Materials Engineering, FME BUT Brno
2020 - so far, vice-chair, Council of Ph.D. study Physical and Materials Engineering, FME BUT Brno

Non-University activities

member of Editorial Board of Journal of Processing and Application of Ceramics
member of Editorial Board of Science of Sintering journal
member of International Advisory Board of the Institute of Inorganic Chemistry of the Slovak Academy of Sciences
fellow of European Ceramic Society
member of Management Committee of COST 539 ACTION
member of Management Committee of RP DEMATEN, 7thFP project No. 204953
member of Management Committee of COST MP0904 ACTION
member of Management Committee of BioScaffolds, 7thFP project No. 604036
member of Management Committee of GlaCerHub, Horizon Europe project No. 101087154

Prizing by scientific community

Fellow of European Ceramic Society since 2019
10 invited lectures at international conferences
TOP 10 Excellence BUT 2007 and 2009 in publication activity
Excellent rating for GACR project No. 17-05620S, 2020

Projects

Maca K. et al.: Processing of electroceramics from nanopowders, project MEYS OC 102 (Action COST 539), 2006-9
Maca K. et al.: Reinforcement of research potential of the Department of Materials Engineering in the field of processing and characterization of nanostructured materials (RP DEMATEN), project 7th FP EU Nr. 204953, 2008 - 2011
Maca K. et al.: Processing of electroceramics from nanopowders - II, project MEYS OC 09015 (Action COST 539), 2009
Maca K. et al.: Processing and properties of ferroics and multiferroics, project MEYS LD 11035 (Action COST MP0904), 2011-13
Maca K. et al.: Natural inorganic polymers and smart functionalized micro-units applied in customized rapid prototyping of bioactive scaffolds (Bio-Scaffolds), project 7th FP EU Nr. 604036, 2013 - 2016
Maca K. et al.: Rozvoj kooperačnej a vzdelávacej platformy pre zvyšovanie cezhraničnej konkurencieschopnosti v oblasti využitia plazmových aplikácii pre sklo - keramické technológie, co-operation project between Slovak and Czech Republic Z 2241032004301, 2014
Maca K. et al.: Utilization of theoretical and experimental approaches to sintering for tailoring the microstructure and properties of advanced ceramic materials, Grant agency of the Czech Republic Nr. 15-06390S, 2015-2017
Maca K et al.: Physical activation of ceramic particles surface towards improved fine-grained advanced ceramics, Grant agency of the Czech Republic Nr. 17-05620S, 2017-2019
Maca K. et al.. Development of functional ceramic and glass ceramic materials in collaboration with the Centre of Excellence FunGlass, project Inter-Excellence, MEYS, Nr. LT13018, 2018-2022
Maca K. at al.: Control of microstructure and properties of lead-free piezoceramic materials through advanced ceramic processing, Grant agency of the Czech Republic Nr. 18-20498S, 2018-2020
Maca K. et al.: Microstructure and functional properties refinement by dopant distribution in transparent ceramics – combined experimental and theoretical approach, Grant agency of the Czech Republic Nr. 20-14237S, 2020-2022
Maca K. et al.: Tailoring of interfaces in lead-free ferroelectric-dielecric composites to enhance their electromechanical properties, Grant agency of the Czech Republic Nr. 21-24805S, 2021–2023
Maca K. et al.: Research and development of filtration equipment for electrical insulating liquids using highly functional ceramic materials, Technological Agency of the Czech Republic Nr. FW06010300, 2023–2026
Maca K. et al.: Glass-ceramic innovation ecosystem for implementation of new research directions in applications (GlaCerHub), Horizon Europe project Nr. 101087154, 2023–2027

Sum of citations (without self-citations) indexed within SCOPUS

1670

Sum of citations (without self-citations) indexed within ISI Web of Knowledge

1510

Supervised courses:

Publications:

DRDLÍKOVÁ, K.; KLEMENT, R.; DRDLÍK, D.; SPUSTA, T.; GALUSEK, D.; MACA, K.:
Luminescent Er3+doped transparent alumina ceramics, Elsevier
journal article in Web of Science
SALAMON, D.; KALOUSEK, R.; ZLÁMAL, J.; MACA, K.:
Role of conduction and convection heat transfer during rapid crack-free sintering of bulk ceramic with low thermal conductivity
journal article in Web of Science
POUCHLÝ, V.; MACA, K.:
Sintering kinetic window for yttria-stabilized cubic zirconia
journal article in Web of Science
SPUSTA, T.; SVOBODA, J.; MACA, K.:
Study of pore closure during pressure-less sintering of advanced oxide ceramics
journal article in Web of Science
SALAMON, D.; KALOUSEK, R.; MACA, K.; SHEN, Z.:
Rapid Grain Growth in 3Y-TZP Nanoceramics by Pressure-Assisted and Pressure-Less SPS
journal article in Web of Science
MACA, K.; POUCHLÝ, V.; BODIŠOVÁ, K.; ŠVANCÁREK, P.; GALUSEK, D.:
Densification of fine-grained alumina ceramics doped by magnesia, yttria and zirconia evaluated by two different sintering models
journal article in Web of Science
XIONG, Y.; FU, Z.; POUCHLÝ, V.; MACA, K.; SHEN, Z.:
Preparation of Transparent 3Y-TZP Nanoceramics with No Low-Temperature Degradation
journal article in Web of Science
POUCHLÝ, V.; MACA, K.; SHEN, Z.:
Two-stage master sintering curve applied to two-step sintering of oxide ceramics,
Journal of the European Ceramic Society, Vol.33, (2013), No.12, pp.2275-2283, ISSN 0955-2219
journal article - other

List of publications at Portal BUT

Abstracts of most important papers:

POUCHLÝ, V.; MACA, K.; SHEN, Z.:
Two-stage master sintering curve applied to two-step sintering of oxide ceramics,
Journal of the European Ceramic Society, Vol.33, (2013), No.12, pp.2275-2283, ISSN 0955-2219
journal article - other
Tetragonal (3 mol% Y2O3) and two cubic zirconia (8 mol% Y2O3) as well as alumina green bodies were used for the construction of the Master Sintering Curve (MSC) created from sets of constant-rate-of-heating (CRH) sintering experiments. The activation energies calculated according to the MSC theory were 770 kJ/mol for Al2O3, 1270 kJ/mol for t-ZrO2, 620 kJ/mol and 750 kJ/mol for c-ZrO2. These values were verified by an alternative approach based on an analysis of the densification rate in the intermediate sintering stage. The MSCs established from the Two-Step Sintering (TSS) experiments showed at high densities a significant deflection from those constructed from the CRH experiments. This deflection was explained by lower sintering activation energy in the closed porosity stage. A new two-stage MSC model was developed to reflect the change in sintering activation energy and to describe TSS. The efficiency of TSS of four materials under investigation was correlated with their activation energies during the final sintering stage.
KACHLÍK, M.; MACA, K.; GOIAN, V.; KAMBA, S.:
Processing of phase pure and dense bulk EuTiO3 ceramics and their infrared reflectivity spectra, ELSEVIER
journal article in Web of Science
The aim of this work was to prepare phase pure and dense EuTiO3 ceramics and to establish their infrared reflectivities. Two kinds of stoichiometric powder mixture (Eu2O3+Ti2O3 and Eu2O3+TiO2) were used as precursors for shaping green bodies by cold isostatic pressing. Dense bulk samples were prepared by pressure-less sintering in reducing (Ar+7%H2, 100%H2) conditions in a temperature range of 1300–1650 C. The sample prepared from Eu2O3+TiO2 powder mixture sintered in pure hydrogen at a temperature of 1400 C for 2 hours exhibited a relative density higher than 95%TD and 100% phase purity, which resulted in its high infrared reflectivity affected by neither low density nor phase impurities
MACA, K.; POUCHLÝ, V.; ŽALUD, P.:
Two-Step Sintering of Oxide Ceramics with Various Crystal Structures, Elsevier
journal article in Web of Science
The influence of Two-Step Sintering (TSS) process on the final microstructure of oxide ceramic materials with three different crystal structures was studied. Two kinds of alumina (particle size 100nm resp. 240nm) as well as tetragonal zirconia (stabilized with 3mol%Y2O3, particle size 60nm) and cubic zirconia (8mol%Y2O3, 140nm) powders were cold isostatically pressed and pressureless sintered with different heating schedules. The microstructures achieved with TSS method were compared with microstructures achieved with conventional Single-Step Sintering schedule (SSS). The results showed that the efficiency of the TSS of these oxide ceramics was more dependent on their crystal structure than on their particle size and green body microstructure. The method of TSS brought only negligible improvement of the microstructure of tetragonal zirconia and hexagonal alumina ceramics. On the other hand, TSS was successful in the sintering of cubic zirconia ceramics; it led to a decrease in grain size by a factor of 2.
MACA, K.; CIHLÁŘ, J.; ČÁSTKOVÁ, K.; ZMEŠKAL, O.; HADRABA, H.:
Sintering of gadolinia-doped ceria prepared by mechanochemical synthesis, Elsevier Science
journal article in Web of Science
Gadolinia-doped ceria (GDC) ceramics were prepared by mechanochemical synthesis of ceria and gadolinia (10mol.%) powders with subsequent uniaxial pressing and pressureless sintering. The mechanochemical synthesis was conducted in an attritor with different dispersion media: neutral (distilled water), basic (aqueous solution of ammonia), acidic (aqueous solution of propionic acid), and non-polar medium (xylene with stearic acid). The effect of suspension composition and attritor milling time on the sintering behaviour and ionic conductivity of GDC was studied. An attritor milling time of 3 to 6 hours was evaluated as the optimum milling time from the viewpoint of further sintering behaviour. Longer milling times resulted in nanometre-sized powders, whose sintering behaviour deteriorated due to powder agglomeration. The appearance of agglomerates in the non-polar medium was reduced. The ionic conductivity of the samples was evaluated by impedance spectroscopy and correlated with their microstructure.
TRUNEC, M.; MACA, K.:
Compaction and Pressureless Sintering of Zirconia Nanoparticles,
Journal of the American Ceramic Society, Vol.90, (2007), No.9, pp.2735-2740, ISSN 0002-7820, Blackwell Publishing
journal article - other
Four nanometer-sized zirconia powders stabilized by 3 mol% Y2O3 were used for the preparation of dense bulk ceramics. Ceramic green bodies were prepared by cold isostatic pressing at pressures of 300-1000 MPa. The size of pores in ceramic green bodies and their evolution during sintering were correlated with the characteristics of individual nanopowders and with the sintering behavior of powder compacts. Only homogeneous green bodies with pores of less than 10 nm could be sintered into dense bodies (>99% t.d.) at sufficiently low temperature to keep the grain sizes in a range <100 nm. Powder with uniform particles of 10 nm in size yielded green bodies of required microstructure. These nanoparticle compacts were sintered without pressure to give bodies (diameter 20 mm, thickness 4 mm) with a relative density higher than 99% and a grain size of about 85 nm (as determined by linear intercept method).