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Dr Lucjan Kozielski University of Silesia 12 Żytnia St., 41-200 Sosnowiec, POLAND Tel. +48 32 2691870; Fax. +48 32 2691863

Curriculum Vitae

Content 1. Biographical data p. 2 2. Scientific productivity p. 4

2.1 Papers p. 4 2.2 Patents p. 5 2.3 National research projects 6 2.4 Foreign research projects 6 2.5. Scientific leadership 6 2.6 Recent international collaborations. 7

3 Extramural activities 7 3.1 Organization of conferences 7 3.2 Invited lectures 7 3.3 Appointed as the referee of international journals 8 3.4 Completed original design, construction or technical elaboration for industry 8

4. Recent teaching experience 8 4.1 Lectures 9 4.2 Laboratories, seminars, exercises 9

5. Membership of professional bodies 9 6. Leisure activities and hobbies 9 7 Closing remarks 9

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1. Lucjan Kozielski – Biographical Data

1962 – born in Mikołów (Poland), married (1989), 1 child 1981-1987 SILESIAN TECHNICAL UNIVERSITY, Gliwice, Poland 1987 – M.Sc. in Electric Engineering Specialty: Energy Conversion and Operational Use, Silesian Technical University, Gliwice, Poland 1988 – 1990 industrial practice in “Energoprojekt” Katowice and Gdańsk, in which was assisted in designing the first Atomic Power Plant in Poland in Żarnowiec (North of Poland) from 1990 – Technical Assistant and later Senior Resaercher in Electroceramics and Micromechatronics Division at the Institute of Technology and Mechatronics, University of Silesia, Sosnowiec Żytnia 12, Poland 1994 – 1998 German language course finshed with passing the “ZDaF (Certificate: German as a foreign language) - Goethe Institut” 1998 – 2003 English language course finshed with passing the First Certificate in English FCE 2007 – Ph.D. thesis: “Technology of gradient piezoelectric ceramic-based solid solution of PZT type for energy transducers applications” (Otrzymywanie gradientowej ceramiki piezoelektrycznej na bazie roztworu stałego typu PZT do zastosowań w przetwornikach energii). Thesis was awarded by Scientific Council of the Department of Informatics and Material Science, University of Silesia. The thesis provided interdisciplinary approach to graded structure phenomena, that allows an efficiency increase of piezoelectric transformer, based on the artificial graded connection of piezoelectric input and output part from the highest performance materials specific for each part separately. It was concluded, that increased energy transfer in such graded construction of piezoelectric transformer is due to synergy of higher transformation coefficients of the both parts of this specific device. Such a case is not possible in monolithic piezoelectric ceramics, in which optimisation can be targeted only for one part of transformer. 2007 (1 March - 15 September) – Postdoc position in the Nordic Hysitron Laboratory,

Department of Materials Science, Helsinki University of Technology in Finland. In frame of Finish - Japanese project founded by Finland Academy of Science, were conducted Nano indentation deformation and Atomic Force Microscopy Piezoresponse Mode (PFM) investigations of lead free piezoelectric materials supervised by professor Wataru Sakamoto from Nagoya University and doctor Shijo Nagao from Osaka University. 2008 (26-29 May) – improving the PFM investigations competence for piezoelectric materials during organized by professor Nava Setter „2nd International Piezoresponse Force Microscopy Workshop”, EPFL Lausanne, Switzerland. 2008 (26-27 June) – improving the AFM competence during Scanning and Short Response Microscopy School in Centre for Nanometer-scale Science and Advanced Materials (NANOSAM); Jagiellonian University, Kraków, Poland.

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2008 - 2014 – Academic Teacher at the Mechatronics University, 11 Listopada street 13, 40-387 Katowice, Poland. From 2012 to 2014 at the position of Vice Dean for Infrastructure and Laboratories of this University. Applicant gained a lot of teaching experience conducting 1500 hours of lectures and laboratories and supervising of 91 Engineering Thesis. 2008 - 2011 manager of research project of Polish Ministry of Science and Education N N507 352635 “Piezoelectric transformer with optical and magnetic feedback”.

The main objective of this project was synthesis, advanced characterization and modeling of single-and multi-phase multiferroic and piezoelectric – photovoltaic micro systems for piezoelectric transformers application. Multi fuctional oxides with various boundary conditions were produced by innovative synthesis and a top-down approach, investigated by manifold complex tools and theoretically described by analytical modeling.

As the result of the project 16 reviewed and highly indexed by Scopus papers had been published and additionally 3 patents restricted. 2009 (September) – PLC controller programming course, ASTOR Katowice, Poland. 2009 (July), 2010 (April), 2012 (February), 2013 (November), 2014 (December), 2015 (February and May), 2016 (February) – Short Term Scientific Missions (one or two weeks), Technical University of Liberec, Piezoelectricity Research Laboratory.

Research area: energy conversion efficiency measurements of fabricated from piezoelectric as well as multi functional materials Piezoelectric Transformers and additional investigation of the light and magnetic field induced variation of piezoelectric coefficients. The recorded results was included in my Habilitation Monograph: Piezoelectric transformer in transducer applications (Uniwersytet Śląski, Wydawnictwo Gnome, Katowice 2012, p. 123) and in many publications. 2010 (March) –2014 (Juni) contractor in EU research project: Single- and multiphase ferroics and multiferroics with restricted geometries (SIMUFER): Chair Prof Liliana MITOSERIU Funding amount: EUR 527,700 EUR. Short description: Ferroic and multiferroic oxides with various boundary conditions (thin films, free-standing, supported nano-particles/wires/ribbons/islands/toroids, hollow particles, hierarchical structures) and multiphase systems with at least one ferroic or multiferroic component were produced by innovative synthesis and a top-down approach, investigated by manifold complex tools and theoretically described by multiscale modeling. In the frame of the grant was supported Lucjan Kozielski Short Scientific Mission in Technical University of Liberec, Liberec (CZ). 21.05 - 31.05.2012 (800 EUR). Web page: http://www.cost.eu/COST_Actions/mpns/MP0904 2010 (April) –2013 (March) contractor in an international grant of Portugal Fundação para a Ciência e a Tecnologia, I.P. “Ferromagnetic nanocrystals based on doped ZnO for tunneling magneto resistance (TMR) devices”. Grant number: PTDC/FIS/098943/2008 Funding amount: EUR 185,000. Chair: Prof Maria de Jesus de Matos Gomes. Web page: http://www.fct.pt/apoios/projectos/consulta/vglobal_projecto.phtml.en?idProjecto=98943&idElemConcurso=2805 2010 (04-07 May) SCADA industrial controlling and visualization systems course, Astor Academy Gdańsk.

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2011 (April), 2013 (July), 2015 (February and May), 2016 (March) – Short Term Scientific Missions (one or two weeks) at Advanced Ceramics Laboratory, Federal Institutes of Technology EMPA in ETH Zurich Domain, Duebendorf, Switzerland.

Research area: the synthesis of functional piezoelectric materials in micro fiber form, their characterisation and processing. The particles are applied in polymer composites, coatings and ceramic components with the objective to create materials with higher piezoelectric properties and therewith the potential for innovative applications of piezoelectric transformers and harvesters. Dr Kozielski supervised there or scientific coordinated 5 half year technological works and subsequent Master Thesis performed in personal collaborations with dr Frank Clemens. 2011 (June) –Industrial robots programming course, ASTOR Kraków 2012 (from 21th to 31 May) – Short Term Scientific Mission (STSM) commissioned by MP0904 COST Action : Single- and multiphase ferroics and multiferroics with restricted geometries (SIMUFER) in Technical University of Liberec. 2013 May 15 th. The scientific supervised by L. Kozielski PhD project from Brygida Dzidek in prestigious Ministry of Science and Higher Education “Diamentowy Grant” competition awarded 51 position from over 300 other projects. It is important to underline, that B. Dzidek Master Thesis and her technological half a year work at EMPA Advanced Ceramics Laboratory in Switzerland was previously supervised by applicant. From 2014 – Academic Teacher at the Katowice School of Technology, 43 Rolna street, 40-555

Katowice, Silesia province, Poland. From 2015 at the position of supervisor of students industrial practices. Applicant gained a lot of teaching experience conducting 454 hours of lectures and laboratories and supervising of 26 Engineering Thesis.

2015 (24-25 February) – improving the AFM investigations competence for piezoelectric materials during Nt-MDT Workshop „ Techniques of AFM Raman, SNOM and TERS”, Frankfurt, Germany. 2015 (15-18 September) participation in the visualization system course Wonderware InTouch

organized by Astor Academy, Warszawa 2015 - 2018 manager of research project of The National Centre for Research and Development TANGO1/266384/NCBR/2015 " Implementation of the piezoelectric transformer for sensing, energy harvesting and biomedical applications.

The main objective of this project was synthesis, advanced characterization and fabrication of single-and multi-phase multiferroic materials for piezoelectric sensors, energy harvesters and transformer for biomedical applications. 2. Scientific productivity 2.1 Papers Please refer to the attached list of 42 publications indexed by SCOPUS bibliographic database (Hirsch Index = 6, number of citations = 87) and additional 13 own research results in scientific journals recorded by GOOGLE SCHOLAR web search engine. One published scientific monographs: KOZIELSKI, Lucjan. Piezoelectric Transformer in Transducer Applications. University of Silesia, 2012. The provided copies of all papers are meant as a proof of the quality of the work performed so far.

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2.2. Patents 1. No. and date of the Polish Patent Office acceptance: P 390585, 02.03.2010. No. and

date of grant of the patent: PL 218084, 16.04.2015. Title of the invention: Piezoelectric transformer with optical feedback. The inventors: Lucjan Kozielski Short description: Piezoelectric Transformer have been fabricated from material with the piezoelectric and photovoltaic properties at the same time. The voltage gain defined as the output to input voltage ratio is dependent to the light intensity (optical feedback).

2. No. and date of the Polish Patent Office acceptance: P 392870; 05.11.2010. Title of the invention: Piezoelectric transformer with magnetic feedback. No. and date of grant of the patent: PL 218706, 29.09.2015. The inventors: Lucjan Kozielski Short description: Piezoelectric Transformer have been fabricated from material with the piezoelectric and magnetic properties at the same time. The voltage gain defined as the output to input voltage ratio is dependent to the magnetic field intensity (magnetic feedback).

3. No. and date of the Polish Patent Office acceptance: P 397547; 23.12.2011. Title of the invention: Magnetic field sensor from piezoelectric - magnetic transformer. The inventors: Lucjan Kozielski Short description: Multiferroic two phase material have been used for fabrication of new type of transformer- sensor. The sensitivity to the magnetic field is high enough, to use of conventional multimeters for measurements of magnetic field intensity.

4. No. and date of the Polish Patent Office acceptance: P 405305, 11.09.2013. Title of the invention: The ferroelectric dielectric material and process for its preparation. The inventors: Beata Wodecka-Duś, Małgorzata Adamczyk-Habrajska, Lucjan Kozielski, Dionizy Czekaj Short description: new material useful especially in ultra capacitors and methods of preparing this material. The ferroelectric (Ba1-xLax) TiO3 dielectric material was produced with a spatial structure of point defects providing increased levels of donor and oxygen vacancies.

5. No. and date of the Polish Patent Office acceptance: P 405306, 11.09.2013. Title of the invention: Ultra capacitor The inventors: Beata Wodecka-Duś, Małgorzata Adamczyk-Habrajska, Lucjan Kozielski, Dionizy Czekaj Short description: Ultra capacitor with an extreme dielectric constant intended for storage of energy, that can be applied for collecting electrical energy for the rapid use in medicine or in renewable energy sources (RES).

6. No. and date of the Polish Patent Office acceptance: P 410562, 15.12.2014. Title of the invention: Fabrication method of BaBi2Nb2O9 ceramics and ceramics pressure sensor. The inventors:, M. Adamczyk-Habrajska, A. Molak, D. Czekaj, L. Kozielski, B. Wodecka-Duś, A. Kamieniarz, Z. Machnik, D. Radoszewska Short description: Ultra capacitor with an extreme dielectric constant intended for storage of energy, that can be applied for collecting electrical energy for the rapid use in medicine or in renewable energy sources (RES).

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2.3 National research projects 1. "Piezoelectric transformer with optical and magnetic feedback " N N507 352635

06.10.2008 - 05.10.2011, Higher Education Ministry. Function: project manager. 2. "The impact of the conditions of preparation and concentration on La thermo-and

piezoresistive properties of semiconductor ceramics BaTiO", funded by the Higher Education from 2010 to 2013 as grant no. N N507 494338. Function: contractor.

3. "Construction of energy converters using lead free ceramics", funded by the Higher Education in 2010-2013 as grant no. N N507 504338. Function: contractor.

4. "Nanocrystalline thin layer (Ba, Sr) TiO3 functional electroceramics for smart antenna arrays", funded by the Higher Education in the years 2006-2009 as a grant N507 098 31/2319. Function: contractor.

5. "Production of microwave BiNbO ceramic matrix” funded by the Higher Education funds for science in the years 2011 -2014 as grant no. 218540 NN507. Function: contractor.

6. “Implementation of the piezoelectric transformer for sensing, energy harvesting and biomedical applications” The National Centre for Research and Development TANGO1/266384/NCBR/2015 " 01.07.2015 - 31.12.2018. Function: project manager.

7. "The design of ultra capacitor using lead-free ceramics" (TANGO1 / 267100 / NCBR / 2015).01.07.2015 - 31.12.2018. Function: contractor.

2.4 Foreign research projects 1. „Single and multiphase ferroics and multiferroics with restricted geometries” COST

MP0904 Action, 2009-2014. Function: contractor. 2. “Ferromagnetic nanocrystals based on doped ZnO for tunneling magneto resistance

(TMR) devices”. 2010 –2013 of Grant number: PTDC/FIS/098943/2008 Portugal Fundação para a Ciência e a Tecnologia, I.P. Funding. Function: contractor. Web page: http://www.fct.pt/apoios/projectos/consulta/vglobal_projecto.phtml.en?idProjecto=98943&idElemConcurso=2805

2.5. Scientific leadership

1. While working at the University of Silesia in Katowice, the applicant was involved in general supervision of one student Master Thesis and her half a year laboratory experiments at EMPA Advanced Ceramics Laboratory in Deubendorf, Switzerland. The applicant was also secondary assistant supervisor of 17 theses concerning piezoelectric properties of bulk ceramics and thin films as well as didactic stands for laboratories.

2. While working as the Academic Teacher at the Mechatronics University in Katowice, the applicant was supervisor of 91 Engineering Thesis concerning application of piezoelectric materials and didactic stands for laboratories.

3. While working as the Academic Teacher at the Katowice School of Technology in Katowice, the applicant was supervisor of 26 Engineering Thesis concerning application of piezoelectric materials and didactic stands for laboratories.

4. Supervision of foreign students half a year stays for conducting experimental parts of their Master Thesis Work at EMPA “Advanced Ceramics Laboratory” in Switzerland:

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a) Piechowiak M., Piezoelectric Parameter Comparison of Single and 1-3 Composite Fibre PZT Structures, EMPA Advanced Ceramics Laboratory, 2007 (EMPA Project No. 841165).

b) Kasperczyk M., Processing and setting parameters of fine PZT fibres using thermoplastic co-extrusion, EMPA Advanced Ceramics Laboratory, 2008 (EMPA Project No 841179).

c) Adamska A., Developing of PLZT electro optical fibers by using thermoplastic extrusion method, EMPA Advanced Ceramics Laboratory, 2010 (EMPA Project No. 841199).

d) Dzidek B. Fabrication and characterisation of multifunctional ceramics fibres obtained by extrusion method, 2013 (EMPA Project No. 841279).

2.6 Recent international collaborations The following international collaborations have been accomplished during the applicant’s position at the Functional Electroceramics Division in Materials Science Department, University of Silesia:

1. Helsinki University of Technology, Nordic Hysitron Laboratory (Prof. R. Nowak) Mechanical characterization of advanced piezoelectric materials

2. Technical University of Liberec, Piezoelectric Resaerch Center (Prof. J. Erhart) Characterization of piezoelectric properties of multifunctional structures

3. INPT, National Polytechnic Institute of Toulouse, France (Dr. F. Pigache) Application of piezoelectric transformers for plasma generation

4. Mechanical Engineering Univ. of New Orleans (Prof. D. Hui) Mechanical properties of piezoelectric ceramics

5. EMPA Advanced Ceramics Laboratory (dr F. Clemens) Technology of piezoelectric thin fibers

3 Extramural activities 3.1 Organization of conferences Organizing Committee of: The 1st Int'l Conference on Ceramic Science and Technology (CST 2015),

Shanghai, China, 19-21.07.2015: http://www.engii.org/ws/OrganizingCommittee.aspx?id=621 Organizing Committee of: The 2nd Int'l Conference on Ceramic Science and Technology (CST 2016)

Suzhou, China, 25-27.07.2016: http://www.engii.org/ws2016/OrganizingCommittee.aspx?id=765 Smart Material Seminar Sosnowiec, Poland, 2010 - organizer 3.2 Invited lectures

1. Piezoelectric transformer with light feedback, 03.06.2010, Technical University of Liberec, Liberec.

2. Transformer piezoelectric sensor applications, 18.12.2012, Silesian Intercollegiate Center for Education and Interdisciplinary Research, Chorzów.

3. Transformer piezoelectric sensor, 01.06.2012, AGH University of Science and Technology, Kraków.

4. Piezoelectric properties of lead free (Ba, Ca)TiO3 (BCT) system, 30.10.2013, Technical University of Liberec, Liberec.

5. Multiferroic materials - Energy conversion characteristics, 28.05.2014, Technical University of Liberec, Liberec.

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6. Modern mechatronic applications of piezoelectric materials, 01.06.2015, Institute of Molecular Physics, PAS, Poznań.

7. Mutiferroic sensors, 02.07.2015, Institute of Power Engineering Ceramic Department CEREL Boguchwała near Rzeszów.

3.3 Appointed as the referee of international journals

1. Progress in Electromagnetics Research, 2011-2013, 5 times.

2. Transactions on Ultrasonics, Ferroelectrics, 2013, 2 times.

3. Ferroelectrics, 2011, 1.

4. Manuscript ID 12090607 J. Electromagnetic Waves and Applications (JEMWA) 2012.

5. Manuscript ID 12120402 J. Electromagnetic Waves and Applications (JEMWA) 2012.

6. Infrared Physics & Technology, 2013, 1.

7. Manuscript ID JALCOMD-13-02279 for Journal of Alloys and Compounds, 2013.

8. Manuscript ID GIPE-2013-0036 for Inverse Problems in Science & Engineering, 2013.

9. Manuscript ID MSB-D-13-00270 for Materials Science and Engineering B, 2013, 1

10. Manuscript ID AME‐15‐0842 for Advances in Mechanical Engineering 2015

11. Manuscript ID JALCOM‐D‐15‐01793 for Journal of Alloys and Compounds 2015.

12. Manuscript ID JALCOM‐D‐15‐05502R1 for Journal of Alloys and Compounds 2015.

13. Manuscript FE from 24.01.2015 for ask of Prof J. Petzelt for Ferroelectrics 2015.

14. Manuscript ID SNA‐D‐15‐00653 for Sensors 2015

15. ID MATCHEMPHYS‐D‐15‐02597 for Materials Chemistry and Physics 2016.

16. Manuscript ID JALCOM‐D‐15‐09934R1for Journal of Alloys and Compounds 2016.

17. Manuscript ID MATCHEMPHYS‐D‐15‐02597 for Mat. Chemistry and Physics 2016

3.4 Completed original design, construction or technical elaboration for industry 1.Completed original design of Building Automation Systems and Building Managment

Systems SCADA 01.10 – 31.12.2008, at the rink MOSiR Cieszyn ul. Sportowa 1 43-400 Cieszyn

2.Partial participation in design and implementation of control and measurement station for testing high-power fuses 01.10.2009 – 31.12.2012 P.U.P. Elnap Sp. z o. o. Company ul. Chemiczna 6 42-520 Dąbrowa Górnicza

3.Partial participation in design of Building Automation Systems and Building Managment Systems for Izba Celna Katowice ul. Słoneczna 34, 40-136 Katowice

4. Completed original design: Temperature influence on commercial and piezoelectric transformer based magnetic field sensors, 13.11. – 13 12. 2015, for company ADACO - Projects and supplies for power plants, ul. Sosnowa 12 Bukowno, Poland.

5. Completed original design: Development of the concept and design of computer-controlled magnetic field generator with adjustable amplitude and frequency, 24-31.12.2015, for company ADACO - Projects and supplies for power plants, ul. Sosnowa 12 Bukowno, Poland.

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4. Recent teaching experience During the applicant’s appointment as Academic Teacher at Mechatronics University,

Katowice School of Technology and University of Silesia in Katowice 4.1 Lectures:

1. Optoelectronics and sensor technology (undergraduate course) 2. Smart Materials (undergraduate course). 3. Smart Building systems (undergraduate course). 4. Mechatronic structures technologies (undergraduate course). 5. Electromechanical Transducers (undergraduate course). 6. Vision and navigation systems in mechatronics (undergraduate course). 7. Kinematics of robots (undergraduate course). 8. Industrial robot programming (graduate course). 9. Actuators and servodrives: (post graduate course). 10. Micromechatronics systems technology (undergraduate course). 11. PLC controllers programming (undergraduate course).

4.2 Laboratories, seminars, exercises: 1. Electronic laboratory (undergraduate course) 2. Electric laboratory (undergraduate course) 3. Actuators and servodrives laboratory (undergraduate course) 4. Mechatronics laboratory (undergraduate course) 5. PLC controllers programming laboratory (undergraduate course) 6. Automatic systems laboratory (undergraduate course) 7. Optoelectronics and sensor technology exercises (undergraduate course) 8. Smart Materials seminar (undergraduate course). 9. Electromechanical Transducers laboratory and exercises (undergraduate course). 10. Vision and navigation systems in mechatronics (undergraduate course). 11. Kinematics of robots exercises (undergraduate course). 12. Industrial robot programming laboratory (undergraduate and graduate course).

5. Membership of professional bodies

1. The Polish Ceramics Society and The Polish Acoustic Society. 2. European Cooperation in Science and Technology (COST) external expert. 3. The European Commission independent experts for European research and innovation.

6. Leisure activities and hobbies

Since childhood the applicant has been devoted to mountain hiking and skiing (the basic Montain Association License at the age of 13, guide patent 23). He has accomplished several trips in Tatra Mountains, Polish and Czech Sudetes and in the Swiss Alps as a guide (usually 6-15 members of a group) and was a manager of Students Beskids Shelter “Lasek”. 7 Closing remarks This application is motivated, in the first place, by the habilitation degree of the research performed in Poland, Czech and Switzerland. I hope that I have already demonstrated (in past and also recently) a true devotion to research and education. In particular, I found the atmosphere of research life very demanding and highly attractive for me. I do believe that my destiny is to remain in science i and to work there especially contributing to the development of international contacts.

Dr inż. Lucjan Kozielski

I. List of published scientific papers indexed by Scopus (Scopus EXPORT DATE:03 April

2016)

1. Sebastian, T., Kozielski, L., Erhart, J. Co-sintered PZT ceramics for the

piezoelectric transformers (2015) Ceramics International, 41 (8), art. no. 10353, pp. 9321-

9327.

2. Adamczyk, M., Kozielski, L., Zachariasz, R., Pawełczyk, M., Szymczak, L.

Structural, dielectric specroscopy and internal friction correlation in BaBi2Nb2O9 ceramics

(2014) Archives of Metallurgy and Materials, 59 (1), pp. 7-10.

3. Kozielski, L., Buixaderas, E., Clemens, F. Rhombohedral PLZT piezoelectric

microfibers: A combined Raman and X-ray diffraction study (2014) Phase Transitions, 87

(10-11), pp. 982-991.

4. Dzidek, B., Kozielski, L., Adamczyk, M., Pilch, M., Clemens, F. Technology

of PLZT ceramics microfibers for multiferroics composites (2013) Phase Transitions, 86 (7),

pp. 695-702.

5. Adamczyk, M., Kozielski, L., Pilch, M., Pawełczyk, M., Soszyński, A.

Influence of vanadium dopant on relaxor behavior of BaBi2Nb 2O9 ceramics (2013) Ceramics

International, 39 (4), pp. 4589-4595. Cited 2 times.

6. Kozielski, L., Erhart, J., Clemens, F.J. Light-intensity-induced characterization

of elastic constants and d33 piezoelectric coefficient of PLZT single fiber based transducers

(2013) Sensors (Switzerland), 13 (2), pp. 2419-2429. Cited 2 times.

7. Adamczyk, M., Zawada, A., Pilch, M., Kozielski, L. Influence of post-sintering

annealing on relaxor properties of BaBi 2Nb2O9 ceramics (2013) Phase Transitions, 86 (2-3),

pp. 175-181. Cited 1 time.

8. Kozielski, L., Płońska, M. Optic and piezoelectric coupling in the sol-gel PLZT

electroceramics (2013) Materials Science Forum, 730-732, pp. 129-134.

9. Kozielski, L., Płońska, M. Magnetic and piezoelectric properties of the Fe3+

doped PLZT electroceramics (2013) Materials Science Forum, 730-732, pp. 117-122.

10. Bućko, M.M., Polnar, J., Kozielski, L. Dielectric properties of some Aurivillius

phases in the Bi4Ti3O12 - BiFeO3 system (2013) Materials Science Forum, 730-732, pp. 88-

93.

11. Kozielski, L., Adamczyk, M., Erhart, J., Pawełczyk, M. Application testing of

Sr doping effect of PZT ceramics on the piezoelectric transformer gain and efficiency

proposed for MEMS actuators driving (2012) Journal of Electroceramics, 29 (2), pp. 133-138.

Cited 4 times.

12. Kozielski, L. Piezoelectric transformer with magnetic feedback on gain and

efficiency (2012) Ferroelectrics, 428 (1), pp. 74-81.

13. Kozielski, L., Adamczyk, M., Pilch, M. Comparison study of macro and micro

scale AC and DC conductivity measurements with Impedance Spectroscopy and Atomic

Force Microscopy techniques applied in PBZT ceramics (2012) Ceramics International, 38

(4), pp. 3105-3109. Cited 2 times.

14. Kozielski, L., Adamczyk, M. Magnetic and piezoelectric properties of

magnetoelectric laminate transformer (2011) Archives of Metallurgy and Materials, 56 (4),

pp. 1111-1117. Cited 1 time.

15. Kozielski, L., Adamczyk, M., Erhart, J., Rusek, K. PLZT-based light controlled

piezoelectric transformer (2011) Ferroelectrics, 417 (1), pp. 161-169. Cited 1 time.

16. Adamczyk, M., Kozielski, L., Pawełczyk, M., Pilch, M. Dielectric and

mechanical properties of BaBi2(Nb 0.99V0.01)2O9 ceramics (2011) Archives of Metallurgy and

Materials, 56 (4), pp. 1163-1168.

17. Adamczyk, M., Kozielski, L., Pilch, M. Impedance spectroscopy of BaBi 2Nb

2O 9 ceramics (2011) Ferroelectrics, 417 (1), pp. 1-8.

18. Adamczyk, M., Kozielski, L., Lisińska-Czekaj, A., Czekaj, D. Application of

the FITSC method for characterization of PZT-type ceramics with the diffuse phase transition

(2011) Journal of Alloys and Compounds, 509 (22), pp. 6452-6456. Cited 2 times.

19. Buixaderas, E., Berta, M., Kozielski, L., Gregora, I. Raman spectroscopy of

Pb(Zr1-xTix)O3 graded ceramics around the morphotropic phase boundary (2011) Phase

Transitions, 84 (5-6), pp. 528-541. Cited 6 times.

20. Kozielski, L. Light controlled piezoelectric transformer (2011) Japanese

Journal of Applied Physics, 50 (4 PART 1), art. no. 048004, . Cited 2 times.

21. Kozielski, L., Adamczyk, M., Erhart, J. PLZT-based photovoltaic piezoelectric

transformer with light feedback (2011) IOP Conference Series: Materials Science and

Engineering, 18 (SYMPOSIUM 6), art. no. 092001, .

22. Clemens, F.J., Heiber, J., Graule, T., Piechowiak, M., Kozielski, L., Czekaj, D.

Microstructural and electromechanical comparison of different piezoelectric PZT based single

fibers and their 1-3 composites (2010) Proceedings of the 2010 IEEE International

Symposium on the Applications of Ferroelectrics, ISAF 2010, Co-located with the 10th

European Conference on the Applications of Polar Dielectrics, ECAPD 2010, art. no.

5712231, .

23. Kozielski, L., Buixaderas, E., Clemens, F., Bujakiewicz-Korońska, R. PZT

microfibre defect structure studied by Raman spectroscopy (2010) Journal of Physics D:

Applied Physics, 43 (41), art. no. 415401, . Cited 4 times.

24. Kozielski, L., Adamczyk, M., Paweczyk, M. Effect of Sr doping on phase

transition and electric behaviour of (Pb 0.70Sr0.30)(Zr0.70Ti0.30)O 3 ceramics (2010) Phase

Transitions, 83 (10-11), pp. 790-799. Cited 2 times.

25. Kozielski, L., Plonska, M., Bucko, M.M. Electrical and mechanical

examination of PLZT/PZT graded structure for photovoltaic driven piezoelectric transformers

(2010) Materials Science Forum, 636-637, pp. 369-373. Cited 1 time.

26. Plonska, M., Kozielski, L., Podstawek, L. Technology of PLZT material used

for photovoltaic driven piezoelectric transformers (2010) Materials Science Forum, 636-637,

pp. 348-355. Cited 2 times.

27. Kozielski, L., Adamczyk, M. Electrical and mechanical examination of PLZT

graded structure for photovoltaic driven piezoelectric transformers (2009) Archives of

Metallurgy and Materials, 54 (4), pp. 973-978. Cited 1 time.

28. Kozielski, L., Janik, P., Janik, M., Bućko, M.M. Model explanation of

electrical characteristic anomalies in PLZT graded structure for piezoelectric transformers

(2009) 11th International Conference and Exhibition of the European Ceramic Society 2009,

1, pp. 291-296.

29. Kozielski, L., Adamczyk, M., Rusek, K., Plonska, M. Light influence on

nanomechanical characterisation of PLZT ceramics (2009) Archives of Metallurgy and

Materials, 54 (4), pp. 951-955.

30. Kozielski, L., Piechowiak, M., Czekaj, D., Lisinska-Czekaj, A., Smalarz, G.,

Clemens, F., Nowak, R. Mechanical examination of PZT microfibre defects structure (2008)

Phase Transitions, 81 (11-12), pp. 1081-1088. Cited 3 times.

31. Adamczyk, M., Kozielski, L., Pawełczyk, M. Effect of hot pressing on

processing and properties of BBN ceramics (2008) Ceramics International, 34 (7), pp. 1617-

1622. Cited 9 times.

32. Kozielski, L., Adamczyk, M., Schreithofer, N., Sakamoto, W., Nowak, R.

Impedance spectroscopy structural analysis: Ca-dopant segregation in

(Pb0.75Ba0.25)(Zr0.70Ti0.30)O 3 (2008) Japanese Journal of Applied Physics, 47 (4 PART 1), pp.

2176-2181. Cited 6 times.

33. Czekaj, D., Jaszczyszyn, E., Orkisz, T., Kozielski, L., Lisińska-Czekaj, A.,

Federowicz, E., Modelski, J. Synthesis and basic properties of ferroelectric thin films.

Methods materials and novel applications (2007) 16th International Conference on

Microwaves, Radar and Wireless Communications, MIKON 2006, art. no. 4345275, .

34. Szymczak, L., Kozielski, L., Adamczyk, M., Lisińska-Czekaj, A., Ujma, Z.,

Czekaj, D. Dielectric, pyroelectric and thermally stimulated depolarization current

investigations on (Ba,Sr)TiO3 ceramics with Bi2O 3 additive (2007) Ferroelectrics, 349 (1),

pp. 179-189. Cited 4 times.

35. Wodecka-Duś, B., Lisińska-Czekaj, A., Orkisz, T., Adamczyk, M., Osińska, K.,

Kozielski, L., Czekaj, D. The sol-gel synthesis of barium strontium titanate ceramics (2007)

Materials Science- Poland, 25 (3), pp. 791-799. Cited 9 times.

36. Kozielski, L., Lisińska-Czekaj, A., Czekaj, D. Graded PZT ceramics for

piezoelectric transformers (2007) Progress in Solid State Chemistry, 35 (2-4 SPEC. ISS.), pp.

521-530. Cited 11 times.

37. Lisińska-Czekaj, A., Czaja, M., Kozielski, L., Czekaj, D., Piechowiak, M.,

Nowakowski, M., Zawiślok, K. Photoluminescence of nanocrystalline bismuth titanate thin

films synthesized by the sol-gel metod (2006) Materials Science Forum, 514-516 (PART 1),

pp. 128-132. Cited 2 times.

38. Kozielski, L., Lisińska-Czekaj, A., Czekaj, D. Design and analysis of the PZT-

based piezoelectric transformer (2006) Materials Science Forum, 514-516 (PART 1), pp. 198-

201. Cited 1 time.

39. Kozielski, L., Adamczyk, M., Lisinska-Czekaj, A., Orkisz, T., Piechowiak, M.,

Czekaj, D. Structure and dielectric properties of PZT-type ceramics with the diffuse phase

transition (2006) Phase Transitions, 79 (6-7), pp. 427-433. Cited 11 times.

40. Adamczyk, M., Ujma, Z., Pawełczyk, M., Szymczak, L., Kozielski, L.

Influence of sintering conditions on relaxor properties of BaBi 2Nb2O9 ceramics (2006) Phase

Transitions, 79 (6-7), pp. 435-445. Cited 8 times.

41. Dudek, J., Kossakowska, M., Kozielski, L., Surowiak, Z. Influence of PbTiO3

content on basic piezoelectric properties of nano-structured PZT ceramics (2001) Prace

Naukowe Instytutu Telekomunikacji i Akustyki Politechniki Wrocławskiej, (83), pp. 389-392.

42. Adamczyk, M., Kozielski, L., Bochenek, D., Radoszewska, D., Pawełczyk,

M., Wodecka-Duś, B.: Impedance spectroscopy of vanadium modified BaBi2Nb2O9

ceramics European Physical Journal B 89 (2016) pp. 1-5.

II. List of published scientific papers not indexed by Scopus database (Google Scholar

EXPORT DATE:03 April 2016)

43. L. Kozielski, M. Adamczyk, A.Lisińska-Czekaj, D. Czekaj, R. Zachariasz, M.

Pawelczyk, M. Pilch: Mechanical properties of BaBi2Nb2O9 ceramics obtained by different

measurements techniques, World Journal of Engineering 10(4) (2013) 329-335.

44. M. Adamczyk, A. Lisińska-Czekaj, L. Kozielski, R. Zachariasz, R. Nowak and

D. Czekaj: Nano-indentation studies and macro-scale mechanical testing of vanadium

modified BBN ceramics, World Journal of Engineering 9(6) (2012) 475-480.

45. L. Kozielski, F. Clemens: Multiferroics application - Magnetic controlled

piezoelectric transformer, Processing and Application of Ceramics 6 (2012) pp. 15–20.

46. L. Kozielski, D. Bochenek: Characterization of energy conversion of

multiferroic PFN and PFN:Mn Processing and Application of Ceramics 7 [4] (2013) 167–173

47. L. Kozielski, A. Adamska: Manufacturing PLZT electro-optical fibres by the

thermoplastic extrusion method. Ceramics Materials 62 (2010) pp. 42-45.

48. L. Kozielski, P. Janik, M. Janik, A. M. Bućko: Model Explanation of Electrical

Characteristic Anomalies in PLZT Graded Structure for Piezoelectric Transformers. Ceramics

Materials, 62 (2010) pp. 471-476.

49. M. Adamczyk, K. Osińska, L. Kozielski, M. Pawełczyk: Manufacturing And

Properties of BaBi2Nb2O9 of Aurivillius Structure, Ceramic Materials 64 4 (2012) 468-472.

50. L. Kozielski, M. Płońska, M. Adamczyk, M. M. Bućko, P. Janik: Piezoelectric

Transformer With Magnetic Feedback, Ceramic Materials 64, 4, (2012), 447-451.

51. D. Czekaj, A. Lisińska-Czekaj, T. Orkisz, K. Osińska, L. Kozielski: Sol-Gel

Derived (Ba,Sr)TiO3 Thin Films for Tunable Devices, Archives of Acoustics 31 4 (2006)

385–390

52. J. Dudek, L. Kozielski, Z. Surowiak: The Influence of Preparation Conditions

on The Electro-Acoustic Properties of The PZT-Type Piezoceramic Sensors, Archives of

Acoustics 25, 1, 35–42 (2000)

53. Z. Surowiak, L. Kozielski, B. Wodecka-Dus: The Influence of Pb Vacancies

on The Properties of PZT-Type Ceramic Transducers, Archives of Acoustics 25, 2, 251–269

(2000).

54. K. Łuczak, L. Kozielski Transformatorowe Generatory Energii Do

Bezprzewodowych Sieci Samozasilających się Czujników w Budynkach Inteligentnych.

Transformer energy generators for wireless network the sensors in intelligent buildings

Zeszyty Naukowe Wyższej Szkoły Technicznej W Katowicach 6 (2014) pp. 65-71.

55. P. Smaczyński, M. Sopicka-Lizer, K. Wojciechowski, J. Plewa, D. Czekaj, L.

Kozielski: The role of the microstructure in tailoring thermoelectric properties of calcium

cobaltite based ceramic, Proceedings of the 10th ECERS conference European Ceramic

Society, June 17–21, (2007) Berlin pp. 1370–1375.

56. P. Smaczyński, M. Sopicka-Lizer, K. Wojciechowski, D. Czekaj, L. Kozielski:

Effect of Bi2O3 oxide on the electrical conductivity and thermoelectric properties of ceramics

based on calcium cobalt, Ceramics 101 (2008) pp. 203–211.

III. List of published scientific monographs:

1. KOZIELSKI, Lucjan. Piezoelectric Transformer in Transducer Applications. University of

Silesia, 2012.

IV. Publications currently in printing (after corrections)

L. Kozielski, M. Pilch, T. Lusiola, and F. Clemens: PLZT microfibers volume gradients and

anisotropy, Ferroelectrics 2016

2. L. Kozielski, M. Adamczyk, K. Feliksik, D. Bochenek, F. Clemens: PLZT microfibers

technology optimization, Archives of Metallurgy and Materials 2016

3. M. Adamczyk, J. Kusz, W. Hofmeister, M. Zubko, L Kozielski, M. Pilch, D. Bochenek, B.

Wodecka-Duś: Study of phase transition in Bi3TiNbO9-BaBi2Nb2O9 ceramics, Archives of

Metallurgy and Materials 2016

V. Patents

1. No. and date of the Polish Patent Office acceptance: P 390585, 02.03.2010. No.

and date of grant of the patent: PL 218084, 16.04.2015.

Title of the invention: Piezoelectric transformer with optical feedback.

The inventors: Lucjan Kozielski.

Short description: Piezoelectric Transformer have been fabricated from material with the

piezoelectric and photovoltaic properties at the same time. The voltage gain defined as the

output to input voltage ratio is dependent to the light intensity (optical feedback).

2. No. and date of the Polish Patent Office acceptance: P 392870; 05.11.2010.

Title of the invention: Piezoelectric transformer with magnetic feedback. No. and date of

grant of the patent: PL 218706, 29.09.2015.

The inventors: Lucjan Kozielski.

Short description: Piezoelectric Transformer have been fabricated from material with the

piezoelectric and magnetic properties at the same time. The voltage gain defined as the output

to input voltage ratio is dependent to the magnetic field intensity (magnetic feedback).

3. No. and date of the Polish Patent Office acceptance: P 397547; 23.12.2011.

Title of the invention: Magnetic field sensor from piezoelectric - magnetic transformer.

The inventors: Lucjan Kozielski.

Short description: Multiferroic two phase material have been used for fabrication of new type

of transformer- sensor. The sensitivity to the magnetic field is high enough, to use of

conventional multimeters for measurements of magnetic field intensity.

4. No. and date of the Polish Patent Office acceptance: P 405305, 11.09.2013.

Title of the invention: The ferroelectric dielectric material and process for its preparation.

The inventors: Beata Wodecka-Duś, Małgorzata Adamczyk-Habrajska, Lucjan Kozielski,

Dionizy Czekaj.

Short description: new material useful especially in ultra capacitors and methods of preparing

this material. The ferroelectric (Ba1-xLax) TiO3 dielectric material was produced with a spatial

structure of point defects providing increased levels of donor and oxygen vacancies.

5. No. and date of the Polish Patent Office acceptance: P 405306, 11.09.2013.

Title of the invention: Ultra capacitor

The inventors: Beata Wodecka-Duś, Małgorzata Adamczyk-Habrajska, Lucjan Kozielski,

Dionizy Czekaj.

Short description: Ultra capacitor with an extreme dielectric constant intended for storage of

energy, that can be applied for collecting electrical energy for the rapid use in medicine or in

renewable energy sources (RES).

6. No. and date of the Polish Patent Office acceptance: P 410562, 15.12.2014.

Title of the invention: Fabrication method of BaBi2Nb2O9 ceramics and ceramics pressure

sensor.

The inventors:, M. Adamczyk-Habrajska, A. Molak, D. Czekaj, L. Kozielski, B. Wodecka-

Duś, A. Kamieniarz, Z. Machnik, D. Radoszewska.

Short description: Ultra capacitor with an extreme dielectric constant intended for storage of

energy, that can be applied for collecting electrical energy for the rapid use in medicine or in

renewable energy sources (RES).

Katowice 17.04.2016 Dr inż. Lucjan Kozielski