1. Y. Gao, S. Wu, S. Liu, J. Xe, E. Pawlikowska, M. Szafran, A. Rydosz, F. Gao, Enhanced dielectric tunability and energy storage density of sandwich-structured Ba0.6Sr0.4TiO3/PVDF composites, Materials Letters 306 (2022) 130910, DOI


1. A. Paleczek, D. Grochala, A. Rydosz,  Artificial Breath Classification Using XGBoost Algorithm for Diabetes Detection, Sensors  21 (2021) 4187;

2.  X. Meng, J. Xu, J. Zhu, P. Zhang, A. Rydosz, M. J. Reeece, F. Gao,  Pyrochlore-fluorite dual-phase high-entropy ceramic foams with extremely low thermal conductivity from particle-stabilized suspension, Scripta Materialia 194 (2021) 113714; DOI: 10.1016/j.scriptamat.2020.113714

3. T. Pisarkiewicz, W. Maziarz, A. Malolepszy, L. Stobinski, D.A. Michon, A. Szkudlarek, M. Pisarek, J. Kanak. A. Rydosz, Nitrogen Dioxide Sensing using Multilayer Structure of Reduced Graphene Oxide and α-Fe2O3, Sensors 21 (2021) 1011;

4. B. Szafraniak, L. Fusnik, J. Xu, F. Gao, A. Brudnik, A. Rydosz, Semiconducting Metal Oxides: SrTiO3, BaTiO3 and BaSrTiO3 in Gas‐Sensing Applications: A Review, Coatings  11 (2021) 185;

5. A. Paleczek, B. Szafraniak, L. Fusnik, A. Brudnik, D. Grochala, S. Kluska, M. Jurzecka-Szymacha, E. Maciak, P. Kaluzynski, A. Rydosz, The Heterostructures of CuO and SnOx for NO2 Detection, Sensors 21 (2021) 4387,

6. K. Staszek, Balanced Six-Port Reflectometer With Nonmatched Power Detectors, IEEE Transactions on Microwave Theory and Techniques (2021), doi: 10.1109/TMTT.2021.3101701. PDF


1. J. Sorocki, A. Rydosz, K. Staszek, Wideband microwave multiport-based system for low gas concentration sensing and its application for acetone detection, Sensors and Actuators B 323 (2020) 128710; DOI: 10.1016/j.snb.2020.128710

2. A. Rydosz, K. Kollbek, N.-T.H. Kim-Ngan, A. Czapla, A. Brudnik, Optical diagnostics of the magnetron sputtering process of copper in an argon–oxygen atmosphere, Journal of Materials Science: Materials in Electronics 31 (2020) 11624-11636; DOI: 10.1007/s10854-020-03713-z

3. A. Rydosz, K. Dyndal, M. Sitarz, J. Xu, F. Gao, K. Marszalek, A. Rydosz, Influence of glad sputtering configuration on the crystal structure, morphology, and gas-sensing properties of the WO3 films, Coatings 10 (2020) 1-15; DOI: 10.3390/coatings10111030

4. A. Rydosz, K. Dyndal, K. Kollbek, W. Andrysiewicz, M. Sitarz, K. Marszalek, Structure and optical properties of the WO3 thin films deposited by the GLAD magnetron sputtering technique, Vacuum 177 (2020) 109378;DOI: 10.1016/j.vacuum.2020.109378

5. K. Dyndal, A. Zarzycki, W. Andrysiewicz, D. Grochala, K. Marszalek, A. Rydosz, CuO-Ga2O3 thin films as a gas-sensitive material for acetone detection, Sensors 20 (2020) 3142; DOI: 10.3390/s20113142

6. A. Rydosz, K. Dyndal, W. Andrysiewicz, D. Grochala, K. Marszalek, GLAD magnetron sputtered ultra-thin copper oxide films for gas-sensing application, Coatings 10 (2020) 378; DOI: 10.3390/coatings10040378

7. W. Andrysiewicz, J. Krzeminski, K. Skarzynski, K. Marszalek, M. Sloma, A. Rydosz, Flexible Gas Sensor Printed on a Polymer Substrate for Sub-ppm Acetone Detection, Electronic Materials Letters 16 (2020) 146-155; DOI: 10.1007/s13391-020-00199-z

8. T. Pisarkiewicz, W. Maziarz, A. Malolepszy, L. Stobinski, D. Michon, A. Rydosz, Multilayer structure of reduced graphene oxide and copper oxide as a gas sensor, Coatings 10 (2020) 1-13; DOI: 10.3390/coatings10111015

9. A. Rydosz, Chapter 28: Nanosensors for exhaled breath monitoring as a possible tool for noninvasive diabetes detection, Nanosensors for Smart Cities, Micro and Nano Technologies, 2020, pages 467-481;

10. A. Rydosz, Copper Oxide Thin Films for Sub-ppm Acetone Detection Obtained by Glancing Angle Magnetron Sputtering Deposition, ECS Meeting Abstracts, vol. MA2020-01, IMCS 10: Sensors for Breath Analysis, Biomimetic Taste, and Olfaction Sensing, MA2020-01, 2398; doi:; conference paper

11. K. Marszałek, A. Rydosz, From materials investigation to non-invasive diabetes diagnosis, Acta Physica Polonica B Proceedings Supplement 13 (2020) 759-765; doi:10.5506/APhysPolBSupp.13.759

12. A. Rydosz, K. Marszalek, G. Putynkowski, A Novel Approach for Device Dedicated to Non-Invasice Diabetes Control, Journal of Diabetes and Treatment, 5 (2020) 1077; doi: 10.29011/2574-7568.001077

13. P. Nowak, W. Maziarz, A. Rydosz, K. Kowalski, M. Ziabka, K. Zakrzewska, SnO2/TiO2 Thin Film n-n Heterostructures of Improved Sensitivity to NO2, Sensors 20 (2020) 6830; doi:10.3390/s20236830


1. K. Staszek, A. Szkudlarek, M. Kawa, A. Rydosz, Microwave system with sensor utilizing GO-based gas-sensitive layer and its application to acetone detection, Sensors and Actuators B 297 (2019) 126699; DOI: 10.1016/j.snb.2019.126699

2. A. Rydosz, K. Staszek, A. Brudnik. S. Gruszczynski, Tin dioxide thin film with UV-enhanced acetone detection in microwave frequency range, Micromachines 10 (2019) 574; DOI: 10.3390/mi10090574

3. J. Sorocki, A. Rydosz, A prototype of a portable gas analyzer for exhaled acetone detection, Applied Science 9 (2019) 2605; DOI: 10.3390/app9132605

4. A. Rydosz, A. Brudnik, K. Staszek, Metal oxide thin films prepared by magnetron sputtering technology for volatile organic compound detection in the microwave frequency range, Materials 12 (2019) 877; DOI: 10.3390/ma12060877

5. S. Gruszczynski, R. Smolarz, A. Rydosz, K. Wincza, Broadband Differentially-Fed Substrate-Integrated Directional Coupler, 2019 Conference on Microwave Techniques, COMITE 2019 – Microwave and Radio Electronics Weekdoi: 10.1109/COMITE.2019.8733577conference paper

6. A. Rydosz, K. Staszek, K. Wincza, S. Gruszczynski, Microwave system with sensor utilizing cuo-based gas-sensitive layer for acetone detection, 2019 IEEE Asia-Pacific Microwave Conference, APMC 2019doi: 10.1109/APMC46564.2019.9038248, conference paper 

Before 2019

The publications before the LAB was established could be found here.