Printed Intelligence Infrastructure - Publications

2023

1. Pourkheirollal, H. et al. Simplified exponential equivalent circuit models for prediction of printed supercapacitor’s discharge behavior – Simulations and experiments, Journal of Power Sources, 2023 (567), 232932.
2. Laurila, M.-M. et al., A combination of experimental and numerical method for optimizing the sensitivity of ultra-thin piezoelectric sensor with interdigitated electrodes, Flexible and Printed Electronics, 2023 (8), 015006.

2022

1. P. Vilmi, C. Schuss, E. Hannila, R. Sliz and T. Fabritius, "Dust accumulation sensing system with a screen-printed interdigitated sensor," 2022 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), Ottawa, ON, Canada, 2022, pp. 1-6, doi: 10.1109/I2MTC48687.2022.9806631.
2. Sliz, Rafal; Molaiyan, Palanivel; Fabritius, Tapio; Lassi, Ulla (2022) Printed electronics to accelerate solid-state battery development. - Nano Express 3 (2), 021002 . https://doi.org/10.1088/2632-959X/ac5d8e.
3. Sliz, Rafal; Valikangas, Juho; Silva Santos, Hellen; Vilmi, Pauliina; Rieppo, Lassi; Hu, Tao; Lassi, Ulla; Fabritius, Tapio (2022) Suitable Cathode NMP Replacement for Efficient Sustainable Printed Li-Ion Batteries, ACS applied energy materials, 5, 4 , 4047-4058 , - , DOI: 10.1021/acsaem.1c02923.
4. Rokaya, C. et al., Reliability test of fully printed and flexible organic electrolyte-based supercapacitor, Flexible and Printed Electronics, 2022 (7), 035023.
5. Fu, Z. et al., Cyclic Bending Reliability and Failure Mechanism of Printed Biodegradable Flexible Supercapacitor on Polymer Substrate, ACS Applied Materials & Interfaces, 2022 (14), 40145.
6. Laurila, M.-M. et al., Self-powered, high sensitivity printed e-tattoo sensor for unobtrusive arterial pulse wave monitoring, Nano Energy, 2022 (102), 107625.
7. Pourkheirollah, H. et al., An improved exponential model for charge and discharge behavior of printed supercapacitor modules under varying load conditions, Journal of Power Sources, 2022 (535), 231475.
8. Bhalerao, S. et al., Flexible, solution-processed, indium oxide (In2O3) thin film transistors (TFT) and circuits for internet-of-things (IoT), Materials Science in Semiconductor Processing, 2022 (139), 106354.
9. Rokaya, C. et al., Integration of fully printed and flexible organic electrolyte-based dual cell supercapacitor with energy supply platform for low power electronics, Journal of Energy Storage, 2022 (50), 104221.
10. Lozano, K. et al., Effect of Electrode Structure on the Performance of Fully Printed Piezoelectric Energy Harvesters, IEEE Journal on Flexible Electronics, 2022 (1), 24.
    

2021

1. Éva Bozó, Henri Ervasti, Niina Halonen, Seyed Hossein Hosseini Shokouh, Jarkko Tolvanen, Olli Pitkänen, Topias Järvinen, Petra S. Pálvölgyi, Ákos Szamosvölgyi, András Sápi, Zoltan Konya, Marta Zaccone, Luana Montalbano, Laurens De Brauwer, Rakesh Nair, Vanesa Martínez-Nogués, Leire San Vicente Laurent, Thomas Dietrich, Laura Fernández de Castro, and Krisztian Kordas, Bioplastics and Carbon-Based Sustainable Materials, Components, and Devices: Toward Green Electronics ACS Applied Materials & Interfaces 2021 13 (41), 49301-49312, DOI: 10.1021/acsami.1c13787
2. Ervasti, H., Järvinen, T., Pitkänen, O., Bozó, É., Hiitola-Keinänen, J., Huttunen, O.-H., Hiltunen, J., & Kordas, K. (2021). Inkjet-Deposited Single-Wall Carbon Nanotube Micropatterns on Stretchable PDMS-Ag Substrate–Electrode Structures for Piezoresistive Strain Sensing. ACS Applied Materials & Interfaces, 13(23), 27284–27294. https://doi.org/10.1021/acsami.1c04397
3. M. Haapala, et al. (2021) "Impedance plethysmography-based method in the assessment of subclinical atherosclerosis", Atherosclerosis, 319, 101-107.
4. E. Hannila, N. Heinilehto, K. Remes, J. Lauri, K. Keränen and T. Fabritius, "Hybrid Thermal Modeling to Predict LED Thermal Behavior in Hybrid Electronics," in IEEE Transactions on Instrumentation and Measurement, vol. 70, pp. 1-10, 2021, Art no. 6001910, doi: 10.1109/TIM.2020.3043112.
5. Behfar, H. et al., Failure Mechanisms in Flip-Chip Bonding on Stretchable Printed Electronics, Adv. Eng. Mater. 2021, 2100264 (1-9).
6. Lozano, K. et al., Self-Powered, Ultrathin, and Transparent Printed Pressure Sensor for Biosignal Monitoring, ACS Appl. Electron. Mater. 2021.
7. Mikkonen, R. et al., Inkjet-printed, nanofiber-based soft capacitive pressure sensors for tactile sensing, in IEEE Sensors Journal, 2021, 21, 26286-26293.
8. Rokaya, C. et al., Polymer-based printed electrolytic capacitor and its circuitry application in a low pass filtering, rectifying and energy storage unit, Flex. Print. Electron., 2021, 6, 025005.
9. Behfar, H. et al., Fully Integrated Wireless Elastic Wearable Systems for Health Monitoring Applications, IEEE Transactions on Components, Packaging and Manufacturing Technology.
10. Forouzmehr, M. et al., Selective atomic layer deposition on flexible polymeric substrates employing a polyimide adhesive as a physical mask, Journal of Vacuum Science & Technology A, 2021, 39, 012405.
11. Fu, Z. et al., Rolling reliability of polyurethane and polyurethane-acrylic ICAs interconnections on printed stretchable electronics, Microelectronics Reliability, 2021, 119, 114067.
    

2020

1. Sollami Delekta, S., Laurila, MM., Mäntysalo, M. et al. Drying-Mediated Self-Assembly of Graphene for Inkjet Printing of High-Rate Micro-supercapacitors. Nano-Micro Lett. 2020, 12, 40.
2. C. K. McGinn, et al. (2020) "Formulation, printing, and poling method for piezoelectric films based on PVDF–TrFE", Journal of Applied Physics, 128, 225304.
3. A. Railanmaa, et al. (2020) "Skin-conformable printed supercapacitors and their performance in wear", Sci Rep., 10, 15194 .
4. M. Arvani, et al. (2020) "Current Collectors for Low Resistance Aqueous Flexible Printed Supercapacitors", Journal of Energy Storage, 29, 101384.
5. M. Arvani, et al. (2020) "Additive manufacturing of monolithic supercapacitors with biopolymer separator", Journal of Applied Electrochemistry, 50, 689–697 .
6. M. Kujala, et al. (2020) "Bending reliability of screen-printed vias for a flexible energy module", npj Flex Electron, 4, 24.
7. D. Di Vito, et al. (2020) "Mechanically driven strategies to improve electromechanical behaviour of printed stretchable electronic systems", Sci Rep., 10, 12037.
8. M. Mosallaei, et al. (2020) "Improvements in the electromechanical properties of stretchable interconnects by locally tuning the stiffness", Flex. Print. Electron., 5, 015004.
9. R. Mikkonen, et al. (2020) "Inkjet Printable Polydimethylsiloxane for All-Inkjet-Printed Multilayered Soft Electrical Applications", ACS Appl. Mater. Interfaces, 12, 10, 11990-11997.
10. C. Liedert, L. Rannaste, A. Kokkonen, O.-H. Huttunen, R. Liedert, J. Hiltunen, L. Hakalahti (2020) "Roll-to-Roll Manufacturing of Integrated Immunodetection Sensors", ACS Sensors, 5 (7), pp. 2010-2017.
11. A. Huttunen, S. Aikio, M. Kurkinen, J.-T. Mäkinen, R. Mitikka, L. Kivimäki, M. Harjumaa, J. Takalo-Mattila, C. Liedert, J. Hiltunen, L. Hakalahti (2020) "Portable Low-Cost Fluorescence Reader for LFA Measurements", IEEE Sensors Journal, 20 (17), art. no. 9088161, pp. 10275-10282.
12. S. Asgari, T. Fabritius (2020) “Equivalent circuit model of graphene chiral metadevice absorber composed of U-shaped resonator array”, Optics Express, 28(26), 39850-39867.
13. R. Sliz, J. Czajkowski and T. Fabritius (2020) “Taming the coffee ring effect – enhanced thermal control as method for thin-films nanopatterning” Langmuir 36 (32), 9562-9570.
14. I. Niskanen, J. Lauri, M. Yokota, R. Heikkilä, T. Hashimoto, T. Fabritius (2020) “Determination of the refractive index of particles through the immersion solid matching method”, IEEE Trans. of Instrumentation and Measurements.
15. R. Sliz, O-H Huttunen, E. Jansson, J. Kemppainen, J. Schroderus, M. Kurkinen and T. Fabritius (2020) ”Reliability of R2R-printed, flexible electrodes for e-clothing applications”, NPJ Flexible Electronics 4(/1) 1-9.
16. E. Hannila, K. Remes, T. Kurkela, T. Happonen, K. Keränen and T. Fabritius (2020) “The effect of torsional bending on reliability and lifetime of printed silver conductors”, IEEE Transaction on Electron Devices, 67(6), 2522-2528.
17. S. Asgari, N. Granpayeh and T. Fabritius (2020) “Controllable terahertz cross-shaped three-dimensional graphene intrinsically chiral metastructure and its biosensing application” Optics Communications, 474, 126080.
18. S. Asgari and T. Fabritius (2020) “Tunable Mid-Infrared Graphene Plasmonic Cross-Shaped Resonator for Demultiplexing Application”, Applied Sciences, 10(3), 1193.
19. Tuomo Siponkoski, Mikko Nelo, Heli Jantunen, Jari Juuti, A printable P(VDF-TrFE)-PZT Composite with Very High Piezoelectric Coefficient, Applied Materials Today, Volume 20, 2020, 100696, ISSN 2352-9407, https://doi.org/10.1016/j.apmt.2020.100696
20. Blomquist, N., Koppolu, R., Dahlström, C., Toivakka, M., and Olin, H. (2020). Influence of Substrate in Roll-to-roll Coated Nanographite Electrodes for Metal-free Supercapacitors. Scientific Reports, 10(1).
21. Wang, X., Wang, Q., and Xu, C. (2020a). Nanocellulose-Based Inks for 3D Bioprinting: Key Aspects in Research Development and Challenging Perspectives in Applications – A Mini Review. Bioengineering, 7(2):40.
22. Wickström, H., Koppolu, R., Mäkilä, E., Toivakka, M., and Sandler, N. (2020). Stencil Printing – A Novel Manufacturing Platform for Orodispersible Discs. Pharmaceutics, 12(1):33.
    

2019

1. K. Remes and T. Fabritius (2019) “Non-contact Characterization of Flexible Hybrid Electronics by Synchronized Thermography” IEEE Transaction of Instrumentation and Measurement 69 (5), 2390-2397.
2. R. Sliz, M. Lejay, J. Fan, S. Kinge, S. Hoogland, T. Fabritius, F P. Garcia de Arquer, E.H. Sargent (2019) “Stable Colloidal Quantum Dot Inks Enable Inkjet-Printed High-Sensitivity Infrared Photodetectors”, ACS Nano 13(10), 11988-11995.
3. E. Hannila, B. Augustine, T. Kurkela, J. Lauri, T. Fabritius (2019) ”Yield and Electrical Functionality of the Glass Laminated Conductive Wires and Connectors”, IEEE Transactions on Components, Packaging and Manufacturing Technology, 9(12), 2499-2505.
4. I. Niskanen, J. Lauri, J. Räty, R. Heikkilä, H. Liimatainen, T. Hashimoto, T. Fabritius, M. Yokota (2019) ”Monitoring drying process of varnish by immersion solid matching method”, Progress in Organic Coatings, 136, 105299.
5. I. Niskanen, T. Suopajärvi, H. Liimatainen, T. Fabritius, G. Thungström (2019) “Determining complex refractive index of cellulose nanocrystals by combination of Beer-Lambert and immersion matching methods”, Journal of Quantitative Spectroscopy and Radiative Transfer, 235, 1-6.
6. K. Remes, A. Järvenpää, T. Fabritius (2019) “Contactless online characterization of large-area conductive thin films by thermography and induction”, Optics Letters, 44(10), 2574-2577.
7. J. Lauri, C. Liedert, A. Kokkonen, T. Fabritius (2019) “Effect of solvent lamination on roll-to-roll hot-embossed PMMA microchannels evaluated by optical coherence tomography”, Materials Research Express, 6(7), 075333.
8. X. Shi, Z. Hong, M. Laakso, F. Niklaus, R. Sliz, T. Fabritius, M. Somani, T. Nyo, Z. Wang, M. Zhang, G. Wang, J. Kömi, M. Huttula and W. Cao (2019) “Quantitative assessment of structural and compositional colors induced by femtosecond laser: A case study on 301LN stainless steel surface”, Applied Surface Science, 484, 655-662.
9. B. Augustine, K. Remes, G. Lorite, J. Varghese and T. Fabritius (2019) “Recycling perovskite solar cells through inexpensive quality recovery and reuse of patterned indium tin oxide and substrates from expired devices by single solvent treatment”, Solar Energy Materials and Solar Cells, 194, 74-82.
10. A. Railanmaa, et al. (2019) "Non-toxic printed supercapacitors operating in sub-zero conditions", Scientific Reports, Vol. 9, 14059.
11. M. Schubert, et al. (2019) "Printed Flexible Microelectrode for Application of Nanosecond Pulsed Electric Fields on Cells", Materials, 12(17), 2713.
12. M.-M. Laurila, et al. (2019) "Evaluation of printed P(VDF-TrFE) pressure sensor signal quality in arterial pulse wave measurement", IEEE Sensors Journal, 8796416.
13. T. Vuorinen, et al. (2019) "Validation of Printed, Skin‐Mounted Multilead Electrode for ECG Measurements", Advanced Materials Technologies, 1900246.
14. A. Railanmaa, et al. (2019) "Highly flexible and non-toxic natural polymer gel electrolyte for printed supercapacitors for IoT", Appl. Phys. A, 125: 168.
15. M.-M. Laurila, et al. (2019) "A Fully Printed Ultra-Thin Charge Amplifier for On-Skin Biosignal Measurements", IEEE Journal of the Electron Devices Society, vol. 7, pp. 566-574.

2022

1. Pourkheirollah, H. et al., A Modified Exponential Equivalent Parallel Resistance (EPR) Model for Predicting Self-Discharge Behavior of Printed Flexible Supercapacitors, 2022 IEEE 9th Electronics System-Integration Technology Conference (ESTC), 2022, pp. 264-268, doi: 10.1109/ESTC55720.2022.9939466.
2. Fu, Z. et al., Assessment of a Cyclic Bending Test Method for Printed Flexible Supercapacitor, FLEPS 2022 – IEEE International Conference on Flexible and Printable Sensors and Systems, 2022, pp. 1-4, doi:10.1109/FLEPS53764.2022.9781495.

2021

1. R. Sliz, M. Karzarjeddi, H. Liimatainen and T. Fabritius, "Nanocellulose as Sustainable Replacement for Plastic Substrates in Printed Electronics Applications," 2021 IEEE 11th International Conference Nanomaterials: Applications & Properties (NAP), Odessa, Ukraine, 2021, pp. 1-4, doi: 10.1109/NAP51885.2021.9568541.
2. R. Sliz, J. Valikangas, P. Vilmi, T. Hu, U. Lassi and T. Fabritius, "Replacement of NMP solvent for more sustainable, high-capacity, printed Li-ion battery cathodes," 2021 IEEE 16th Nanotechnology Materials and Devices Conference (NMDC), Vancouver, BC, Canada, 2021, pp. 1-5, doi: 10.1109/NMDC50713.2021.9677509.
3. Montero, K.L., Laurila, M. -M. and Mäntysalo, M. Fully Printed Unobtrusive and Skin-conformable Piezoelectric Energy Harvester, 2021 IEEE International Conference on Flexible and Printable Sensors and Systems (FLEPS), 2021, pp. 1-4, doi: 10.1109/FLEPS51544.2021.9469861.

2020

1. P. Vilmi, R. Sliz and T. Fabritius, "Double-sided environmental sensor for high-efficiency particulate air filter," 2020 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), Dubrovnik, Croatia, 2020, pp. 1-5, doi: 10.1109/I2MTC43012.2020.9128647.
2. E. Hannila, N. Heinilehto, J. Lauri, K. Keränen and T. Fabritius, "Measuring and modelling the thermal behavior of LEDs in structural electronics," 2020 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), Dubrovnik, Croatia, 2020, pp. 1-6, doi: 10.1109/I2MTC43012.2020.9128941.
3. R. Sliz et al., "Influence of elongation and washing on double-layer R2R-printed flexible electrodes for smart clothing applications," 2020 IEEE 20th International Conference on Nanotechnology (IEEE-NANO), Montreal, QC, Canada, 2020, pp. 282-287, doi: 10.1109/NANO47656.2020.9183549.
4. Montero, K.L., Laurila, M. -M. and Mäntysalo, M. All Printed Flexible Piezoelectric Pressure Sensor with Interdigitated Electrodes, 2020 IEEE 8th Electronics System-Integration Technology Conference (ESTC), 2020, pp. 1-6, doi: 10.1109/ESTC48849.2020.9229777.
5. Mikkonen, R. and Mäntysalo, M., Inkjettable, polydimethylsiloxane based soft electronics, 2020 IEEE International Conference on Flexible and Printable Sensors and Systems (FLEPS), 2020, pp. 1-3, doi: 10.1109/FLEPS49123.2020.9239558.
6. M. Rohaim, et al., Design of Thin, High Permittivity, Multiband, Monopole-Like Antennas, 2020 IEEE 19th Biennial Conference on Electromagnetic Field Computation (CEFC), 2020, pp. 1-4, doi: 10.1109/CEFC46938.2020.9451492.
7. M. Arvani et al., Flexible Energy Supply for Distributed Electronics Powered by Organic Solar Cell and Printed Supercapacitor, 2020 IEEE 20th International Conference on Nanotechnology (IEEE-NANO), Montreal, QC, Canada, 2020, pp. 257-262, doi: 10.1109/NANO47656.2020.9183493.
8. Hakola, L. et al., Sustainable materials and processes for electronics, photonics and diagnostics, Electronics Goes Green 2020+, Berlin, Germany, September 1. 2020, ISBN 978-3-8396-1659-8 Proceedings, pp. 45-52.
   

2019

1. C. Schuss, T. Fabritius, B. Eichberger and T. Rahkonen (2019) “Impacts on the Output Power of Photovoltaic Cells on Top of Electric and Hybrid Electric Vechicles” IEEE Transaction of Instrumentation and Measurement 69(5) 2449-2458.
2. J. Lauri, E. Hannila and T. Fabritius, "Non-Destructive Characterization of Glass Laminated Electronics," 2019 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 2019, pp. 1-5.

-