Your search keyword '"Awsiuk, Kamil"' showing total 6 results

1. Electrically Switchable Film Structure of Conjugated Polymer Composites

Author

Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, Budkowski, Andrzej, Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, and Budkowski, Andrzej

Abstract

Domains rich in different blend components phase-separate during deposition, creating a film morphology that determines the performance of active layers in organic electronics. However, morphological control either relies on additional fabrication steps or is limited to a small region where an external interaction is applied. Here, we show that different semiconductor-insulator polymer composites can be rapidly dip-coated with the film structure electrically switched between distinct morphologies during deposition guided by the meniscus formed between the stationary barrier and horizontally drawn solid substrate. Reversible and repeatable changes between the morphologies used in devices, e.g., lateral morphologies and stratified layers of semiconductors and insulators, or between phase-inverted droplet-like structures are manifested only for one polarity of the voltage applied across the meniscus as a rectangular pulse. This phenomenon points to a novel mechanism, related to voltage-induced doping and the doping-dependent solubility of the conjugated polymer, equivalent to an increased semiconductor content that controls the composite morphologies. This is effective only for the positively polarized substrate rather than the barrier, as the former entrains the nearby lower part of the coating solution that forms the final composite film. The mechanism, applied to the pristine semiconductor solution, results in an increased semiconductor deposition and 40-times higher film conductance.

Published

2022

2. Electrically Switchable Film Structure of Conjugated Polymer Composites

Author

Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, Budkowski, Andrzej, Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, and Budkowski, Andrzej

Abstract

Domains rich in different blend components phase-separate during deposition, creating a film morphology that determines the performance of active layers in organic electronics. However, morphological control either relies on additional fabrication steps or is limited to a small region where an external interaction is applied. Here, we show that different semiconductor-insulator polymer composites can be rapidly dip-coated with the film structure electrically switched between distinct morphologies during deposition guided by the meniscus formed between the stationary barrier and horizontally drawn solid substrate. Reversible and repeatable changes between the morphologies used in devices, e.g., lateral morphologies and stratified layers of semiconductors and insulators, or between phase-inverted droplet-like structures are manifested only for one polarity of the voltage applied across the meniscus as a rectangular pulse. This phenomenon points to a novel mechanism, related to voltage-induced doping and the doping-dependent solubility of the conjugated polymer, equivalent to an increased semiconductor content that controls the composite morphologies. This is effective only for the positively polarized substrate rather than the barrier, as the former entrains the nearby lower part of the coating solution that forms the final composite film. The mechanism, applied to the pristine semiconductor solution, results in an increased semiconductor deposition and 40-times higher film conductance.

Published

2022

3. Electrically Switchable Film Structure of Conjugated Polymer Composites

Author

Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, Budkowski, Andrzej, Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, and Budkowski, Andrzej

Abstract

Domains rich in different blend components phase-separate during deposition, creating a film morphology that determines the performance of active layers in organic electronics. However, morphological control either relies on additional fabrication steps or is limited to a small region where an external interaction is applied. Here, we show that different semiconductor-insulator polymer composites can be rapidly dip-coated with the film structure electrically switched between distinct morphologies during deposition guided by the meniscus formed between the stationary barrier and horizontally drawn solid substrate. Reversible and repeatable changes between the morphologies used in devices, e.g., lateral morphologies and stratified layers of semiconductors and insulators, or between phase-inverted droplet-like structures are manifested only for one polarity of the voltage applied across the meniscus as a rectangular pulse. This phenomenon points to a novel mechanism, related to voltage-induced doping and the doping-dependent solubility of the conjugated polymer, equivalent to an increased semiconductor content that controls the composite morphologies. This is effective only for the positively polarized substrate rather than the barrier, as the former entrains the nearby lower part of the coating solution that forms the final composite film. The mechanism, applied to the pristine semiconductor solution, results in an increased semiconductor deposition and 40-times higher film conductance.

Published

2022

4. Electrically Switchable Film Structure of Conjugated Polymer Composites

Author

Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, Budkowski, Andrzej, Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, and Budkowski, Andrzej

Abstract

Domains rich in different blend components phase-separate during deposition, creating a film morphology that determines the performance of active layers in organic electronics. However, morphological control either relies on additional fabrication steps or is limited to a small region where an external interaction is applied. Here, we show that different semiconductor-insulator polymer composites can be rapidly dip-coated with the film structure electrically switched between distinct morphologies during deposition guided by the meniscus formed between the stationary barrier and horizontally drawn solid substrate. Reversible and repeatable changes between the morphologies used in devices, e.g., lateral morphologies and stratified layers of semiconductors and insulators, or between phase-inverted droplet-like structures are manifested only for one polarity of the voltage applied across the meniscus as a rectangular pulse. This phenomenon points to a novel mechanism, related to voltage-induced doping and the doping-dependent solubility of the conjugated polymer, equivalent to an increased semiconductor content that controls the composite morphologies. This is effective only for the positively polarized substrate rather than the barrier, as the former entrains the nearby lower part of the coating solution that forms the final composite film. The mechanism, applied to the pristine semiconductor solution, results in an increased semiconductor deposition and 40-times higher film conductance.

Published

2022

5. Electrically Switchable Film Structure of Conjugated Polymer Composites

Author

Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, Budkowski, Andrzej, Awsiuk, Kamil, Dabczynski, Pawel, Marzec, Mateusz M., Rysz, Jakub, Moons, Ellen, and Budkowski, Andrzej

Abstract

Domains rich in different blend components phase-separate during deposition, creating a film morphology that determines the performance of active layers in organic electronics. However, morphological control either relies on additional fabrication steps or is limited to a small region where an external interaction is applied. Here, we show that different semiconductor-insulator polymer composites can be rapidly dip-coated with the film structure electrically switched between distinct morphologies during deposition guided by the meniscus formed between the stationary barrier and horizontally drawn solid substrate. Reversible and repeatable changes between the morphologies used in devices, e.g., lateral morphologies and stratified layers of semiconductors and insulators, or between phase-inverted droplet-like structures are manifested only for one polarity of the voltage applied across the meniscus as a rectangular pulse. This phenomenon points to a novel mechanism, related to voltage-induced doping and the doping-dependent solubility of the conjugated polymer, equivalent to an increased semiconductor content that controls the composite morphologies. This is effective only for the positively polarized substrate rather than the barrier, as the former entrains the nearby lower part of the coating solution that forms the final composite film. The mechanism, applied to the pristine semiconductor solution, results in an increased semiconductor deposition and 40-times higher film conductance.

Published

2022

6. Polymer Blends Spin-Cast into Films with Complementary Elements for Electronics and Biotechnology

Author

Budkowski, Andrzej, Zemla, Joanna, Moons, Ellen, Awsiuk, Kamil, Rysz, Jakub, Bernasik, Andrzej, Björström Svanström, Cecilia M., Lekka, Małgorzata, Jaczewska, Justyna, Budkowski, Andrzej, Zemla, Joanna, Moons, Ellen, Awsiuk, Kamil, Rysz, Jakub, Bernasik, Andrzej, Björström Svanström, Cecilia M., Lekka, Małgorzata, and Jaczewska, Justyna

Abstract

Versatility of solution-processing strategy based on the simultaneous rather than additive deposition of different functional molecules is discussed. It is shown that spin-cast polymer blends result in films with domains that could form elements with complementary functions of (i) solar cells, (ii) electronic circuitries, and (iii) test plates for protein micro-arrays: Alternating layers, rich in electrondonating polyfluorene and electron-accepting fullerene derivative, result in optimized solar power conversion. Surface patterns, made by soft lithography, align conductive paths of conjugated poly(3-alkylthiophene) in dielectric polystyrene. Proteins, preserving their biologically activity, are adsorbed to hydrophobic domains of polystyrene in hydrophilic matrix of poly(ethylene oxide). The authors report the research progress on structure formation in three polymer blend families, resulting in films with complementary elements for electronics and biotechnology. Blend film structures are determined with secondary ion mass spectrometry, atomic force microscopy, and fluorescence microscopy. In addition, the authors present recent results on (i) structure formation in fullerene derivative/poly(3-alkylthiophene) blends intended for solar cells, (ii) 3-dimensional SIMS imaging of conductive paths of poly(3-alkylthiophene) in dielectric polystyrene, (iii) test lates for multiprotein micro-arrays fabricated with blend films of hydrophobic polystyrene and thermoresponsive poly (N-sopropylacrylamide).

Published

2012