Your search keyword '"Wortmann, Jonas"' showing total 15 results

1. Utilizing the unique charge extraction properties of antimony tin oxide nanoparticles for efficient and stable organic photovoltaics

Author

Liu, Chao, Félix, Roberto, Forberich, Karen, Du, Xiaoyan, Heumüller, Thomas, Matt, Gebhard J, Gu, Ening, Wortmann, Jonas, Zhao, Yicheng, Cao, Yuanyuan, He, Yakun, Ying, Lei, Hauser, Alina, Oszajca, Marek F, Hartmeier, Benjamin, Rossier, Michael, Lüchinger, Norman A, Liu, Yi-Sheng, Guo, Jinghua, Nie, Kaiqi, Wilks, Regan G, Bachmann, Julien, Bär, Marcus, Li, Ning, and Brabec, Christoph J

Subjects

Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, Organic photovoltaics, Antimony doped tin oxide, Interface engineering, Doping mechanism, Metal oxide nanoparticles, Nanotechnology, Macromolecular and materials chemistry, Materials engineering

Abstract

Simultaneously enhancing device performance and longevity, as well as balancing the requirements on cost, scalability, and simplification of processing, is the goal of interface engineering of organic solar cells (OSCs). In our work, we strategically introduce antimony (Sb3+) cations into an efficient and generic n-type SnO2 nanoparticles (NPs) host during the scalable flame spray pyrolysis synthesis. Accordingly, a significant switch of conduction property from an n-type character to a p-type character is observed, with a corresponding shift in the work function (WF) from 4.01 ± 0.02 eV for pristine SnO2 NPs to 5.28 ± 0.02 eV for SnO2 NPs with 20 mol. % Sb content (ATO). Both pristine SnO2 and ATO NPs with fine-tuned optoelectronic properties exhibit remarkable charge carrier extraction properties, excellent UV resistance and photo-stability being compatible with various state-of-the-art OSCs systems. The reliable and scalable pristine SnO2 and ATO NPs processed by doctor-blading in air demand no complex post-treatment. Our work offers a simple but unique approach to accelerate the development of advanced interfacial materials, which could circumvent the major existing interfacial problems in solution-processed OSCs.

Published

2021

2. Industrial viability of single-component organic solar cells

Author

He, Yakun, Li, Ning, Heumüller, Thomas, Wortmann, Jonas, Hanisch, Benedict, Aubele, Anna, Lucas, Sebastian, Feng, Guitao, Jiang, Xudong, Li, Weiwei, Bäuerle, Peter, and Brabec, Christoph J.

Published

2022

3. Elucidating the Full Potential of OPV Materials Utilizing a High-Throughput Robot-Based Platform and Machine Learning

Author

Du, Xiaoyan, Lüer, Larry, Heumueller, Thomas, Wagner, Jerrit, Berger, Christian, Osterrieder, Tobias, Wortmann, Jonas, Langner, Stefan, Vongsaysy, Uyxing, Bertrand, Melanie, Li, Ning, Stubhan, Tobias, Hauch, Jens, and Brabec, Christoph J.

Published

2021

4. Photodegradation of Organic Solar Cells under Visible Light and the Crucial Influence of Its Spectral Composition.

Author

Weitz, Paul, Wortmann, Jonas, Liu, Chao, Wen, Tian-Jiao, Li, Chang-Zhi, Heumüller, Thomas, and Brabec, Christoph J.

Published

2024

5. The role of exciton lifetime for charge generation in organic solar cells at negligible energy-level offsets

Author

Classen, Andrej, Chochos, Christos L., Lüer, Larry, Gregoriou, Vasilis G., Wortmann, Jonas, Osvet, Andres, Forberich, Karen, McCulloch, Iain, Heumüller, Thomas, and Brabec, Christoph J.

Published

2020

6. Understanding Causalities in Organic Photovoltaics Device Degradation in a Machine‐Learning‐Driven High‐Throughput Platform.

Author

Liu, Chao, Lüer, Larry, Corre, Vincent M. Le, Forberich, Karen, Weitz, Paul, Heumüller, Thomas, Du, Xiaoyan, Wortmann, Jonas, Zhang, Jiyun, Wagner, Jerrit, Ying, Lei, Hauch, Jens, Li, Ning, and Brabec, Christoph J.

Published

2024

7. Cross material prediction linking spectral features to efficiency parameters using gaussian process regression

Author

Wortmann, Jonas, primary, Luerr, Dr. Larry, additional, Osterrieder, Tobias, additional, Hauch, Dr. Jens, additional, Heumüller, Dr. Thomas, additional, Brabec, Prof. Dr. Christoph, additional, Liu, Dr. Chao, additional, and Le Corre, Dr. Vincent M., additional

Published

2023

8. Understanding Causalities in Organic Photovoltaics Device Degradation in a Machine‐Learning‐Driven High‐Throughput Platform

Author

Liu, Chao, primary, Lüer, Larry, additional, Corre, Vincent M. Le, additional, Forberich, Karen, additional, Weitz, Paul, additional, Heumüller, Thomas, additional, Du, Xiaoyan, additional, Wortmann, Jonas, additional, Zhang, Jiyun, additional, Wagner, Jerrit, additional, Ying, Lei, additional, Hauch, Jens, additional, Li, Ning, additional, and Brabec, Christoph J., additional

Published

2023

9. Analyzing industrial figure of merit for single-component organic solar cells

Author

He, Yakun, primary, Brabec, Christoph, additional, Heumüller, Thomas, additional, Wortmann, Jonas, additional, Hanisch, Benedict, additional, Aubele, Anna, additional, Li, Ning, additional, Feng, Guitao, additional, Jiang, Xudong, additional, Li, Weiwei, additional, Bäuerle, Peter, additional, and Lucas, Sebastian, additional

Published

2022

10. Suppressing Nonradiative Recombination in Lead–Tin Perovskite Solar Cells through Bulk and Surface Passivation to Reduce Open Circuit Voltage Losses

Author

Zhang, Kaicheng, primary, Späth, Andreas, additional, Almora, Osbel, additional, Le Corre, Vincent M., additional, Wortmann, Jonas, additional, Zhang, Jiyun, additional, Xie, Zhiqiang, additional, Barabash, Anastasia, additional, Hammer, Maria S., additional, Heumüller, Thomas, additional, Min, Jie, additional, Fink, Rainer, additional, Lüer, Larry, additional, Li, Ning, additional, and Brabec, Christoph J., additional

Published

2022

11. Ultrastable single-component organic solar cells: the next frontier towards industrial viability

Author

He, Yakun, primary, Brabec, Christoph, additional, Heumüller, Thomas, additional, Wortmann, Jonas, additional, Hanisch, Benedict, additional, Aubele, Anna, additional, Li, Ning, additional, Feng, Guitao, additional, Jiang, Xudong, additional, Li, Weiwei, additional, Bäuerle, Peter, additional, and Lucas, Sebastian, additional

Published

2022

12. Utilizing the unique charge extraction properties of antimony tin oxide nanoparticles for efficient and stable organic photovoltaics

Author

Liu, Chao, primary, Félix, Roberto, additional, Forberich, Karen, additional, Du, Xiaoyan, additional, Heumüller, Thomas, additional, Matt, Gebhard J., additional, Gu, Ening, additional, Wortmann, Jonas, additional, Zhao, Yicheng, additional, Cao, Yuanyuan, additional, He, Yakun, additional, Ying, Lei, additional, Hauser, Alina, additional, Oszajca, Marek F., additional, Hartmeier, Benjamin, additional, Rossier, Michael, additional, Lüchinger, Norman A., additional, Liu, Yi-Sheng, additional, Guo, Jinghua, additional, Nie, Kaiqi, additional, Wilks, Regan G., additional, Bachmann, Julien, additional, Bär, Marcus, additional, Li, Ning, additional, and Brabec, Christoph J., additional

Published

2021

13. Magnetic Refrigeration with Recycled Permanent Magnets and Free Rare-Earth Magnetocaloric La–Fe–Si

Author

Benke, Dimitri, Fries, Maximilian, Specht, Marius, Wortmann, Jonas, Pabst, Marc, Gottschall, Tino, Radulov, Iliya, Skokov, Konstantin, Bevan, Alex Ivor, Prosperi, Davide, Tudor, Catalina, Afiuny, Peter, Zakotnik, Miha, Gutfleisch, Oliver, Benke, Dimitri, Fries, Maximilian, Specht, Marius, Wortmann, Jonas, Pabst, Marc, Gottschall, Tino, Radulov, Iliya, Skokov, Konstantin, Bevan, Alex Ivor, Prosperi, Davide, Tudor, Catalina, Afiuny, Peter, Zakotnik, Miha, and Gutfleisch, Oliver

Abstract

Magnetic refrigeration is an upcoming technology that could be an alternative to the more than 100-year-old conventional gas–vapor compression cooling. Magnetic refrigeration might answer some of the global challenges linked with the increasing demands for readily available cooling in almost every region of the world and the global-warming potential of conventional refrigerants. Important issues to be solved are, for example, the required mass and the ecological footprint of the rare-earth permanent magnets and the magnetocaloric material, which are key parts of the magnetic cooling device. The majority of existing demonstrators use Nd–Fe–B permanent magnets, which account for more than 50% of the ecological footprint, and Gd, which is a critical raw material. This work shows a solution to these problems by demonstrating the world’s first magnetocaloric demonstrator that uses recycled Nd–Fe–B magnets as the magnetic field source, and, as a Gd replacement material, La–Fe–Mn–Si for the magnetocaloric heat exchanger. These solutions show that it is possible to reduce the ecological footprint of magnetic cooling devices and provides magnetic cooling as a green solid-state technology that has the potential to satisfy the rapidly growing global demands.

Published

2020

14. Magnetic Refrigeration with Recycled Permanent Magnets and Free Rare‐Earth Magnetocaloric La–Fe–Si

Author

Benke, Dimitri, primary, Fries, Maximilian, additional, Specht, Marius, additional, Wortmann, Jonas, additional, Pabst, Marc, additional, Gottschall, Tino, additional, Radulov, Iliya, additional, Skokov, Konstantin, additional, Bevan, Alex Ivor, additional, Prosperi, Davide, additional, Tudor, Catalina Oana, additional, Afiuny, Peter, additional, Zakotnik, Miha, additional, and Gutfleisch, Oliver, additional

Published

2020

15. Magnetic Refrigeration with Recycled Permanent Magnets and Free Rare-Earth Magnetocaloric La–Fe–Si

Author

Benke, Dimitri, Fries, Maximilian, Specht, Marius, Wortmann, Jonas, Pabst, Marc, Gottschall, Tino, Radulov, Iliya, Skokov, Konstantin, Bevan, Alex Ivor, Prosperi, Davide, Tudor, Catalina, Afiuny, Peter, Zakotnik, Miha, and Gutfleisch, Oliver

Subjects

13. Climate action, 7. Clean energy

Abstract

Magnetic refrigeration is an upcoming technology that could be an alternative to the more than 100-year-old conventional gas–vapor compression cooling. Magnetic refrigeration might answer some of the global challenges linked with the increasing demands for readily available cooling in almost every region of the world and the global-warming potential of conventional refrigerants. Important issues to be solved are, for example, the required mass and the ecological footprint of the rare-earth permanent magnets and the magnetocaloric material, which are key parts of the magnetic cooling device. The majority of existing demonstrators use Nd–Fe–B permanent magnets, which account for more than 50% of the ecological footprint, and Gd, which is a critical raw material. This work shows a solution to these problems by demonstrating the world’s first magnetocaloric demonstrator that uses recycled Nd–Fe–B magnets as the magnetic field source, and, as a Gd replacement material, La–Fe–Mn–Si for the magnetocaloric heat exchanger. These solutions show that it is possible to reduce the ecological footprint of magnetic cooling devices and provides magnetic cooling as a green solid-state technology that has the potential to satisfy the rapidly growing global demands.