Your search keyword '"Lindh, E"' showing total 16 results

1. Controlling the Emission Zone by Additives for Improved Light-Emitting Electrochemical Cells

Author

Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, Edman, Ludvig, Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, and Edman, Ludvig

Abstract

The position of the emission zone (EZ) in the active material of a light-emitting electrochemical cell (LEC) has a profound influence on its performance because of microcavity effects and doping- and electrode-induced quenching. Previous attempts of EZ control have focused on the two principal constituents in the active material-the organic semiconductor (OSC) and the mobile ions-but this study demonstrates that it is possible to effectively control the EZ position through the inclusion of an appropriate additive into the active material. More specifically, it is shown that a mere modification of the end group on an added neutral compound, which also functions as an ion transporter, results in a shifted EZ from close to the anode to the center of the active material, which translates into a 60% improvement of the power efficiency. This particular finding is rationalized by a lowering of the effective electron mobility of the OSC through specific additive: OSC interactions, but the more important generic conclusion is that it is possible to control the EZ position, and thereby the LEC performance, by the straightforward inclusion of an easily tuned additive in the active material.

Published

2022

2. Controlling the Emission Zone by Additives for Improved Light-Emitting Electrochemical Cells

Author

Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, Edman, Ludvig, Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, and Edman, Ludvig

Abstract

The position of the emission zone (EZ) in the active material of a light-emitting electrochemical cell (LEC) has a profound influence on its performance because of microcavity effects and doping- and electrode-induced quenching. Previous attempts of EZ control have focused on the two principal constituents in the active material-the organic semiconductor (OSC) and the mobile ions-but this study demonstrates that it is possible to effectively control the EZ position through the inclusion of an appropriate additive into the active material. More specifically, it is shown that a mere modification of the end group on an added neutral compound, which also functions as an ion transporter, results in a shifted EZ from close to the anode to the center of the active material, which translates into a 60% improvement of the power efficiency. This particular finding is rationalized by a lowering of the effective electron mobility of the OSC through specific additive: OSC interactions, but the more important generic conclusion is that it is possible to control the EZ position, and thereby the LEC performance, by the straightforward inclusion of an easily tuned additive in the active material.

Published

2022

3. Controlling the Emission Zone by Additives for Improved Light-Emitting Electrochemical Cells

Author

Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, Edman, Ludvig, Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, and Edman, Ludvig

Abstract

The position of the emission zone (EZ) in the active material of a light-emitting electrochemical cell (LEC) has a profound influence on its performance because of microcavity effects and doping- and electrode-induced quenching. Previous attempts of EZ control have focused on the two principal constituents in the active material-the organic semiconductor (OSC) and the mobile ions-but this study demonstrates that it is possible to effectively control the EZ position through the inclusion of an appropriate additive into the active material. More specifically, it is shown that a mere modification of the end group on an added neutral compound, which also functions as an ion transporter, results in a shifted EZ from close to the anode to the center of the active material, which translates into a 60% improvement of the power efficiency. This particular finding is rationalized by a lowering of the effective electron mobility of the OSC through specific additive: OSC interactions, but the more important generic conclusion is that it is possible to control the EZ position, and thereby the LEC performance, by the straightforward inclusion of an easily tuned additive in the active material.

Published

2022

4. Controlling the Emission Zone by Additives for Improved Light-Emitting Electrochemical Cells

Author

Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, Edman, Ludvig, Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, and Edman, Ludvig

Abstract

The position of the emission zone (EZ) in the active material of a light-emitting electrochemical cell (LEC) has a profound influence on its performance because of microcavity effects and doping- and electrode-induced quenching. Previous attempts of EZ control have focused on the two principal constituents in the active material-the organic semiconductor (OSC) and the mobile ions-but this study demonstrates that it is possible to effectively control the EZ position through the inclusion of an appropriate additive into the active material. More specifically, it is shown that a mere modification of the end group on an added neutral compound, which also functions as an ion transporter, results in a shifted EZ from close to the anode to the center of the active material, which translates into a 60% improvement of the power efficiency. This particular finding is rationalized by a lowering of the effective electron mobility of the OSC through specific additive: OSC interactions, but the more important generic conclusion is that it is possible to control the EZ position, and thereby the LEC performance, by the straightforward inclusion of an easily tuned additive in the active material.

Published

2022

5. Controlling the Emission Zone by Additives for Improved Light-Emitting Electrochemical Cells

Author

Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, Edman, Ludvig, Rafols-Ribe, Joan, Zhang, Xiaoying, Larsen, Christian, Lundberg, Petter, Lindh, E. Mattias, Mai, Cuc Thu, Mindemark, Jonas, Gracia-Espino, Eduardo, and Edman, Ludvig

Abstract

The position of the emission zone (EZ) in the active material of a light-emitting electrochemical cell (LEC) has a profound influence on its performance because of microcavity effects and doping- and electrode-induced quenching. Previous attempts of EZ control have focused on the two principal constituents in the active material-the organic semiconductor (OSC) and the mobile ions-but this study demonstrates that it is possible to effectively control the EZ position through the inclusion of an appropriate additive into the active material. More specifically, it is shown that a mere modification of the end group on an added neutral compound, which also functions as an ion transporter, results in a shifted EZ from close to the anode to the center of the active material, which translates into a 60% improvement of the power efficiency. This particular finding is rationalized by a lowering of the effective electron mobility of the OSC through specific additive: OSC interactions, but the more important generic conclusion is that it is possible to control the EZ position, and thereby the LEC performance, by the straightforward inclusion of an easily tuned additive in the active material.

Published

2022

6. Oligomer Electrolytes for Light-Emitting Electrochemical Cells : Influence of the End Groups on Ion Coordination, Ion Binding, and Turn-on Kinetics

Author

Gerz, Isabelle, Lindh, E. Mattias, Thordarson, Pall, Edman, Ludvig, Kullgren, Jolla, Mindemark, Jonas, Gerz, Isabelle, Lindh, E. Mattias, Thordarson, Pall, Edman, Ludvig, Kullgren, Jolla, and Mindemark, Jonas

Abstract

The electrolyte is an essential constituent of the light-emitting electrochemical cell (LEC), since its operating mechanism is dependent on the redistribution of mobile ions in the active layer. Recent developments of new ion transporters have yielded high-performance devices, but knowledge about the interactions between the ionic species and the ion transporters and the influence of these interactions on the LEC performance is lacking. We therefore present a combined computational and experimental effort that demonstrates that the selection of the end group in a star-branched oligomeric ion transporter based on trimethylolpropane ethoxylate has a paramount influence on the ionic interactions in the electrolyte and thereby also on the performance of the corresponding LECs. With hydroxyl end groups, the the salt is strongly coordinated to the ion transporter, which leads to suppression of ion pairing, but the penalty is a hindered ion release and a slow turn-on for the LEC devices. With methoxy end groups, an intermediate coordination strength is seen together with the formation of contact ion pairs, but the LEC performance is very good with fast turn-on. Using a series of ion transporters with alkyl carbonate end groups, the ion transporter:cation coordination strength is lowered further, but the turn-on kinetics are slower than what is seen for devices comprising the methoxy end-capped ion transporter.

Published

2019

7. The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

The light-emitting electrochemical cell (LEC) is functional at substantial active-layer thickness, and is as such heralded for being fit for low-cost and fault-tolerant solution-based fabrication. We report here that this statement should be moderated, and that in order to obtain a strong luminous output, it is fundamentally important to fabricate LEC devices with a designed thickness of the active layer. By systematic experimentation and simulation, we demonstrate that weak optical microcavity effects are prominent in a common LEC system, and that the luminance and efficiency, as well as the emission color and the angular intensity, vary in a periodic manner with the active-layer thickness. Importantly, we demonstrate that high-performance light-emission can be attained from LEC devices with a significant active-layer thickness of 300 nm, which implies that low-cost solution-processed LECs are indeed a realistic option, provided that the device structure has been appropriately designed from an optical perspective., Correction in: Scientific Reports https://doi.org/10.1038/s41598-018-25287-x, published online 03 May 2018. Scientific Reports, vol. 8, article number: 8697. DOI: 10.1038/s41598-018-26760-3.

Published

2018

8. Publisher Correction: The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

Correction to: Scientific Reports, vol. 8, article number: 6970.DOI: 10.1038/s41598-018-25287-x

Published

2018

9. Publisher Correction: The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

Correction to: Scientific Reports, vol. 8, article number: 6970.DOI: 10.1038/s41598-018-25287-x

Published

2018

10. The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

The light-emitting electrochemical cell (LEC) is functional at substantial active-layer thickness, and is as such heralded for being fit for low-cost and fault-tolerant solution-based fabrication. We report here that this statement should be moderated, and that in order to obtain a strong luminous output, it is fundamentally important to fabricate LEC devices with a designed thickness of the active layer. By systematic experimentation and simulation, we demonstrate that weak optical microcavity effects are prominent in a common LEC system, and that the luminance and efficiency, as well as the emission color and the angular intensity, vary in a periodic manner with the active-layer thickness. Importantly, we demonstrate that high-performance light-emission can be attained from LEC devices with a significant active-layer thickness of 300 nm, which implies that low-cost solution-processed LECs are indeed a realistic option, provided that the device structure has been appropriately designed from an optical perspective., Correction in: Scientific Reports https://doi.org/10.1038/s41598-018-25287-x, published online 03 May 2018. Scientific Reports, vol. 8, article number: 8697. DOI: 10.1038/s41598-018-26760-3.

Published

2018

11. Publisher Correction: The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

Correction to: Scientific Reports, vol. 8, article number: 6970.DOI: 10.1038/s41598-018-25287-x

Published

2018

12. The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

The light-emitting electrochemical cell (LEC) is functional at substantial active-layer thickness, and is as such heralded for being fit for low-cost and fault-tolerant solution-based fabrication. We report here that this statement should be moderated, and that in order to obtain a strong luminous output, it is fundamentally important to fabricate LEC devices with a designed thickness of the active layer. By systematic experimentation and simulation, we demonstrate that weak optical microcavity effects are prominent in a common LEC system, and that the luminance and efficiency, as well as the emission color and the angular intensity, vary in a periodic manner with the active-layer thickness. Importantly, we demonstrate that high-performance light-emission can be attained from LEC devices with a significant active-layer thickness of 300 nm, which implies that low-cost solution-processed LECs are indeed a realistic option, provided that the device structure has been appropriately designed from an optical perspective., Correction in: Scientific Reports https://doi.org/10.1038/s41598-018-25287-x, published online 03 May 2018. Scientific Reports, vol. 8, article number: 8697. DOI: 10.1038/s41598-018-26760-3.

Published

2018

13. The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

The light-emitting electrochemical cell (LEC) is functional at substantial active-layer thickness, and is as such heralded for being fit for low-cost and fault-tolerant solution-based fabrication. We report here that this statement should be moderated, and that in order to obtain a strong luminous output, it is fundamentally important to fabricate LEC devices with a designed thickness of the active layer. By systematic experimentation and simulation, we demonstrate that weak optical microcavity effects are prominent in a common LEC system, and that the luminance and efficiency, as well as the emission color and the angular intensity, vary in a periodic manner with the active-layer thickness. Importantly, we demonstrate that high-performance light-emission can be attained from LEC devices with a significant active-layer thickness of 300 nm, which implies that low-cost solution-processed LECs are indeed a realistic option, provided that the device structure has been appropriately designed from an optical perspective., Correction in: Scientific Reports https://doi.org/10.1038/s41598-018-25287-x, published online 03 May 2018. Scientific Reports, vol. 8, article number: 8697. DOI: 10.1038/s41598-018-26760-3.

Published

2018

14. Publisher Correction: The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

Correction to: Scientific Reports, vol. 8, article number: 6970.DOI: 10.1038/s41598-018-25287-x

Published

2018

15. Publisher Correction: The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

Correction to: Scientific Reports, vol. 8, article number: 6970.DOI: 10.1038/s41598-018-25287-x

Published

2018

16. The Weak Microcavity as an Enabler for Bright and Fault-tolerant Light-emitting Electrochemical Cells

Author

Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, Edman, Ludvig, Lindh, E. Mattias, Lundberg, Petter, Lanz, Thomas, Mindemark, Jonas, and Edman, Ludvig

Abstract

The light-emitting electrochemical cell (LEC) is functional at substantial active-layer thickness, and is as such heralded for being fit for low-cost and fault-tolerant solution-based fabrication. We report here that this statement should be moderated, and that in order to obtain a strong luminous output, it is fundamentally important to fabricate LEC devices with a designed thickness of the active layer. By systematic experimentation and simulation, we demonstrate that weak optical microcavity effects are prominent in a common LEC system, and that the luminance and efficiency, as well as the emission color and the angular intensity, vary in a periodic manner with the active-layer thickness. Importantly, we demonstrate that high-performance light-emission can be attained from LEC devices with a significant active-layer thickness of 300 nm, which implies that low-cost solution-processed LECs are indeed a realistic option, provided that the device structure has been appropriately designed from an optical perspective., Correction in: Scientific Reports https://doi.org/10.1038/s41598-018-25287-x, published online 03 May 2018. Scientific Reports, vol. 8, article number: 8697. DOI: 10.1038/s41598-018-26760-3.

Published

2018