Your search keyword '"Karl-Augustin Zaininger"' showing total 6 results

1. Open-circuit and short-circuit loss management in wide-gap perovskite p-i-n solar cells

Author

Pietro Caprioglio, Joel A. Smith, Robert D. J. Oliver, Akash Dasgupta, Saqlain Choudhary, Michael D. Farrar, Alexandra J. Ramadan, Yen-Hung Lin, M. Greyson Christoforo, James M. Ball, Jonas Diekmann, Jarla Thiesbrummel, Karl-Augustin Zaininger, Xinyi Shen, Michael B. Johnston, Dieter Neher, Martin Stolterfoht, and Henry J. Snaith

Subjects

Science

Abstract

A mismatch between quasi-Fermi level splitting and open-circuit voltage is detrimental to wide bandgap perovskite pin solar cells. Here, through theoretical and experimental approaches, the authors optimize n- and p-type interfaces to achieve open-circuit voltage of 1.29 V and T80 of 3500 h at 85 °C.

Published

2023

2. Reducing Nonradiative Losses in Perovskite LEDs through Atomic Layer Deposition of Al2O3 on the Hole-Injection Contact

Author

Emil G. Dyrvik, Jonathan H. Warby, Melissa M. McCarthy, Alexandra J. Ramadan, Karl-Augustin Zaininger, Andreas E. Lauritzen, Suhas Mahesh, Robert A. Taylor, and Henry J. Snaith

Subjects

General Engineering, General Physics and Astronomy, General Materials Science

Abstract

Halide perovskite light-emitting diodes (PeLEDs) exhibit great potential for use in next-generation display technologies. However, scale-up will be challenging due to the requirement of very thin transport layers for high efficiencies, which often present spatial inhomogeneities from improper wetting and drying during solution processing. Here, we show how a thin Al2O3 layer grown by atomic layer deposition can be used to preferentially cover regions of imperfect hole transport layer deposition and form an intermixed composite with the organic transport layer, allowing hole conduction and injection to persist through the organic hole transporter. This has the dual effect of reducing nonradiative recombination at the heterojunction and improving carrier selectivity, which we infer to be due to the inhibition of direct contact between the indium tin oxide and perovskite layers. We observe an immediate improvement in electroluminescent external quantum efficiency in our p-i-n LEDs from an average of 9.8% to 13.5%, with a champion efficiency of 15.0%. The technique uses industrially available equipment and can readily be scaled up to larger areas and incorporated in other applications such as thin-film photovoltaic cells.

Published

2023

3. Visualizing macroscopic inhomogeneities in perovskite solar cells

Author

Akash Dasgupta, Suhas Mahesh, Pietro Caprioglio, Yen-Hung Lin, Karl-Augustin Zaininger, Robert D.J. Oliver, Philippe Holzhey, Suer Zhou, Melissa M. McCarthy, Joel A. Smith, Maximilian Frenzel, M. Greyson Christoforo, James M. Ball, Bernard Wenger, and Henry J. Snaith

Subjects

Fuel Technology, Renewable Energy, Sustainability and the Environment, Chemistry (miscellaneous), Materials Chemistry, Energy Engineering and Power Technology

Abstract

Despite the incredible progress made, the highest efficiency perovskite solar cells are still restricted to small areas (

Published

2022

4. Pump-Profile Engineering for Spatial- and Spectral-Mode Control in Two-Dimensional Colloidal-Quantum-Dot Spasers

Author

David J. Norris, Ario Cocina, Jian Cui, Boris le Feber, Karl-Augustin Zaininger, Stephan J. P. Kress, and Robert C. Keitel

Subjects

Physics, Colloid, Active laser medium, Quantum dot, business.industry, Surface plasmon, Physics::Optics, Optoelectronics, Spaser, business, Plasmon, Nanomaterials, Compensation (engineering)

Abstract

In the initial proposal of the spaser – a source of coherent, intense, and narrow-band surface plasmons – colloidal quantum dots were envisioned as an ideal gain medium for compensation of the significant losses intrinsic to plasmonics. However, many spasers shown to date have required a single material to both serve as a gain medium and define the plasmonic cavity, a design that prevents the use of quantum dots or other colloidal nanomaterials. In addition, these concepts are inherently challenging for integration in a larger plasmonic circuit.

Published

2018

5. A customizable class of colloidal-quantum-dot metallic lasers and amplifiers

Author

Kevin M. McPeak, Dimos Poulikakos, Patrizia Richner, Jian Cui, Felipe V. Antolinez, Sriharsha V. Jayanti, Patrik Rohner, Karl Augustin Zaininger, David J. Norris, Stephan J. P. Kress, and David Kim

Subjects

Electromagnetic field, Physics, Multidisciplinary, Active laser medium, business.industry, Amplifier, Physics::Optics, 02 engineering and technology, 021001 nanoscience & nanotechnology, Laser, 01 natural sciences, 7. Clean energy, law.invention, 010309 optics, Photoexcitation, Laser linewidth, law, Quantum dot, 0103 physical sciences, Optoelectronics, 0210 nano-technology, business, Plasmon

Abstract

Colloidal quantum dots are robust, efficient, and tunable emitters now used in lighting, displays, and lasers. Consequently, when the spaser—a laser-like source of high-intensity, narrow-band surface plasmons—was first proposed, quantum dots were specified as the ideal plasmonic gain medium for overcoming the significant intrinsic losses of plasmons. Many subsequent spasers, however, have required a single material to simultaneously provide gain and define the plasmonic cavity, a design unable to accommodate quantum dots and other colloidal nanomaterials. In addition, these and other designs have been ill suited for integration with other elements in a larger plasmonic circuit, limiting their use. We develop a more open architecture that decouples the gain medium from the cavity, leading to a versatile class of quantum dot–based metallic lasers that allow controlled generation, extraction, and manipulation of electromagnetic waves. We first create aberration-corrected plasmonic cavities with high quality factors at desired locations on an ultrasmooth silver substrate. We then incorporate quantum dots into these cavities via electrohydrodynamic printing or drop-casting. Photoexcitation under ambient conditions generates monochromatic light (0.65-nm linewidth at 630 nm, Q ~ 1000) above threshold. This signal is extracted, directed through an integrated amplifier, and focused at a nearby nanoscale tip, generating intense electromagnetic fields. More generally, our device platform can be straightforwardly deployed at different wavelengths, size scales, and geometries on large-area chips for fundamental studies and applications.

Published

2017

6. A customizable class of colloidal-quantum-dot spasers and plasmonic amplifiers

Author

Stephan J P, Kress, Jian, Cui, Patrik, Rohner, David K, Kim, Felipe V, Antolinez, Karl-Augustin, Zaininger, Sriharsha V, Jayanti, Patrizia, Richner, Kevin M, McPeak, Dimos, Poulikakos, and David J, Norris

Abstract

Colloidal quantum dots are robust, efficient, and tunable emitters now used in lighting, displays, and lasers. Consequently, when the spaser-a laser-like source of high-intensity, narrow-band surface plasmons-was first proposed, quantum dots were specified as the ideal plasmonic gain medium for overcoming the significant intrinsic losses of plasmons. Many subsequent spasers, however, have required a single material to simultaneously provide gain and define the plasmonic cavity, a design unable to accommodate quantum dots and other colloidal nanomaterials. In addition, these and other designs have been ill suited for integration with other elements in a larger plasmonic circuit, limiting their use. We develop a more open architecture that decouples the gain medium from the cavity, leading to a versatile class of quantum dot-based spasers that allow controlled generation, extraction, and manipulation of plasmons. We first create aberration-corrected plasmonic cavities with high quality factors at desired locations on an ultrasmooth silver substrate. We then incorporate quantum dots into these cavities via electrohydrodynamic printing or drop-casting. Photoexcitation under ambient conditions generates monochromatic plasmons (0.65-nm linewidth at 630 nm

Published

2017