Oct 19, 2023 |
(Nanowerk News) Organic semiconductors, which usually consist of carbon-based molecular materials or polymers, are part of a variety of today’s applications: For example, ultra-thin, mechanically flexible and lightweight semiconductor thin films are used in modern transistors, sensitive sensors, or organic solar cells. Their energy conversion potential and thus their functionality is determined by the electronic energy levels of the organic thin films, which depend on the molecules as well as their arrangement and the interactions between neighboring molecules within the thin films.
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Key Takeaways
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Researchers at the Leibniz Institute of Photonic Technology have developed a novel technique for the automated, precise production of organic semiconductor thin films.
The “Rolling Transferred Langmuir Layer” technique improves upon existing methods, allowing for monolayer films with controlled molecular arrangement and specific electronic properties.
This breakthrough enables the production of organic semiconductor films with fewer surface defects and increased quality.
The method allows for control over two key variables: molecular packing density and the number of stacked molecular layers.
The new technology has applications in optoelectronics, including organic solar cells and sensors, paving the way for components with optimized energy conversion and functionality.
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Based on the new ‘Rolling Transfered Langmuir Layer’ technology, which can be used to produce thin films with specific properties, improved flexible solar cells can be produced, for example. (Image: Leibniz Institute of Photonic Technology)
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The Research
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A German-American team of scientists – led by Leibniz Institute of Photonic Technology (Leibniz IPHT) – has succeeded in developing a novel manufacturing process that allows to precisely fabricate thin semiconductor films with customized structural and electronic properties in an automated manner.
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The method presented in the journal Advanced Materials (“Tailoring the weight of surface and intralayer edge states to control LUMO energies”) should make it possible to specifically produce thin films with controllable interactions between neighboring molecules and specific energy levels.
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Rolling deposition of semiconductor thin films
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The presented “Rolling Transfered Langmuir Layer” technique, a further development of the established Langmuir Blodgett technique for the deposition of thin films, is suitable for the production of monolayers of organic semiconductor molecules at air-water interfaces. For this purpose, a layer of molecules formed on a water surface is transferred to a solid substrate. The molecular monolayer is deposited on the substrate using a specific rolling transfer system developed by the researchers, which contains the substrate to be coated and which is moved over the molecular film on the water surface. The molecular layer formed at the air-water interface adheres to the substrate during the rolling motion.
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“The developed process also allows crystalline films to be deposited, the production of which using established methods previously involved considerable effort and often led to surface defects, such as fractures in the organic thin films. With the process presented, we can reduce these surface defects to a minimum and produce both monolayers and multiple thin-film layers with individual properties directly, uniformly and with high quality in a scalable manner,” explains PD Dr. habil. Martin Presselt, head of the Organic Thin Films and Interfaces Group at Leibniz IPHT, who developed the new method together with his team.
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Tailor-made thin films
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Two parameters play a decisive role in the production of semiconducting thin films with tailor-made structural and energetic properties: “On the one hand, the ‘Rolling Transfered Langmuir Layer’ technique enables to systematically vary the packing density of the molecules within a layer, which can range from very densely packed to less densely packed, via the surface pressure during deposition. On the other hand, the number of stacked molecular layers and thus the layer thickness of the thin films can be precisely adjusted. In this way, semiconductor thin films with targeted interactions between neighboring molecules and specific energy levels can be reproducibly produced,” says Dr. Sarah Jasmin Finkelmeyer, scientist in the Organic Thin Films and Interfaces Group, who played a major role in developing the new method.
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The technological approach developed by the researchers lays the foundation for the fabrication of thin-film-based novel (opto-) electronic components with optimized properties. For example, organic photovoltaic modules that efficiently generate electrical energy from sunlight as well as thin films that convert sunlight into chemical energy can be further developed.
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