Dendrimers finally have what it takes to break into the laser scene

Dendrimers finally have what it takes to break into the laser scene
Molecular structure of carbon-bridged phenylenevinylene-carbazole dendrimers (GnCOPV2, n = 1, 2, 3), fluorescent microscopy images of the maicrometer-scale single crystals, and laser oscillation spectra. Credit: University of Tsukuba

Advances in optical devices are supported by the development of new materials. Microcrystallites of luminescent organic compounds can act as tiny laser sources for such devices, for example, in displays and other components. Dendrimers offer numerous advantages as luminescent materials, but so far, they have not been used as microcrystallites owing to their fragility and poor crystallinity. Now, a team of researchers has produced dendrimers that form robust crystals with lasing properties. Their findings are published in Angewandte Chemie.

Dendrimers are polymers that grow out from a core through the addition of small molecules to form extended branches, which explains their name, derived from the Greek word for tree. Dendrimers have many advantages that make them interesting luminescent materials. They are highly soluble, which makes them easy to incorporate into systems; they have high quantum yields, meaning you get a lot of the light you put in back again; they are good at harvesting light, and they tend to show relatively low luminescence loss when condensed into a solid.

The researchers made a family of dendrimers—getting larger in size as the generation number increased—made up of carbazole units forming the branches around a highly fluorescent core. The dendrimers formed stable single crystals even when the solvent was removed, and could be analyzed by single-crystal X-ray analysis. In fact, the third generation , which has a of 4,600 Da, is the largest organic dendrimer ever to have been analyzed in this way.

"Our dendrimers have two key parts," study corresponding author Professor Yohei Yamamoto explains. "The branches are made up of aromatic molecules that act as light-harvesting antennas, collecting light made up of waves in many different planes, which is known as non-polarized light. This light is then transferred to the fluorescent core, whose structure leads to polarized light— with waves in a single plane—being generated."

When the dendrimer crystals were subjected to strong optical pumping, the process used to amplify the signal in laser materials, they produced amplified and lasing with little damage to the structure of the material or the optical properties.

"The family of dendrimers we produced remedies a number of issues that have prevented the properties of these materials from being exploited. We therefore expect them to make a significant contribution to the development of organic materials for laser optics," says Professor Yamamoto. "The robust properties and laser emission of the crystals will be useful for components such as full-color optical displays and micro-optical circuits."


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More information: Kohei Iwai et al, Single‐crystalline Optical Microcavities from Luminescent Dendrimers, Angewandte Chemie International Edition (2020). DOI: 10.1002/anie.202000712
Citation: Dendrimers finally have what it takes to break into the laser scene (2020, May 8) retrieved 30 November 2020 from https://phys.org/news/2020-05-dendrimers-laser-scene.html
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