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New Supramolecular Scaffold Could Advance 2D Molecular Assemblies

This new method opens doors for advancements in materials science, such as creating better solar cells

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Research in the field of material science and electronics relies on the innovative arrangement of molecules or atoms to develop materials with unique properties not found in conventional materials. Two-dimensional (2D) assemblies of π-electronic systems, arranged in thin layers, are becoming increasingly important in the fields of materials science and organic electronics. Their unique arrangement allows for specific electronic and physical properties, making them ideal for applications like solar cells, and flexible displays. However, creating such assemblies is challenging because it often requires special designs and techniques for each type of molecule.

In a study published in Science Advances, on 13 September 2024, Assistant Professor Tomoya Fukui and Professor Takanori Fukushima from Institute of Science Tokyo, in collaboration with Professor Taku Hasobe from Keio University, present a streamlined approach using supramolecular scaffolds. These scaffolds serve as molecular templates, allowing for the assembly of various molecules into 2D structures without requiring custom setups for each component.

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The researchers used 1,8,13-substituted tripodal triptycene as a supramolecular scaffold. Tripodal triptycene-based supramolecular scaffold can assemble into a 2D hexagonal pattern that can be stacked along one dimension, creating a “2D + 1D” structure. The space between these layers can accommodate other molecules. In their earlier work, the team incorporated spherical fullerene (C60) molecules within these layers. In their latest study, they demonstrated that this scaffold could also organize planar acene chromophores by sandwiching pentacene and anthracene chromophores between two triptycene units, forming two distinct 2D self-assembling structures.

Acenes were selected due to their potential for singlet fission (SF). In this process, a single high-energy photon is converted into two lower-energy triplet excitons, which is expected to enhance solar cell efficiency by increasing charge carriers. Dr. Fukui notes that for efficient singlet fission in the solid state, two conditions must be met: “Acene chromophores need to be placed in close proximity to each other to provide sufficient electronic coupling. Second, the environment around the chromophores needs to be designed to allow them to undergo conformational changes to prevent triplet recombination.”

In the pentacene-based assemblies, the effective overlap of chromophores enabled singlet fission to occur, with a high quantum yield of 88% for generating a pair of triplets and 130% for producing two free triplets. However, the anthracene-based assemblies did not exhibit singlet fission, likely due to weaker electronic coupling between the chromophores.
“Pentacene chromophores, which have a size larger than that of the diameter of the triptycene framework, have effective overlap to cause SF, while such an overlap between the chromophores does not occur in the assembly of anthracene analog,” explains Prof. Fukushima.

Such assemblies can be integrated into comb-shaped electrodes, potentially paving to the way for device applications. “This demonstrates the utility of the triptycene-based supramolecular scaffold to design functional pi-electronic molecular assemblies,” says Prof. Hasobe. The scaffold's adaptable design offers a versatile platform for constructing 2D assemblies with different molecules, paving the way for advancements in supramolecular chemistry, materials science, and organic electronics.

-Note: This news release was originally published by the Institute of Science Tokyo. As it has been republished, it may deviate from our style guide.

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