A Large Starphene Comprising Pentacene Branches

Starphenes are attractive compounds due to their characteristic physicochemical properties that are inherited from acenes, making them interesting compounds for organic electronics and optics. However, the instability and low solubility of larger starphene homologs make their synthesis extremely cha...

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Veröffentlicht in:	Angewandte Chemie 2021-03, Vol.133 (14), p.7831-7837
Hauptverfasser:	Holec, Jan, Cogliati, Beatrice, Lawrence, James, Berdonces‐Layunta, Alejandro, Herrero, Pablo, Nagata, Yuuya, Banasiewicz, Marzena, Kozankiewicz, Boleslaw, Corso, Martina, Oteyza, Dimas G., Jancarik, Andrej, Gourdon, Andre
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Sprache:	eng
Schlagworte:	acenes Analytical methods Carbonyl compounds Carbonyls Chemistry decarbonylation Homology HOMO–LUMO gap NMR NMR spectroscopy Nuclear magnetic resonance Optics Physicochemical properties solid-state synthesis Starphene Synthesis
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creator	Holec, Jan Cogliati, Beatrice Lawrence, James Berdonces‐Layunta, Alejandro Herrero, Pablo Nagata, Yuuya Banasiewicz, Marzena Kozankiewicz, Boleslaw Corso, Martina Oteyza, Dimas G. Jancarik, Andrej Gourdon, Andre
description	Starphenes are attractive compounds due to their characteristic physicochemical properties that are inherited from acenes, making them interesting compounds for organic electronics and optics. However, the instability and low solubility of larger starphene homologs make their synthesis extremely challenging. Herein, we present a new strategy leading to pristine [16]starphene in preparative scale. Our approach is based on a synthesis of a carbonyl‐protected starphene precursor that is thermally converted in a solid‐state form to the neat [16]starphene, which is then characterised with a variety of analytical methods, such as 13C CP‐MAS NMR, TGA, MS MALDI, UV/Vis and FTIR spectroscopy. Furthermore, high‐resolution STM experiments unambiguously confirm its expected structure and reveal a moderate electronic delocalisation between the pentacene arms. Nucleus‐independent chemical shifts NICS(1) are also calculated to survey its aromatic character. Starphenes show promising optoelectronic properties. Notably, HOMO–LUMO energy gap presumably decreases with their increasing size, making larger homologues extremely desirable. Unfortunately, with the size, their instability and insolubility also increase, challenging classical synthetic ways. A new method has been developed, enabling synthesis of large starphenes in a quantity sufficient for their full characterisation and further applications.
doi_str_mv	10.1002/ange.202016163
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However, the instability and low solubility of larger starphene homologs make their synthesis extremely challenging. Herein, we present a new strategy leading to pristine [16]starphene in preparative scale. Our approach is based on a synthesis of a carbonyl‐protected starphene precursor that is thermally converted in a solid‐state form to the neat [16]starphene, which is then characterised with a variety of analytical methods, such as 13C CP‐MAS NMR, TGA, MS MALDI, UV/Vis and FTIR spectroscopy. Furthermore, high‐resolution STM experiments unambiguously confirm its expected structure and reveal a moderate electronic delocalisation between the pentacene arms. Nucleus‐independent chemical shifts NICS(1) are also calculated to survey its aromatic character. Starphenes show promising optoelectronic properties. Notably, HOMO–LUMO energy gap presumably decreases with their increasing size, making larger homologues extremely desirable. 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However, the instability and low solubility of larger starphene homologs make their synthesis extremely challenging. Herein, we present a new strategy leading to pristine [16]starphene in preparative scale. Our approach is based on a synthesis of a carbonyl‐protected starphene precursor that is thermally converted in a solid‐state form to the neat [16]starphene, which is then characterised with a variety of analytical methods, such as 13C CP‐MAS NMR, TGA, MS MALDI, UV/Vis and FTIR spectroscopy. Furthermore, high‐resolution STM experiments unambiguously confirm its expected structure and reveal a moderate electronic delocalisation between the pentacene arms. Nucleus‐independent chemical shifts NICS(1) are also calculated to survey its aromatic character. Starphenes show promising optoelectronic properties. Notably, HOMO–LUMO energy gap presumably decreases with their increasing size, making larger homologues extremely desirable. 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subjects	acenes Analytical methods Carbonyl compounds Carbonyls Chemistry decarbonylation Homology HOMO–LUMO gap NMR NMR spectroscopy Nuclear magnetic resonance Optics Physicochemical properties solid-state synthesis Starphene Synthesis
title	A Large Starphene Comprising Pentacene Branches
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