Easier to Twist than Bend: The Scope of the Bridge Formation Approach to Naphthalenophane Synthesis

Anjan Bedi; Linda J.W. Shimon; Benny Bogoslavsky; Ori Gidron

doi:10.1055/s-0040-1721102

Easier to Twist than Bend: The Scope of the Bridge Formation Approach to Naphthalenophane Synthesis

Anjan Bedi, Linda J.W. Shimon, Benny Bogoslavsky, Ori Gidron

The Hebrew University of Jerusalem, Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

Twisting anthracene and higher acenes can alter their optical, magnetic, and electronic properties. To test the effect of twisting on the lower homologue, naphthalene, we synthesized tethered naphthalenophanes bearing alkyl bridges. Both X-ray structure and DFT calculations show that hexyl and butyl bridges induce a 6° and 12° end-to-end twist on the naphthalene unit, respectively. Attempts to increase the twisting further using shorter tethers resulted in an elimination product. Enantiomerically pure naphthalenophanes display strong chiroptical properties, which intensify with increasing twist. Attempts to induce bending, rather than twisting, using the same synthetic methodology, resulted in intermolecular dimerization, yielding macrocyclic naphthalenes. This work highlights the importance of steric hindrance in the synthesis of curved cyclophanes using the bridge formation approach.

Original language	English
Pages (from-to)	323-329
Number of pages	7
Journal	Organic Materials
Volume	2
Issue number	4
DOIs	https://doi.org/10.1055/s-0040-1721102
State	Published - 8 Sep 2020

Keywords

acenes
chirality
curved aromatic molecules
cyclophanes

All Science Journal Classification (ASJC) codes

Organic Chemistry

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10.1055/s-0040-1721102

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abstract = "Twisting anthracene and higher acenes can alter their optical, magnetic, and electronic properties. To test the effect of twisting on the lower homologue, naphthalene, we synthesized tethered naphthalenophanes bearing alkyl bridges. Both X-ray structure and DFT calculations show that hexyl and butyl bridges induce a 6° and 12° end-to-end twist on the naphthalene unit, respectively. Attempts to increase the twisting further using shorter tethers resulted in an elimination product. Enantiomerically pure naphthalenophanes display strong chiroptical properties, which intensify with increasing twist. Attempts to induce bending, rather than twisting, using the same synthetic methodology, resulted in intermolecular dimerization, yielding macrocyclic naphthalenes. This work highlights the importance of steric hindrance in the synthesis of curved cyclophanes using the bridge formation approach.",

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T2 - The Scope of the Bridge Formation Approach to Naphthalenophane Synthesis

AU - Bedi, Anjan

AU - Shimon, Linda J.W.

AU - Bogoslavsky, Benny

AU - Gidron, Ori

PY - 2020/9/8

Y1 - 2020/9/8

N2 - Twisting anthracene and higher acenes can alter their optical, magnetic, and electronic properties. To test the effect of twisting on the lower homologue, naphthalene, we synthesized tethered naphthalenophanes bearing alkyl bridges. Both X-ray structure and DFT calculations show that hexyl and butyl bridges induce a 6° and 12° end-to-end twist on the naphthalene unit, respectively. Attempts to increase the twisting further using shorter tethers resulted in an elimination product. Enantiomerically pure naphthalenophanes display strong chiroptical properties, which intensify with increasing twist. Attempts to induce bending, rather than twisting, using the same synthetic methodology, resulted in intermolecular dimerization, yielding macrocyclic naphthalenes. This work highlights the importance of steric hindrance in the synthesis of curved cyclophanes using the bridge formation approach.

AB - Twisting anthracene and higher acenes can alter their optical, magnetic, and electronic properties. To test the effect of twisting on the lower homologue, naphthalene, we synthesized tethered naphthalenophanes bearing alkyl bridges. Both X-ray structure and DFT calculations show that hexyl and butyl bridges induce a 6° and 12° end-to-end twist on the naphthalene unit, respectively. Attempts to increase the twisting further using shorter tethers resulted in an elimination product. Enantiomerically pure naphthalenophanes display strong chiroptical properties, which intensify with increasing twist. Attempts to induce bending, rather than twisting, using the same synthetic methodology, resulted in intermolecular dimerization, yielding macrocyclic naphthalenes. This work highlights the importance of steric hindrance in the synthesis of curved cyclophanes using the bridge formation approach.

KW - acenes

KW - chirality

KW - curved aromatic molecules

KW - cyclophanes

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U2 - 10.1055/s-0040-1721102

DO - 10.1055/s-0040-1721102

M3 - مقالة

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JO - Organic Materials

JF - Organic Materials

IS - 4

ER -

Easier to Twist than Bend: The Scope of the Bridge Formation Approach to Naphthalenophane Synthesis

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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