Ir-Catalyzed ortho-Borylation of Phenols Directed by Substrate–Ligand Electrostatic Interactions: A Combined Experimental/in Silico Strategy for Optimizing Weak Interactions

A strategy for affecting ortho versus meta/para selectivity in Ir-catalyzed C–H borylations (CHBs) of phenols is described. From selectivity observations with ArylOBpin (pin = pinacolate), it is hypothesized that an electrostatic interaction between the partial negatively charged OBpin group and the...

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Veröffentlicht in:	Journal of the American Chemical Society 2017-06, Vol.139 (23), p.7864-7871
Hauptverfasser:	Chattopadhyay, Buddhadeb, Dannatt, Jonathan E, Andujar-De Sanctis, Ivonne L, Gore, Kristin A, Maleczka, Robert E, Singleton, Daniel A, Smith, Milton R
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container_end_page	7871
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container_title	Journal of the American Chemical Society
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creator	Chattopadhyay, Buddhadeb Dannatt, Jonathan E Andujar-De Sanctis, Ivonne L Gore, Kristin A Maleczka, Robert E Singleton, Daniel A Smith, Milton R
description	A strategy for affecting ortho versus meta/para selectivity in Ir-catalyzed C–H borylations (CHBs) of phenols is described. From selectivity observations with ArylOBpin (pin = pinacolate), it is hypothesized that an electrostatic interaction between the partial negatively charged OBpin group and the partial positively charged bipyridine ligand of the catalyst favors ortho selectivity. Experimental and computational studies designed to test this hypothesis support it. From further computational work a second generation, in silico designed catalyst emerged, where replacing Bpin with Beg (eg = ethylene glycolate) was predicted to significantly improve ortho selectivity. Experimentally, reactions employing B2eg2 gave ortho selectivities > 99%. Adding triethylamine significantly improved conversions. This ligand–substrate electrostatic interaction provides a unique control element for selective C–H functionalization.
doi_str_mv	10.1021/jacs.7b02232
format	Article
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title	Ir-Catalyzed ortho-Borylation of Phenols Directed by Substrate–Ligand Electrostatic Interactions: A Combined Experimental/in Silico Strategy for Optimizing Weak Interactions
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