Copper-Mediated Dehydrogenative C(sp³)–H Borylation of Alkanes

Abstract: Borylations of inert carbon–hydrogen bonds are highly useful for transforming feedstock chemicals into versatile organoboron reagents. Catalysis of these reactions has historically relied on precious-metal complexes, which promote dehydrogenative borylations with diboron reagents under oxidant-free conditions. Recently, photoinduced radical-mediated borylations involving hydrogen atom transfer pathways have emerged as attractive alternatives because they provide complimentary regioselectivities and proceed und… Show more

“…By increasing the amount of inexpensive and easily recyclable hexane to 20 equiv, we achieved a 55% isolated yield of hexyl 2,3-dihydro-1H-naphtho[1,8-de][1,3,2]diazaborinine (Bdan) ( 1′ , treated with 1,8-diaminonaphthalene 3instead of pinacol) with no loss of regioselectivity (entry 10). This success led to the regioselective C(sp 3 )–H borylation of unbranched alkanes under gentle photocatalytic conditions, a result previously unachievable without our sulfoxide-controlled photocatalytic procedure ( 43 – 45 ).…”

“…However, achieving selective modification of simple alkanes, particularly the terminal functionalization of unbranched chains, poses a formidable challenge owing to the formation of relatively unstable primary carbon radical intermediates through HAT from stronger C–H bonds (Fig. 1B) ( 19 – 21 , 27 , 37 , 38 , 42 – 45 ).…”

“…Nonetheless, the system exhibited unsatisfactory regioselectivity when applied to straight-chain substrates, such as pentane, resulting in an approximately 1:1 methyl to methylene ratio. Very recently, the Xia group ( 44 ) and Aggarwal group ( 45 ) independently reported intriguing C(sp 3 )–H borylation reactions that use base metal chlorides under light irradiation. The regioselectivity observed was similar to that of Aggarwal and Noble’s former metal-free work ( 43 ), thereby confirming the challenge of achieving selective borylation of unbranched alkanes.…”

Terminal C(sp ³ )–H borylation through intermolecular radical sampling

“…By increasing the amount of inexpensive and easily recyclable hexane to 20 equiv, we achieved a 55% isolated yield of hexyl 2,3-dihydro-1H-naphtho[1,8-de][1,3,2]diazaborinine (Bdan) ( 1′ , treated with 1,8-diaminonaphthalene 3instead of pinacol) with no loss of regioselectivity (entry 10). This success led to the regioselective C(sp 3 )–H borylation of unbranched alkanes under gentle photocatalytic conditions, a result previously unachievable without our sulfoxide-controlled photocatalytic procedure ( 43 – 45 ).…”

“…However, achieving selective modification of simple alkanes, particularly the terminal functionalization of unbranched chains, poses a formidable challenge owing to the formation of relatively unstable primary carbon radical intermediates through HAT from stronger C–H bonds (Fig. 1B) ( 19 – 21 , 27 , 37 , 38 , 42 – 45 ).…”

“…Nonetheless, the system exhibited unsatisfactory regioselectivity when applied to straight-chain substrates, such as pentane, resulting in an approximately 1:1 methyl to methylene ratio. Very recently, the Xia group ( 44 ) and Aggarwal group ( 45 ) independently reported intriguing C(sp 3 )–H borylation reactions that use base metal chlorides under light irradiation. The regioselectivity observed was similar to that of Aggarwal and Noble’s former metal-free work ( 43 ), thereby confirming the challenge of achieving selective borylation of unbranched alkanes.…”

Terminal C(sp ³ )–H borylation through intermolecular radical sampling

“…28 It is possible that another species may be acting as the terminal oxidant in this transformation; Aggarwal published a C–H borylation reaction under similar reaction conditions and observed the copper-catalyzed in situ formation of O(Bcat) 2 with residual water. 29 This oxidation of B 2 cat 2 is balanced by the reduction of the water to molecular hydrogen, allowing the C–H borylation to proceed with catalytic CuCl 2 .…”

Cu(ii) salts as terminal oxidants in visible-light photochemical oxidation reactions

“…However, the application of such C–H bond functionalization in constructing structurally diverse polyheterocycles is rare . Besides, while transition-metal-catalyzed C­(sp 3 )–H functionalization reactions with noble metals were widely used, the application of inexpensive metals, such as copper or iron, remains limited and is still challenging . Therefore, it is significant to develop novel catalytic systems for C­(sp 3 )–H bond activation toward structurally interesting molecules.…”

Copper-Catalyzed Synthesis of N-Fused Quinolines via C(sp³)–H Activation-Radical Addition–Cyclization Cascade