A Convenient Photocatalytic Fluorination of Unactivated CH Bonds

Halperin, Shira D.; Fan, Hope; Chang, Stanley; Martin, Rainer E.; Britton, Robert

doi:10.1002/anie.201400420

Cited by 270 publications

(140 citation statements)

References 36 publications

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“…The Inoue, 9 Tang, 10 and Hartwig 11 groups have also shown that N -oxyl radical and silver salts can catalyze or promote C–H fluorination. More recently, photolytic activation methods have also been reported by Britton, 12 Lectka, 8c and Tan 13 using decatungstate, 1,2,4,5-tetracyanobenzene (TCB), and anthraquinone (AQN) as the catalyst, respectively.…”

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confidence: 99%

Visible light-promoted metal-free sp³-C–H fluorination

2014

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Photoexcited acetophenone can catalyze the fluorination of unactivated C(sp3)–H groups. While acetophenone, a colorless oil, only has a trace amount of absorption in the visible light region, its photoexcitation can be achieved by irradiation with light generated by a household compact fluorescent lamp (CFL). This operational simple method provides improved substrate scope for the direct incorporation of a fluorine atom into simple organic molecules. CFL-irradiation can also be used to promote certain classic UV-promoted photoreactions of colorless monoarylketones and enones/enals.

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confidence: 99%

Visible light-promoted metal-free sp³-C–H fluorination

2014

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“…28) [55]. The reaction was designed on the basis of the documented ability of 10 to abstract hydrogen atoms from saturated organic fragments upon irradiation with light [56].…”

Section: Fluorination Of C-h Bondsmentioning

confidence: 99%

Transition Metal-Mediated and Metal-Catalyzed Carbon–Fluorine Bond Formation

Campbell

Hoover

Ritter

2014

Topics in Organometallic Chemistry

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The development of new C-F bond forming reactions from organotransition metal complexes has played a key role in advancing the field of fluorination chemistry and has allowed for improved access to fluorinated organic molecules of interest in medicine, materials, and agrochemicals. In this review, we describe the development of transition metal-mediated and metal-catalyzed fluorination methods over the past decade. Special attention is paid to the variety of organometallic mechanisms by which C-F bond formation can occur and the strengths and limitations of different approaches.

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“…An example is sclareolide: acetophenone 9 (80%/16 turnovers), anthraquinone 10 (77%/39 turnovers), 1,2,4,5-tetracyanobenzene 7 (61%/6.1 turnovers), and TBADT 8 (68%/34 turnovers) all produced mixtures of monofluorinated products in moderate to high yields as compared to the low result observed for the uranium system (26%/26 turnovers, Table 3, Entry 11). Similarly, acetal and ether functional groups are incompatible with the uranyl system, with the dioxolane derived from condensing cyclopentanone with ethylene glycol providing even less reactivity than the parent ketone (Table 3, Entry 12) and tert -butyl methyl ether not producing any fluorinated product.…”

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confidence: 96%

“…Indeed, the recent reports from Lectka, 7 Britton, 8 Chen, 9 and Tan 10 suggests that, despite progress, this transformation is not yet a solved problem. With some exceptions, 11,12,13 recent strategies for selectively fluorinating C sp3 –H bonds have largely recruited photo-hydrogen atom abstraction (HAT) catalysts (denoted [cat]), such as acetophenone, anthraquinone, 1,2,4,5-tetracyanobenzene, and tetra- n -butylammonium decatungstate (TBADT, Figure 1), to generate a carbon-centered radical.…”

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The Uranyl Cation as a Visible‐Light Photocatalyst for C(sp³)−H Fluorination

2016

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The fluorination of unactivated Csp3–H bonds remains a desirable, challenging transformation for pharmaceutical, agricultural, and materials scientists. Previous methods for this transformation have used bench-stable fluorine atom sources; however, many still rely on the use of UV-active photocatalysts for the requisite high-energy hydrogen atom abstraction event. Herein, we describe the use of uranyl nitrate hexahydrate as a convenient, hydrogen atom abstraction catalyst that can mediate fluorinations of certain alkanes upon activation with visible light.

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A Convenient Photocatalytic Fluorination of Unactivated CH Bonds

Cited by 270 publications

References 36 publications

Visible light-promoted metal-free sp³-C–H fluorination

Visible light-promoted metal-free sp³-C–H fluorination

Transition Metal-Mediated and Metal-Catalyzed Carbon–Fluorine Bond Formation

The Uranyl Cation as a Visible‐Light Photocatalyst for C(sp³)−H Fluorination

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A Convenient Photocatalytic Fluorination of Unactivated CH Bonds

Cited by 270 publications

References 36 publications

Visible light-promoted metal-free sp3-C–H fluorination

Visible light-promoted metal-free sp3-C–H fluorination

Transition Metal-Mediated and Metal-Catalyzed Carbon–Fluorine Bond Formation

The Uranyl Cation as a Visible‐Light Photocatalyst for C(sp3)−H Fluorination

Contact Info

Product

Resources

About

Visible light-promoted metal-free sp³-C–H fluorination

Visible light-promoted metal-free sp³-C–H fluorination

The Uranyl Cation as a Visible‐Light Photocatalyst for C(sp³)−H Fluorination