| Literature DB >> 29163916 |
Jasimuddin Ahmed1, Sreejyothi P1, Gonela Vijaykumar1, Anex Jose1, Manthan Raj2, Swadhin K Mandal1.
Abstract
The radical-mediated transitionEntities:
Year: 2017 PMID: 29163916 PMCID: PMC5674448 DOI: 10.1039/c7sc02661g
Source DB: PubMed Journal: Chem Sci ISSN: 2041-6520 Impact factor: 9.825
Scheme 1(a) Canonical forms of the phenalenyl radical showing the spin-bearing centers. (b) Examples of phenalenyl radicals that have undergone C–C σ-bond formation.
Scheme 2(a) General mechanism for the radical-mediated C–H functionalization process. (b) Shirakawa and Hayashi’s proposal of an organic ligand metal complex-based initiation process. (c) The proposed key intermediates for this reaction.
Reaction optimization for the transition metal-free C–H arylation of thiazole (1) at room temperature
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| Entry | Ligand (mol%) | Base (equiv.) | Solvent | Time (h) | Yield |
| 1 | PLY1 (5) | KO | DMSO | 24 | 28 |
| 2 | PLY2 (5) | KO | DMSO | 24 | 67 |
| 3 | PLY3 (5) | KO | DMSO | 24 | 59 |
| 4 | PLY2 (5) | KO | DMF | 24 | 37 |
| 5 | PLY2 (5) | KO | THF | 24 | 0 |
| 6 | PLY2 (5) | NaO | DMSO | 24 | 34 |
| 7 | PLY2 (5) | KO | DMSO | 24 | 64 |
| 8 | PLY2 (5) | KO | DMSO | 12 | 46 |
| 9 | PLY2 (1) | KO | DMSO | 24 | 32 |
| 10 | PLY2 (3) | KO | DMSO | 24 | 49 |
| 11 | PLY2 (5) | KO | DMSO | 24 | 62 |
| 12 | None | KO | DMSO | 24 | <10 |
| 13 | PLY2 (5) | None | DMSO | 24 | 0 |
| 14 |
| KO | DMSO | 24 | <10 |
| 15 |
| KO | DMSO | 24 | <10 |
Reaction conditions: thiazole (0.72 mmol), 2a (0.24 mmol), ligand (5 mol%, 0.012 mmol/1 mol%, 0.0024 mmol/3 mol%, 0.0072 mmol) and KOBu/NaOBu (1 equiv., 0.24 mmol/10 mol%, 0.024 mmol).
Isolated yield.
Dark conditions.
Fig. 1The transition metal-free C–H arylation of heteroarenes at room temperature. (a) The substrate scope for heteroarene arylation. (b) Large-scale synthesis of the core parts of bioactive molecules. (c) The C2 arylation of pyridine. NMR conversion: t = 24 h for azole arylation and t = 8 h for furan and thiophene arylation.
Fig. 2Mechanistic investigations. (a) The competition reaction between benzoxazole and a mixture of two aryl diazonium salts, 2a and 2e. (b) Inhibition of the benzoxazole arylation reaction in the presence of TEMPO. (c) Trapping of the aryl radical by TEMPO. (d) The stoichiometric reaction between a phenalenyl-based ligand and KOBu along with EPR spectra of complex I (before reduction) and green colored species (after reduction).
Fig. 3The plausible mechanistic reaction pathway.
Fig. 4The radical trapping reaction in acetonitrile. (a) The effect of an electron donor (KOBu or TDAE) on the yield. (b) Formation of the trapped phenalenyl radical and its solid state structure, and perspective ORTEP views of the molecular structure of 17. Thermal ellipsoids are drawn with 50% probability. Hydrogen atoms and solvent molecules (acetonitrile) have been omitted for the sake of clarity. Selected bond lengths (Å) and bond angles (°) for the structure of complex 17: O1–K1 2.570(4), O1–C1 1.300(6), C10–C11 1.397(8), C7–C10 1.602(8) and N2–C11 1.128(7); K1–O1–C1 139.7(3), C6A–C7–C8 112.8(4), C9–C8–C7 123.3(5), C11–C10–C7 111.5(5) and N2–C11–C10 173.9(7). (c) The reaction pathway for trapping the phenalenyl-based radical complex and spin density plots of the K-PLY2 radical complex and CH2CN radical.