Your search keyword '"Khrouz L"' showing total 3 results

1. Self-Sensitized Photooxidation of Naphthols to Naphthoquinones and the Use of Naphthoquinones as Visible Light Photocatalysts in Batch and Continuous Flow Reactors.

Author

Lancel M, Zimberlin P, Gomez C, Port M, Khrouz L, Monnereau C, and Amara Z

Abstract

Visible light photooxidation of naphthols to produce naphthoquinones, such as the natural product juglone, has been known for decades and has been widely utilized to benchmark the performances of a variety of photocatalytic systems. We discovered that these transformations can occur without the help of a photocatalyst and, even more intriguingly, that the photocatatyst-free process provides higher yields compared to control experiments utilizing state-of-the-art photocatalysts. In addition, we demonstrate that naphthoquinones and their corresponding naphthol precursors can act as alternatives to commonly used organic and organometallic photocatalysts with applications to challenging targets, such as the antimalarial drug artemisinin. This approach was finally transposed in continuous flow reactors where high photocatalyst stability and process efficiency are demonstrated with a 23× improvement in the space-time yield.

Published

2023

2. Ni-Centered Coordination-Induced Spin-State Switching Triggered by Electrical Stimulation.

Author

Al Shehimy S, Baydoun O, Denis-Quanquin S, Mulatier JC, Khrouz L, Frath D, Dumont É, Murugesu M, Chevallier F, and Bucher C

Subjects

Electric Stimulation, Imidazoles, Ligands, Viologens, Nickel chemistry, Porphyrins

Abstract

We herein report the synthesis and magnetic properties of a Ni(II)-porphyrin tethered to an imidazole ligand through a flexible electron-responsive mechanical hinge. The latter is capable of undergoing a large amplitude and fully reversible folding motion under the effect of electrical stimulation. This redox-triggered movement is exploited to force the axial coordination of the appended imidazole ligand onto the square-planar Ni(II) center, resulting in a change in its spin state from low spin ( S = 0) to high spin ( S = 1) proceeding with an 80% switching efficiency. The driving force of this reversible folding motion is the π-dimerization between two electrogenerated viologen cation radicals. The folding motion and the associated spin state switching are demonstrated on the grounds of NMR, (spectro)electrochemical, and magnetic data supported by quantum calculations.

Published

2022

3. Room Temperature Magnetic Switchability Assisted by Hysteretic Valence Tautomerism in a Layered Two-Dimensional Manganese-Radical Coordination Framework.

Author

Lannes A, Suffren Y, Tommasino JB, Chiriac R, Toche F, Khrouz L, Molton F, Duboc C, Kieffer I, Hazemann JL, Reber C, Hauser A, and Luneau D

Abstract

The manganese-nitronyl-nitroxide two-dimensional coordination polymer {[Mn 2 (NITIm) 3 ]ClO 4 } n (1) (NITImH = 2-(2-imidazolyl)-4,4,5,5-tetramethyl-4,5-dihydro-1H-3-oxide-1-oxyl) undergoes an unusual hysteretic thermo-induced valence tautomeric transition near room temperature, during which the manganese(II) ions are oxidized to manganese(III) and two of the three deprotonated radicals (NITIm - ) are reduced to their diamagnetic aminoxyl form (denoted NIT Red 2- ). Upon cooling, the high-temperature species {[Mn II 2 (NITIm) 3 ]ClO 4 } n (1 HT ) turns into the low-temperature species {[Mn III 2 (NIT Red ) 2 (NITIm)]ClO 4 } n (1 LT ) around 274 K, while on heating the process is reversed at about 287 K. This valence tautomeric phenomenon is supported by temperature-dependent magnetic susceptibility measurements, differential scanning calorimetry (DSC), crystal structure determination, UV-vis absorption, X-ray absorption (XAS), and emission (XES) and electron paramagnetic resonance (EPR) spectroscopies in the solid state.

Published

2016