Defluorination of Perfluoropropene Using Cp*2ZrH2 and Cp*2ZrHF: A Mechanism Investigation from a Joint Experimental−Theoretical Perspective

Application of Industrially Relevant HydroFluoroOlefin (HFO) Gases in Organic Syntheses

Hydrofluoroolefin (HFO) gases are state-of-the-art cooling agents with widespread household and industrial applications. Considering their structural benefits these fluorous feedstocks have gained the attention of organic chemists in the last couple of years. In this short review we summarized the existing synthetic transformations of these gaseous starting material and present their applicability in the synthesis of fluorine-containing organic molecules, which have potential importance as building blocks and reagents for diverse syntheses.

1 Introduction

2 Addition Reactions

3 Substitutions

4 Organometallic Chemistry

4.1 Organolithium Compounds

4.2 Organometallic Complexes

4.3 Silicon Organic Chemistry

4.4 Boron Organic Chemistry

4.5 Palladium-Catalyzed Transformations

4.6 Metathesis

4.7 Hydroesterification, Hydroformylation

5 Conclusions

Copolymerization of Ethylene and Vinyl Fluoride by Self-Assembled Multinuclear Palladium Catalysts

The self-assembled multinuclear Pd^II complexes {(Li-OPO^OMe2)PdMe(4-5-nonyl-pyridine)}₄Li₂Cl₂ (C, Li-OPO^OMe2 = PPh(2-SO₃Li-4,5-(OMe)₂-Ph)(2-SO₃⁻-4,5-(OMe)₂-Me-Ph)), {(Zn-OP-P-SO)PdMe(L)}₄ (D, L = pyridine or 4-^tBu-pyridine, [OP-P-SO]³⁻ = P(4-^tBu-Ph)(2-PO₃²⁻-5-Me-Ph)(2-SO₃⁻-5-Me-Ph)), and {(Zn-OP-P-SO)PdMe(pyridine)}₃ (E) copolymerize ethylene and vinyl fluoride (VF) to linear copolymers. VF is incorporated at levels of 0.1–2.5 mol% primarily as in-chain -CH₂CHFCH₂- units. The molecular weight distributions of the copolymers produced by D and E are generally narrower than for catalyst C, which suggests that the Zn-phosphonate cores of D and E are more stable than the Li-sulfonate-chloride core of C under copolymerization conditions. The ethylene/VF copolymerization activities of C–E are over 100 times lower and the copolymer molecular weights (MWs) are reduced compared to the results for ethylene homopolymerization by these catalysts.

Selective Copper Complex-Catalyzed Hydrodefluorination of Fluoroalkenes and Allyl Fluorides: A Tale of Two Mechanisms

The transition to more economically friendly small-chain fluorinated groups is leading to a resurgence in the synthesis and reactivity of fluoroalkenes. One versatile method to obtain a variety of commercially relevant hydrofluoroalkenes involves the catalytic hydrodefluorination (HDF) of fluoroalkenes using silanes. In this work it is shown that copper hydride complexes of tertiary phosphorus ligands (L) can be tuned to achieve selective multiple HDF of fluoroalkenes. In one example, HDF of the hexafluoropropene dimer affords a single isomer of heptafluoro-2-methylpentene in which five fluorines have been selectively replaced with hydrogens. DFT computational studies suggest a distinct HDF mechanisms for L₂CuH (bidentate or bulky monodentate phosphines) and L₃CuH (small cone angle monodentate phosphines) catalysts, allowing for stereocontrol of the HDF of trifluoroethylene.

Synthesis and Reactivity of Mn–CF3 Complexes

The synthesis, characterization and reactivity of several bi- and tridentate, N-ligated manganese carbonyl trifluoromethyl complexes are presented. These complexes exhibit elongated Mn–CCF3 bonds (versus Mn(CF3)(CO)5), suggesting a lability that could be utilized for the transfer or insertion of the CF3 functional group into organic substrates. Unlike their Mn–X congeners (X = Cl, Br), these Mn–CF3 complexes exhibit a preference for hard donor ancillary ligands, thus enabling the synthesis of 4 N-ligated Mn–CF3 complexes including a mixed-donor tridentate complex using an NNS Schiff base ([2-(methylthio)-N-(1-(pyridin-2-yl)ethylidene)aniline]). Although we have not yet identified efficient CF3 transfer reactions, fluoride abstraction from the Mn–CF3 complexes using trimethylsilyl triflate affords the first stable Mn fluorocarbenes as evidenced by 19F NMR spectroscopy.

Olefin Insertion into a Pd-F Bond: Catalyst Reactivation Following β-F Elimination in Ethylene/Vinyl Fluoride Copolymerization

The discrete (phosphinoarenesulfonate)Pd fluoride complex (PO^Bp,OMe )PdF(lutidine), where PO^Bp,OMe =(2-MeOC₆ H₄ )(2-{2,6-(MeO)₂ C₆ H₃ }C₆ H₄ )(2-SO₃ -5-MeC₆ H₃ )P, inserts vinyl fluoride (VF) to form (PO^Bp,OMe )PdCH₂ CHF₂ (lutidine) and inserts multiple ethylene (E) units to generate polyethylene that contains -CH₂ F chain ends. These results provide strong evidence that the -CHF₂ and -CH₂ F chain ends in E/VF copolymer generated by (phosphinoarenesulfonate)PdR catalysts form by β-F elimination of Pd(β-F-alkyl) species, VF or E insertion of the resulting (PO)PdF species, and subsequent chain growth. These results also imply that β-F elimination is not an important catalyst deactivation reaction in this system.

Synthesis of a rhodium(i) germyl complex: a useful tool for C–H and C–F bond activation reactions

The rhodium(i) germyl complex [Rh(GePh₃)(PEt₃)₃] is a useful tool for C–F and C–H bond activation reactions. For instance, treatment with hexafluoropropene results in the formation of two isomeric C–F activation products [Rh{(E)-CFCF(CF₃)}(PEt₃)₃] and [Rh{(Z)-CFCF(CF₃)}(PEt₃)₃] in a 3 : 1 ratio.

Access to novel fluorovinylidene ligands via exploitation of outer-sphere electrophilic fluorination: new insights into C–F bond formation and activation

Metal fluorovinylidene complexes have been synthesised for the first time by direct electrophilic fluorination of metal alkynyls.

Competing reaction pathways of 3,3,3-trifluoropropene at rhodium hydrido, silyl and germyl complexes: C–F bond activation versus hydrogermylation

The reactivity of the Rh complexes [Rh(L)(PEt₃)₃] (L = H, Si(OEt)₃, GePh₃) towards CH₂CHCF₃ was investigated which involve C–F bond activation and germylation reactions.

Improving selectivity in catalytic hydrodefluorination by limiting SNV reactivity

Competition of HM, SBM and S_NV in hydrodefluorination can lead to low selectivity which can be improved via solvent change.

Chemo-, regio-, and stereo-selective perfluoroalkylations by a Grignard complex with zirconocene

The unique reactivity and high selectivity of the zirconocene-hybridized heterobimetallic perfluoalkyl Grignard reagents can be employed for efficient and highly selective nucleophilic perfluoroalkylation of carbonyl compounds and epoxides, in particular.