Chiral Ions in the Gas Phase. 1. Intramolecular Racemization and Isomerization of O-Protonated (<i>S</i>)-<i>trans</i>-4-Hexen-3-ol

Troiani, Anna; Gasparrini, Francesco; Grandinetti, Felice; Speranza, Maurizio

doi:10.1021/ja960212p

Cited by 16 publications

(45 citation statements)

References 41 publications

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“…[17,18] Indeed, as already pointed out for the CH 3 Cl systems, [3,13] the n G = 1021 AE 22 cm À1 matches the n 6 (e) CH 3 rocking mode of unperturbed CH 3 Cl molecules (n 6 (e) = 1015 cm…”

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confidence: 77%

Gaseous Ion Activation Dynamics: The Role of the Bulk Gas in the Racemization of Chiral Oxonium Ions

Filippi

Speranza

2004

ChemPhysChem

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The kinetics of the inversion of configuration of a family of chiral oxonium ions, that is, O-protonated 1-aryl-1-methoxyethanes [YMe+], were investigated in two different gaseous media (in CH3X with X=F and X=Cl) at 720 torr of pressure and in the temperature range: 25-140 degrees C. The activation parameters of the [YMe+] inversion reaction were found to obey two different isokinetic relationships (IKR), depending on the nature and the position of the substituents in the oxonium ions and on the nature of the bulk gas employed. The observation of two IKR for the same family of reactions was related to a switchover in the resonant vibrational energy exchange between the reactants' critical mode, active in the transition state (omega), and the discrete vibrational levels v of the bulk gas. In CH3F, this vibrational-vibrational coupling switchover concerns the out-of-plane C-F...H-O bending) the phi family) and the H3C-F stretching (the gamma family) modes in the proton-bound [CH3F.YMe+] complex. In CH3Cl, the coupling switchover concerns the out-of-plane C-Cl...H-O bending (the phi family) and the H3C-Cl methyl group rocking (the gamma family) modes in the proton-bound [CH3Cl.YMe+] complex. The [YMe+] activation dynamics also determine the inversion dynamics. The [YMe+]ret<==>[YMe+]inv isomerization for the phi family involves the same "thermodynamically most favorable" transition state in both the CH3F and the CH3Cl media, whereas the same process for the gamma family proceeds through different, dynamically favored transition states.

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confidence: 77%

Gaseous Ion Activation Dynamics: The Role of the Bulk Gas in the Racemization of Chiral Oxonium Ions

Filippi

Speranza

2004

ChemPhysChem

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“…90:10 for 29 ). We consider that the two reactive intermediates 43 and 44 might be involved in the product-forming step (Scheme ) . A nucleophile attacks at the protonated allyl alcohol in either an S N 2 or an S N 2‘ fashion to form two regioisomers.…”

Section: Resultsmentioning

confidence: 99%

Regioselective Synthesis of Acycliccis-Enediynes via an Acid-Catalyzed Rearrangement of 1,2-Dialkynylallyl Alcohols. Syntheses, Computational Calculations, and Mechanism

Dai

Fong

et al. 1999

J. Org. Chem.

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A novel synthesis of acyclic cis-enediynes 2 has been established by an acid-catalyzed rearrangement of 1,2-diyn-2-propen-1-ols 1 possessing a C 3 -aryl group in the presence of water, alcohols, or thiols. Reactivity of allyl alcohols and regio-and cis/trans diastereoselectivity of the allylic migration were examined. In the presence of (()-10-camphorsulfonic acid (CSA), the parent allyl alcohol 5 and the C 3 -methyl-substituted 9 failed to give enediynes, whereas the C 3 -aryl-substituted 12 and 29 underwent the allylic rearrangement to provide predominantly cis-enediynes 16 and 31 at room temperature or below. Under similar acidic conditions, enediyne alcohol 13 produced 16b and 16d with the same regio-and cis/trans diastereoselectivity observed for 12. Allyl alcohol 30, an isomer of 29, also provided enediynes 31c and 32c after a prolonged reaction (90 h) at room temperature in the presence of CSA and EtOH. These results suggested that the same allylic cations were obtained from allyl alcohols 12 and 13 or 29 and 30 even though the ease of ionization differed for each substrate. Involvement of allylic cations in the product-forming step was confirmed by the finding that chiral allyl alcohols (-)-12 and (-)-18c furnished racemic products. In general, the p-MeOPh-substituted allyl alcohol 29 gave a better regioselectivity than the Ph-substituted 12. In the reactions with alcohols, the regioisomeric ratios were 100:0 (31:33) for 29 and ca. 96:4 (16:17) for 12; the ratios decreased to ca. 90:10 (31:33) for 29 and ca. 70:30 (16:17) for 12 when thiols were used. The cis/trans diastereoselectivity is higher for allyl alcohol 12 (100% for 16 at 20 °C) compared to that for 29 (31:32 ) 80:20-94:6 at 0 °C). Computational calculations at the RHF/3-21G level, carried out on the model compounds and allylic cations, indicated that nucleophilic trapping takes place preferentially at the C 3 carbon to form the thermodynamically much more stable enediynes. Under the best reaction conditions (1 equiv of CSA and 2 equiv of EtOH in CH 2 Cl 2 , 20 °C), a number of acyclic cis-enediynes can be synthesized in three steps from the commercially available R-bromocinnamaldehyde (10).

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“…In the preceding paper of this series, the kinetics and the dynamics of the unimolecular racemization and regioisomerization of O-protonated ( S )- trans -4-hexen-3-ol (the IS anti / IS syn mixture in Scheme ) have been investigated in the dilute gas state, i.e., in a reaction environment entirely free from the interference of solvation, ion-pairing, etc., that normally complicates analogous studies in solution. − The results are consistent with a gas-phase intramolecular racemization and regioisomerization involving the intermediacy of the hydrogen-bonded complexes B and C in Scheme , In the particular case of B and C , the moving H 2 O molecule is coplanarly coordinated to the in-plane hydrogens of the allyl cation moiety. The formation of these hydrogen-bonded complexes is determined by kinetic factors as well as by the specific conformation of their oxonium ion precursors.…”

Section: Introductionmentioning

confidence: 99%

“…To enlarge our knowledge of the factors governing acid-promoted unimolecular racemization and regioisomerization of chiral allyl alcohols in the gaseous state, the kinetic investigation has been now extended to the rearrangement of ( S )- trans -4-hexen-3-ol (the 1S anti / 1S syn mixture, henceforth denoted as 1S ) and ( R )- trans -3-hexen-2-ol (the 2R anti / 2R syn mixture, henceforth denoted as 2R ) promoted by a pure Lewis acid, such as the dimethylchloronium ion (CH 3 ) 2 Cl + (Scheme ). By this approach, the methylated oxonium ions IS‘ anti / IS‘ syn (henceforth denoted as IS‘ ) and IIR‘ anti / IIR‘ syn (henceforth denoted as IIR‘ ) can be readily prepared in the dilute gas phase and their rearrangement kinetics evaluated with the same procedures employed in previous studies . Thus, stationary concentrations of the (CH 3 ) 2 Cl + Lewis acid have been generated from γ-radiolysis of gaseous mixtures, containing CH 3 Cl, as the bulk component (720 Torr), together with traces of the chiral alcohol (either 1S or 2R ; 0.5−0.7 Torr), of O 2 , as a radical scavenger (10 Torr), and of (CH 3 O) 3 PO (0.8−0.9 Torr), as a powerful base (proton affinity (PA)=212.0 kcal mol -1 ) .…”

Section: Introductionmentioning

confidence: 99%

Intracomplex CH₃OH Walking around Optically Active 1-Methyl-3-ethylallyl Cations. A Gas-Phase Kinetic Study

Troiani

Speranza

1998

J. Org. Chem.

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The kinetics and the mechanism of the racemization and regioisomerization of O-methylated (S)trans-4-hexen-3-ol (IS′) or (R)-trans-3-hexen-2-ol (IIR′) have been investigated in the gas phase at 720 Torr and in the 40-120 °C temperature range. The starting oxonium intermediates were generated in the gas phase by the reaction of (CH 3 ) 2 Cl + ions, formed by stationary γ-radiolysis of bulk CH 3 Cl, on the corresponding optically active alcohols. The rate constant of the gas-phase regioisomerization of IS′ ((3.4-16.0) × 10 6 s -1 ) was found to exceed that of its racemization ((1.9-9.8) × 10 6 s -1 ) over the entire temperature range. Similar differences were observed for the regioisomerization ((2.9-15.0) × 10 6 s -1 ) and the racemization of IIR′ ((1.8-9.6) × 10 6 s -1 ). By analogy with previous experimental and theoretical evidence, these results are consistent with intramolecular racemization and regioisomerization processes involving the intermediacy of two distinct hydrogen-bonded complexes, wherein the CH 3 OH molecule is coplanarly coordinated to the in-plane hydrogens of the 1-methyl-3-ethylallyl moiety. The activation parameters for their formation from the IS′ and IIR′ were evaluated and compared with those concerning the racemization and regioisomerization of O-protonated (S)-trans-4-hexen-3-ol (IS), previously measured in the gas phase under similar experimental conditions. The comparison reveals that gas-phase racemization and regioisomerization of O-protonated (S)-trans-4-hexen-3-ol (1S′) (AOHdH 2 O) involve transition structures located early along the reaction coordinate, whereas the transition structures involved in the rearrangement of O-methylated (S)-trans-4-hexen-3-ol (1S′) and (R)trans-3-hexen-2-ol (IIR′) (AOH ) CH 3 OH) are placed later along the reaction coordinate and are characterized by a strong coordination of the moving CH 3 OH molecule with the hydrogens of the allylic moiety.

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Chiral Ions in the Gas Phase. 1. Intramolecular Racemization and Isomerization of O-Protonated (S)-trans-4-Hexen-3-ol

Cited by 16 publications

References 41 publications

Gaseous Ion Activation Dynamics: The Role of the Bulk Gas in the Racemization of Chiral Oxonium Ions

Gaseous Ion Activation Dynamics: The Role of the Bulk Gas in the Racemization of Chiral Oxonium Ions

Regioselective Synthesis of Acycliccis-Enediynes via an Acid-Catalyzed Rearrangement of 1,2-Dialkynylallyl Alcohols. Syntheses, Computational Calculations, and Mechanism

Intracomplex CH₃OH Walking around Optically Active 1-Methyl-3-ethylallyl Cations. A Gas-Phase Kinetic Study

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Chiral Ions in the Gas Phase. 1. Intramolecular Racemization and Isomerization of O-Protonated (S)-trans-4-Hexen-3-ol

Cited by 16 publications

References 41 publications

Gaseous Ion Activation Dynamics: The Role of the Bulk Gas in the Racemization of Chiral Oxonium Ions

Gaseous Ion Activation Dynamics: The Role of the Bulk Gas in the Racemization of Chiral Oxonium Ions

Regioselective Synthesis of Acycliccis-Enediynes via an Acid-Catalyzed Rearrangement of 1,2-Dialkynylallyl Alcohols. Syntheses, Computational Calculations, and Mechanism

Intracomplex CH3OH Walking around Optically Active 1-Methyl-3-ethylallyl Cations. A Gas-Phase Kinetic Study

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Intracomplex CH₃OH Walking around Optically Active 1-Methyl-3-ethylallyl Cations. A Gas-Phase Kinetic Study