Microwave spectrum, substitutional structure, and Stark and Zeeman effects in cyclopropenone

Benson, Richard C.; Flygare, W. H.; Oda, Masaomi; Breslow, R.

doi:10.1021/ja00790a004

Cited by 94 publications

(59 citation statements)

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“…This step commenced by the gradual shortening of the C1-C2 and C3-O bonds. Table 1 shows the results using the MP2 and B3LYP methods, which are in good agreement with previous theoretical [40][41][42] and experimental [39,40] studies. Our results indicate that an explanation for the non-dynamic electron correlation in the calculated stationary points on the reaction path of the decomposition of cyclopropenones should be considered.…”

Section: Resultssupporting

confidence: 86%

Theoretical investigation of the photochemical reaction mechanism of cyclopropenone decarbonylation

2011

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The gas-phase decomposition mechanism of the photochemical and thermal reaction of cyclopropenone leading to carbon monoxide and acetylene has been investigated theoretically. We employed the B3LYP, MP2, and CASSCF methods with the 6-311 þ G** basis set to determine the pathways and the potential energy surface (PES) of this reaction. PES minima were characterized by the absence of any imaginary frequencies and compared with the transition states that contained single imaginary frequencies. The intrinsic reaction coordinate (IRC) method was used to find the minimum energy paths in which reactants and products were connected to the transition states. Activation barrier, thermodynamic, and IRC analyses were performed using the above three methods. Our computations indicated that the decomposition of cyclopropenone proceeds through a stepwise mechanism containing two transition states (TS1 and TS2) and an intermediate. The results show that TS1, the critical transition state, determines the rate of the cyclopropenone decomposition reaction. Therefore, we employed natural bond order (NBO) calculations to probe the structure of the intermediate. The calculations showed that the intermediate has resonance structures containing a carbene and a zwitterion. Our results are in good agreement with previous theoretical and experimental studies.

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Section: Resultssupporting

confidence: 86%

Theoretical investigation of the photochemical reaction mechanism of cyclopropenone decarbonylation

2011

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“…For propynal, the spectral line data were determined from a fit to the laboratory measurements of , Costain & Morton (1959), Takami &Shimoda (1976), andWinnewisser (1973). For cyclopropenone, the spectral line data were calculated from a fit to the laboratory frequencies reported by Benson et al (1973) and Guillemin et al (1990). For cyclopropene, the spectral line data were calculated from a fit to the laboratory measurements of , Stigliani et al (1975), Bogey et al (1986), and Vrtilek et al (1987).…”

Section: Observations and Resultsmentioning

confidence: 99%

Cyclopropenone (c‐H₂C₃O): A New Interstellar Ring Molecule

Hollis

Remijan

Jewell

et al. 2006

ApJ

106

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The three-carbon keto ring cyclopropenone (c-H 2 C 3 O) has been detected largely in absorption with the 100 m Green Bank Telescope (GBT ) toward the star-forming region Sagittarius B2( N ) by means of a number of rotational transitions between energy levels that have energies less than 10 K. Previous negative results from searches for interstellar c-H 2 C 3 O by other investigators attempting to detect rotational transitions that have energy levels $10 K or greater indicate no significant hot core component. Thus, we conclude that only the low-energy levels of c-H 2 C 3 O are populated because the molecule state temperature is low, suggesting that c-H 2 C 3

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“…Similarly, the C=C distance changes from 1.338 A in 2,3-dimethylthiirene 1,1-dioxide (IVa) to 1.354 A in the diphenyl compound (IVb) (Ammon, Fallon & Plastas, 1976). The effect is quite dramatic in the cyclopropenones, in which there is ca 0.05 /k increase from cyclopropenone (1.302 A; Benson, Flygare, Oda & Breslow, 1973) to 2,3-diphenylcyclopropenone (1.349 /~; Tsukada, Shimanouchi & Sasada, 1974). Interestingly, the trend in C=C bond lengths in alkyl-and aryl-substituted alkenes is opposite to that observed in the three-membered-ring compounds.…”

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confidence: 85%

1,2-Dimethyl-4,4-triafulvenedicarbonitrile

Ammon¹,

Sherrer²,

Eicher³

1978

Acta Crystallogr Sect B

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Abstract. C8H6N 2, M, = 130.1, monoclinic, P21/n; a = 7.414(1), b = 15.572(1), c = 7.478(1) A, fl = 118.19 (1)°; D e = 1.136 g cm -3 for Z = 4; Mo K~t diffractometer data. Final R = 0.041. The endocyclic C=C distance of 1.327 A is ca 0.02 A less than the value found in diphenyltriafulvenes, a difference which appears to be characteristic of the change in the threemembered-ring substituents from phenyl to alkyl. There are no significant differences between the other structural parameters of the 1,2-dimethyl-and 1,2-diphenyl-4,4-triafulvenedicarbonitriles.Introduction. A sample of 1,2-dimethyl-4,4-triafulvenedicarbonitrile (Ia), prepared in the laboratories of T. Eicher, crystallized from ethanol in the form of colorless blocks. A cube-shaped crystal, ca 0.4 mm in all dimensions, mounted parallel to a, was used for all X-ray measurements. The space group was established with oscillation and Weissenberg photographs with Cu radiation. All lattice-parameter and intensity measurements were made with a Picker FACS-I diffractometer with Mo radiation [graphite monochromator, 2(Mo K~t) = 0.71069 A] with the crystal aligned to place a* paral!el to the instrument's ~p axis. The final unit-cell parameters were obtained by least-squares calculations from the Bragg angles of 12 reflections manually centered at +20 (average of120 o20el = 0.003°).Intensities were measured with the 0-20 scan method, with a 20 scan rate of 2.0 ° min -~, and with 20 s backgrounds. Three standard reflections were counted at 100-reflection intervals. 1575 data were measured to a 20 maximum of 50 ° giving 1340 unique reflections (excluding 63 systematically absent data); 880 of these were 3a above background. The structure was solved by direct methods with the XRAY system (Stewart, Kruger, Ammon, Dickinson & Hall, 1972) subprogram PHASE. The phasing required the calculation of four E maps (corresponding to the four + combinations of two

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Microwave spectrum, substitutional structure, and Stark and Zeeman effects in cyclopropenone

Cited by 94 publications

References 0 publications

Theoretical investigation of the photochemical reaction mechanism of cyclopropenone decarbonylation

Theoretical investigation of the photochemical reaction mechanism of cyclopropenone decarbonylation

Cyclopropenone (c‐H₂C₃O): A New Interstellar Ring Molecule

1,2-Dimethyl-4,4-triafulvenedicarbonitrile

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Microwave spectrum, substitutional structure, and Stark and Zeeman effects in cyclopropenone

Cited by 94 publications

References 0 publications

Theoretical investigation of the photochemical reaction mechanism of cyclopropenone decarbonylation

Theoretical investigation of the photochemical reaction mechanism of cyclopropenone decarbonylation

Cyclopropenone (c‐H2C3O): A New Interstellar Ring Molecule

1,2-Dimethyl-4,4-triafulvenedicarbonitrile

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Cyclopropenone (c‐H₂C₃O): A New Interstellar Ring Molecule