058 h undergo a prototropic shift to yield the Mg aziridinyl porp

058 h undergo a prototropic shift to yield the Mg.aziridinyl.porphin complex. The enthalpy change is favourable, −0.004 h. A further tropic shift with an activation energy of 0.111 h leads to ring opening, also with a favourable enthalpy change of −0.015 h. The ligand is then bound as a Mg.acetaldimine(ethanimine).porphin

complex. This mechanism constitutes another mechanism for the formation of reactive, and unstable, imines that could facilitate the formation of aziridine-2ones, which have been predicated as important in amino-acid synthesis (Aylward and Bofinger, 2001). The reactions have been shown to be feasible from the overall enthalpy Androgen Receptor assay changes in the ZKE approximation at the HF and MP2 /6–31G* level. Aylward, N.N and Bofinger, N, OLEB,6,2001. pp481–500 Collman J.P., Hegedus, L.S., Norton, J.R., Finke, G., Principles and Applications of Organotransition Metal Chemistry, University AG-881 research buy Science books, Mill Valley, California, 1987 pp525–608.

E-mail: n.​aylward@student.​qut.​edu.​au On the Possible Role of Metastable Excited Atoms in the Chemical Evolution of Planetary Atmospheres: A Laboratory Investigation by the Crossed Molecular Beam Technique Nadia Balucani, Raffaele Petrucci, Francesca Leonori, Piergiorgio Casavecchia Dipartimento di Chimica, Università degli Studi di Perugia, Perugia, Italy In our laboratory we have used the crossed molecular beam (CMB) technique with mass spectrometric (MS) detection to investigate elementary learn more reactions of relevance in the chemistry of planetary atmospheres for a number of years. The main advantage of CMB experiments is that it is possible to observe the consequences of well defined molecular collisions and avoid the effects of secondary or wall collisions (Balucani, et al. 2006). The quantities observable by this experimental technique allow us to achieve the most detailed characterization of a gas-phase reaction and to derive important features, such as the product branching ratios. In this respect, the coupling of the CMB technique with MS detection is crucial, because every product species can be ionized

at the electron energy used in the ionizer which precedes the mass filter and so detected. By using the CMB/MS technique we selleck have been able to fully characterize some reactions of relevance in astrochemistry involving atomic species—such as O, C and N (Balucani, et a1. 2006; Costes, et al. 2006; Balucani and Casavecchia, 2006)—or simple radicals—such as CN and OH (Casavecchia, et al., 2001)—or unstable closed-shell species—such as C2(Leonori, et al. 2008). In this contribution, the attention will be focused on several reactions involving electronically excited, metastable states of atomic species—namely C(1 D), N(2 D), O(1 D) and S(1 D). In all cases, the radiative lifetime—spanning the range from 30 s for S(1 D) to 48 h for N(2 D)—is long enough to allow for bimolecular reactions to occur, provided that the gas density is not too low.

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