Molecular systems butadiene

Treating the jr-system butadiene molecule with a HMO (Hiickel molecular orbital) approach, we get four MOs, which are linear combinations of the four atomic p orbitals... 

The polarizable continuum model (PCM) by Tomasi and coworkers [77-79] was selected to describe the effects of solvent, because it was used to successfully investigate the effect of solvent upon the energetics and equilibria of other small molecular systems. The PCM method has been described in detail [80]. The solvents and dielectric constants used were benzene (s = 2.25), methylene chloride (g = 8.93), methanol (g = 32.0), and water (g = 78.4). Full geometry optimizations were carried out for the discrete and PCM models. To simultaneously account for localized hydrogen bonding and bulk solvation effects, PCM single-point energy calculations have been conducted on stationary points of the acrolein and butadiene reaction with two waters explicitly... 

Babkin V. A. and Andreev D. S. Quantum chemical calculation of molecule butadien-1,3 by method MNDO. In Quantum chemical calculation of unique molecular system. Vol. I. Publisher VolSU, c. Volgograd, pp. 235-236 (2010). 

One must speak of a delocalized electron system, comprising the four electrons in butadiene, and stemming from the interactions of the four atomic p electrons. This may be given a more quantitative aspect by saying that in the molecule each of these four electrons occupies a molecular orbital extending over the whole molecular system, and according to the LCAO concept, that this molecular orbital may be written as a linear combination... 

Investigation of excited states of polyatomic molecules in solution provides a good framework in order to study many classes of interactions. But their lifet ime is very short (10 s - 10 °s). So, in order to study such excited states we have built a picosecond absorption spectrometer which allowed us to study many types of molecular systems in solution. We present here two such studies. In the first one (1-4-diphenyl-butadiene) we have shown a solvent assisted electronic level inversion. In the second one we have studied interactions between an intramolecular charge transfer state and polar environment. Before discussing these results, we present the apparatus we have built in our lab. 

Let us now examine the Diels-Alder cycloaddition from a molecular orbital perspective Chemical experience such as the observation that the substituents that increase the reac tivity of a dienophile tend to be those that attract electrons suggests that electrons flow from the diene to the dienophile during the reaction Thus the orbitals to be considered are the HOMO of the diene and the LUMO of the dienophile As shown m Figure 10 11 for the case of ethylene and 1 3 butadiene the symmetry properties of the HOMO of the diene and the LUMO of the dienophile permit bond formation between the ends of the diene system and the two carbons of the dienophile double bond because the necessary orbitals overlap m phase with each other Cycloaddition of a diene and an alkene is said to be a symmetry allowed reaction... 

Since the six carbons shown above have 10 additional bonds, the variety of substituents they carry or the structures they can be a part of is quite varied, making the Diels-Alder reaction a powerful synthetic tool in organic chemistry. A moment s reflection will convince us that a molecule like structure [XVI] is monofunctional from the point of view of the Diels-Alder condensation. If the Diels-Alder reaction is to be used for the preparation of polymers, the reactants must be bis-dienes and bis-dienophiles. If the diene, the dienophile, or both are part of a ring system to begin with, a polycyclic product results. One of the first high molecular weight polymers prepared by this synthetic route was the product resulting from the reaction of 2-vinyl butadiene [XIX] and benzoquinone [XX] ... 

Standard-grade PSAs are usually made from styrene-butadiene rubber (SBR), natural rubber, or blends thereof in solution. In addition to rubbers, polyacrylates, polymethylacrylates, polyfvinyl ethers), polychloroprene, and polyisobutenes are often components of the system ([198], pp. 25-39). These are often modified with phenolic resins, or resins based on rosin esters, coumarones, or hydrocarbons. Phenolic resins improve temperature resistance, solvent resistance, and cohesive strength of PSA ([196], pp. 276-278). Antioxidants and tackifiers are also essential components. Sometimes the tackifier will be a lower molecular weight component of the high polymer system. The phenolic resins may be standard resoles, alkyl phenolics, or terpene-phenolic systems ([198], pp. 25-39 and 80-81). Pressure-sensitive dispersions are normally comprised of special acrylic ester copolymers with resin modifiers. The high polymer base used determines adhesive and cohesive properties of the PSA. 

Figure 23.3 The - bonding molecular orbitals of a conjugated erone (propenal) and a conjugated diene (1,3-butadiene) are similar in shape and are spread over the entire %< system.

Coulson, C. A., and Jacobs, J., Proc. Roy. Soc. London) A206, 287, Electronic levels in simple conjugated systems. II. Butadiene." Best possible molecular orbital is obtained. The idea is the same as that developed by Roothaan (1951). The work has been done quite independently with the similar work by Parr and Mulliken (1950). 

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