Phenanthrene, alkylation structures

Product distribution data (Table V) obtained in the hydrocracking of coal, coal oil, anthracene and phenanthrene over a physically mixed NIS-H-zeolon catalyst indicated similarities and differences between the products of coal and coal oil on the one hand and anthracene and phenanthrene on the other hand. There were differences in the conversions which varied in the order coal> anthracene>phenanthrene coal oil. The yield of alkylbenzenes also varied in the order anthracene >phenanthrene>coal oil >coal under the conditions used. The alkylbenzenes and C -C hydrocarbon products from anthracene were similar to the products of phenanthrene. The most predominant component of alkylbenzenes was toluene and xylenes were produced in very small quantities. Methane was the most and butanes the least predominant components of the gaseous product. The products of coal and coal oil were also found to be similar. The most predominant components of alkylbenzenes and gaseous product were benzene and propane respectively. The data also indicated distinct differences between products of coal origin and pure aromatic hydrocarbons. The alkyl-benzene products of coal and coal oil contained more benzene and xylenes and less toluene, ethylbenzene and higher benzenes when compared to the products from anthracene and phenanthrene. The gaseous products of coal and coal oil contained more propane and butanes and less methane and ethane when compared to the products of anthracene and phenanthrene. The differences in the hydrocracked products were obviously due to the differences in the nature of reactants. Coal and coal oil contain hydroaromatic, naphthenic, heterocyclic and aliphatic structures, in addition to polynuclear aromatic structures. Hydrocracking under severe conditions yielded more BTX as shown in Table VI. The yields of BTX obtained from coal, coal oil, anthracene and phenanthrene were respectively 18.5, 25.5, 36.0, and 32.5 percent. Benzene was the most... 

The most abundant aromatics in the mid-distillate fractions are di- and trimethyl naphthalenes. Other one and two ring aromatics are undoubtedly present in small quantities as either naphtheno- or alkyl-homologues in the Cn-C2orange. In addition to these homologues of alkylbenzenes, tetralin, and naphthalene, the mid-distillate contains some fluorene derivatives and phenanthrene derivatives. The phenanthrene structure appears to be favored over that of anthracene structure (Tissot and Welte, 1978 Speight, 1999). 

Within petroleum certain aromatic structures appear to be favored. For example, alkyl phenanthrenes outnumber alkyl anthracenes by as much as 100 1. In addition, despite the bias in the separation methods, the alkyl derivatives appear to be more abundant than the parent ring compounds. 

Fluorene has been reported to afford the 3,9a-dihydro product, but it is almost certain that this is the 2,4a-dihydro isomer (55 = 1) by analogy with biphenyl. 9,10-Dihydrophenanthrene (56) is reduced as expected to (55 n = 2), but spontaneously reverts to the starting material on standing. These systems do not require the presence of alcohol for reduction and it is consequently possible to alkylate the intermediate anions with alkyl halides, as (56) gives (57). These products are much more stable and structural analysis is simplified accordingly oxidation of the doubly allylic methylene occurs readily to afford the dienone (58 Scheme 7). Dienones of this type have potential as intermediates for the synthesis of natural products. Anthracene and phenanthrene are both readily reduced in the central ring to form the 9,10-di-hydro derivatives as might be expected, but to avoid further reduction it is necessary to have an iron salt present. Further examples are reviewed elsewhere. ... 

With azines the situation is varied. In the radical cations of pyridine and diazines the semi-occupied orbital is largely confined to the nn orbital(s) (see Scheme 2, structure 2), while the radical cation is of the n type with monoazanaphthalenes, -phenanthrenes and -anthracenes. The situation might change with substitution. As an example, alkylpyridine radical cations are of the n type, like the parent compound, whereas for the 2,5-dimethyl, 2-chloro, and 2-bromo derivatives the structure is of the n type [13]. Likewise, with benzo[c]cinnoline the parent compound and its alkyl derivatives give an n radical cation, but with some dimethoxy derivatives a n structure is found [14] and a switch from n to 7t structure occurs also in passing from 1,2,4,5-tetrazine to its 3,6-diamino derivatives [15]. 

It may be seen from the clear aromatic vibronic progression that the fluorescence spectrum is that of phenanthrene, the chromophore present in TMDBIO. This fluorescence, before trapping of the alkyl radicals, was suppressed by the spin-orbit coupling of the nitroxide group located on the iso-indoline framework as seen from its structure (Introduction). The dependence of the fluorescence on the nitroxide concentration may be seen in Figure 6. 

Over the last seventy years over sixty species of Aristolochia have been exploited for chemical examination by research groups throughout the world and a variety of compounds have been isolated. The spectrum of physiologically-active metabolites from Aristolochia species covers 14 major groups based on structure aristolochic acid derivatives, aporphines, amides, benzylisoquinolines, isoquinolones, chlorophylls, terpenoids, lignans, biphenyl ethers, flavonoids, tetralones, benzenoids, steroids, and miscellaneous. The aristolochic acid derivatives, host of phenanthrene derived metabolites were further classified into aristolochic acids, sodium salts of aristolochic acids, aristolochic acid alkyl esters, sesqui- and diterpenoid esters of aristolochic acids, aristolactams, denitroaristolochic acids, and aristolactones. The terpenoids can further be subdivided into 4 groups mono-, sesqui-, di- and tetraterpenoids. 

Only the last method, developed by Rapoport s group [95], is a versatile, chemoselective, and high-yielding. The method is accomplished by adding an alkyl nitrite (2 eq.) to a cold acetone solution of a Pschorr s amine substrate (1 eq.) and sulfuric acid (2 eq.) followed by sodium iodide. Here the iodide serves as a one-electron reductant, which converts an aryldiazonium salt to an aryl radical [95,96]. Then, the fast intramolecular arylation takes place with formation of the phenanthrene structure. While the older Pschorr methods gave very low yields, often under 20%, the Rapoport s method introduced significant improvements as the yields were 45-71% [95]. For example, polymethoxy compound 52 was converted to phenanthrene 53 in 71% yield [95], respectively. Scheme 22. 

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