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Induced handedness

A molecule may also lose mirror symmetry if the presence of the surface induces non-equivalence of otherwise identical groups. This is shown for the theoretical example of methane in tilted adsorption geometry (Fig. 8). Another example is the amino acid glycine, hi tilted geometry, it will become chiral on the surface [22], This surface-induced handedness, in turn, gives rise to four diastereomeric configurations for alanine on a surface (Fig. 9). [Pg.221]

Figure 4.6-13 Optical rotation q recorded as outlined in Fig. 4.6-12 Spectra of two differently concentrated solutions of S-tyrosine-methylester in the nematic mixture EBBA/MBBA (equimolar mixture of N-(p-ethoxybenzylidene)-p - -butylaniline and its methoxy analogue 2 of Table 4.6-1 Riedel-de Haen), left RCE (molar fraction x fa 0.024) related to the selective reflection band indicating pitch and handedness of the. structure, thus characterizing the chirality of the solute molecules by the helical twisting power right Sequence of ACE (,v se 0.0024, therefore the RCE should occur around 200 cm ) each of which indicates the induced handedness and therefore, discriminates enantiomers (Koite, 1978). Figure 4.6-13 Optical rotation q recorded as outlined in Fig. 4.6-12 Spectra of two differently concentrated solutions of S-tyrosine-methylester in the nematic mixture EBBA/MBBA (equimolar mixture of N-(p-ethoxybenzylidene)-p - -butylaniline and its methoxy analogue 2 of Table 4.6-1 Riedel-de Haen), left RCE (molar fraction x fa 0.024) related to the selective reflection band indicating pitch and handedness of the. structure, thus characterizing the chirality of the solute molecules by the helical twisting power right Sequence of ACE (,v se 0.0024, therefore the RCE should occur around 200 cm ) each of which indicates the induced handedness and therefore, discriminates enantiomers (Koite, 1978).
LIGHT-INDUCED HANDEDNESS INVERSION IN CHOLESTERIC LIQUID CRYSTALS... [Pg.154]

Ever since Pasteur s work with enantiomers of sodium ammonium tartrate, the interaction of polarized light has provided a powerful, physical probe of molecular chirality [18]. What we may consider to be conventional circular dichroism (CD) arises from the different absorption of left- and right-circularly polarized light by target molecules of a specific handedness [19, 20]. However, absorption measurements made with randomly oriented samples provide a dichroism difference signal that is typically rather small. The chirally induced asymmetry or dichroism can be expressed as a Kuhn g-factor [21] defined as ... [Pg.269]

Recently, a promising theoretical treatment was introduced by Ferrarini et al.22 which, in selected cases, leads to the effective calculation of the helical sense and pitch of the induced cholesteric phases.23 Attempts to relate the cholesteric handedness of lyotropic cholesterics to the helical sense of the polymers were first reported by Sato and co-workers.11... [Pg.431]

From a cholesteric induction experiment, one can obtain chiral information on the induced cholesteric (namely, pitch and handedness) and therefore the helical twisting power of the dopant in that solvent (at a certain temperature). If a model or molecular theory relating molecular chirality to mesophase chirality is available, one can infer stereochemical information about the dopant (absolute configuration, preferred conformation). [Pg.442]

As mentioned in the introduction, the first empirical correlation between the absolute configuration of dopants and the handedness of induced cholesterics was proposed in 1975.20 The first attempt to find a general correlation was a few years later Krabbe et al.58 related the sense of the cholesteric to a stereochemical descriptor of the dopant based on the effective volume of the substituents and listed many compounds following this rule. However, exceptions were described at that time,59 and, furthermore, this approach neglects the role of the structure of the nematic solvent in determining the sense of the cholesteric. It is well known that chiral compounds may induce cholesterics of opposite handedness in different nematics.60,61... [Pg.442]

The main factor in determining the handedness of the cholesterics induced by bridged 1,1 -binaphtliyls is the helicity (P or M) of the solute, and this observation is the basis of many configurational studies of chiral binaphthyls. All the homochiral (aP)-binaphthyls 15-19 have an M helicity of the core, and all induce, in biphenyl nematics, M cholesterics.65,75 By systematic structural variations of the covalent bridge, it is possible to obtain I J -binaphthalenes with dihedral angles ranging from 60° to 96° (see series 20-24) the handedness of the cholesteric phase always matches the helicity... [Pg.447]

In the held of thermotropic cholesterics, the most promising approach seems to be that reported by Nordio and Ferrarini22 23 for calculating helical twisting powers. It allows one to tackle real molecules with rather complex structures and to describe them in detail. The model is currently being extended to include a better description of nematic solvents and specific solute-solvent interactions. Once tested also for conformationally mobile molecules, this model could allow the prediction of the handedness of single-component cholesterics, and, in the held of induced cholesterics, very interesting information on solute molecules could be obtained. [Pg.452]

Another mechanism of chiral amplification that extends over an even larger scale has been reported by Huck et al. [119] The molecule 12-(9 H-thioxantbene-9 -yli-dene-12H-benzo[a]xanthene (Fig. 11.6), which has no chiral center, nevertheless exists, like the helicenes, in two chiral forms defined by their enantiomeric configurations. Consistent with the discussion in Section 11.2.3, a small net handedness (ca. 0.7 %) could be induced in racemic solutions of this molecule by use of ultraviolet CPL. However, introducing 20 wt% of this molecule, which contained a 1.5% chiral excess of one roto-enantiomer, into a nematic phase of liquid crystals produced macroscopic (100 pm) regions of a chiral cholesteric liquid crystal phase. The... [Pg.192]

Chiral crystals, like any other asymmetric object, exist in two enantiomorphous equienergetic forms, but careful crystallization of the material can induce the entire ensemble of molecules to aggregate into one crystal, of one-handedness, presumably starting from a single nucleus (Figure 2). However, it is not uncommon to find both enantiomorphs present in a given batch of crystals from the same recrystallization. [Pg.104]

We reasoned that chiral organic compounds with low ee induced by CPL can act as a chiral trigger in the enantioselective addition of z -Pr2Zn to pyrimidine-5-carbaldehyde, and that the subsequent asymmetric autocatalysis of pyrimidyl alkanol, formed in situ, amplifies its ee to produce highly enantioenriched pyrimidyl alkanol with an absolute configuration corresponding to that of the handedness of the CPL. [Pg.13]

Irradiation of racemic alkylidenecyclohexanone with CPL induces a small enantiomeric imbalance [79]. We found that chiral alkylidenecyclohexanones with low enantio enrichments trigger asymmetric autocatalysis to produce the highly enantioenriched pyrimidyl alkanol 12 with the absolute configuration corresponding to the handedness of the CPL (Scheme 12) [84],... [Pg.14]

A pro-chiral molecule may turn chiral after undergoing a symmetry breaking chemical reaction on a surface. An example where covalent bonds to surface atoms are formed is the reaction of frans-2-butene with Si(100) [30]. As with purely adsorption-induced chirality, the relative alignment of the prochiral reactant with respect to the surface plane determines the handedness of the adsorbate complex (Scheme la). [Pg.222]

The coadsorption of chiral molecules into racemic layers is an efficient way to induce further asymmetrization towards single handedness. While in heterogeneous chiral catalysis the stationary ratio of modifier and reactant at the surface is assumed to be one, a small amount of chiral dopant can be sufficient for induction of homochirality on the entire surface SU on Cu( 110), for example, forms two enantiomorphous domains in its bisuccinate phase [27]. [Pg.245]

Recently, the importance of the structure of chiral metal complexes on the handedness of the mesophases induced in a nematic LC was exemplified [114]. The chiral metal complexes 10 and 11—in which the alkyl substituents are aligned almost perpendicularly to the C2 axis in the former and parallel in the latter—show very different induction phenomena. Not only are the induced helicities in the nematic LC of opposite sense for the two compounds, but the helical twisting power of 10 is much higher than that of 11. The reason for these differences is the way in which the molecules are incorporated into the host nematic phase and exert their force upon it to create the twist between the layers. [Pg.270]

See other pages where Induced handedness is mentioned: [Pg.337]    [Pg.153]    [Pg.156]    [Pg.304]    [Pg.337]    [Pg.153]    [Pg.156]    [Pg.304]    [Pg.231]    [Pg.325]    [Pg.202]    [Pg.388]    [Pg.410]    [Pg.419]    [Pg.427]    [Pg.431]    [Pg.446]    [Pg.451]    [Pg.506]    [Pg.180]    [Pg.185]    [Pg.191]    [Pg.193]    [Pg.55]    [Pg.171]    [Pg.160]    [Pg.70]    [Pg.148]    [Pg.168]    [Pg.212]    [Pg.193]    [Pg.219]    [Pg.231]    [Pg.243]   
See also in sourсe #XX -- [ Pg.337 ]



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Handedness

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