. 2014 Nov 24;53(48):13115-20.

doi: 10.1002/anie.201406907. Epub 2014 Sep 26.

Dynamic mirror-symmetry breaking in bicontinuous cubic phases

Christian Dressel¹, Feng Liu, Marko Prehm, Xiangbing Zeng, Goran Ungar, Carsten Tschierske

Affiliations

PMID: 25257551
PMCID: PMC4501316
DOI: 10.1002/anie.201406907

Dynamic mirror-symmetry breaking in bicontinuous cubic phases

Christian Dressel et al. Angew Chem Int Ed Engl. 2014.

. 2014 Nov 24;53(48):13115-20.

doi: 10.1002/anie.201406907. Epub 2014 Sep 26.

Authors

Christian Dressel¹, Feng Liu, Marko Prehm, Xiangbing Zeng, Goran Ungar, Carsten Tschierske

Affiliation

¹ Institute of Chemistry, Organic Chemistry, Martin-Luther-University Halle-Wittenberg, Kurt-Mothes-Str. 2, 06120 Halle (Germany).

PMID: 25257551
PMCID: PMC4501316
DOI: 10.1002/anie.201406907

Abstract

Chiral segregation of enantiomers or chiral conformers of achiral molecules during self-assembly in well-ordered crystalline superstructures has fascinated chemists since Pasteur. Here we report spontaneous mirror-symmetry breaking in cubic phases formed by achiral multichain-terminated diphenyl-2,2'-bithiophenes. It was found that stochastic symmetry breaking is a general phenomenon observed in bicontinuous cubic liquid crystal phases of achiral rod-like compounds. In all compounds studied the Im3̄m cubic phase is always chiral, while the Ia3̄d phase is achiral. These intriguing observations are explained by propagation of homochiral helical twist across the entire networks through helix matching at network junctions. In the Ia3̄d phase the opposing chiralities of the two networks cancel, but not so in the three-networks Im3̄m phase. The high twist in the Im3̄m phase explains its previously unrecognized chirality, as well as the origin of this complex structure and the transitions between the different cubic phases.

Keywords: chiral isotropic liquid; conglomerate; deracemization; polycatenar liquid crystal; spontaneous chiral induction.

© 2014 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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Figures

formula image — **Figure 1**
a,b) Framework models of a unit cell of the two cubic structures discussed in this work[20] (see also Figures S15 and S16) and c) typical chemical structures of representative compounds forming these phases (compounds 2–4 were newly synthesized, as described in the SI, and compounds 5 and 6 were known from literature, see Table S1 and Figures S7–S9, S13, S14, S17–S22 for details.[19] a) The double-network ${Ia\bar 3d}$ (“gyroid”) phase; b) the triple-network ${{\it Im}\bar 3m}$ phase. Each of the infinite networks is coloured differently. In (b) the red and blue are the identical “inner” and “outer” networks, mutually related by a (1/2 1/2 1/2) translation; yellow is the “middle” network. Equivalent figures with the added minimum surface are shown in SI.

**Figure 2**
Photomicrographs of chiral domains (dark/bright), observed between slightly uncrossed polarizers. The orientations of polarizer (P) and analyzer (A) are indicated by arrows. a,b) ${{\it Im}\bar 3m}$ phase of compound 1 f at T=112 °C as obtained on cooling from the achiral Iso_HT phase, c) Iso_LT^[*] phase of compound 1 e (T=177 °C) and d) ${{\it Im}\bar 3m}$ phase (T=175 °C) as observed after transition from the Iso_LT^[*] phase; note that the domain boundaries between the chiral domains are slightly shifted. e,f) Growths of the domains of the ${Ia\bar 3d}$ phase at the Iso_LT^[*]-${Ia\bar 3d}$ transition as observed for compound 1 b at T=160 °C (white arrow indicates a seed of the ${Ia\bar 3d}$ phase); note that during formation of the cubic phase the chirality of the Iso_LT^[*] phase is completely extinguished (see also videos in SI).

**Figure 3**
a) Temperature dependent CD spectra (ellipticity in mdeg) of a bulk film of compound 1 g in the Cub^[*]/${{\it Im}\bar 3m}$ (120–125 °C) and the Iso_HT liquid (130–140 °C). On cooling back to the Cub^[*]/${{\it Im}\bar 3m}$ (dashed curves) chirality reverses. b) Helical conformations as computed for a model compound related to compounds 1 b,e with OCH₃ groups instead of the long alkyloxy chains.[23] c,d) DSC cooling thermograms of c) 1 c and 1 f with direct Iso_HT-Cub transitions and d) 1 d[23] and 1 e with an intermediate Iso_LT^[*] phase (see also Figures S1–S6).

**Figure 4**
a) The two networks (red and blue) of the ${Ia\bar 3d}$ phase decorated with schematic mesogens (rod-like molecular cores, green) showing the molecular twist along the network segments. The gyroid minimum surface is also shown (yellow) and b,c) show the network junctions. d) The same for the middle of the three networks of the ${{\it Im}\bar 3m}$ phase (yellow network in Figure 1 b). This network closely follows the Schwartz P-type minimum surface (shown in yellow). e) The middle ${{\it Im}\bar 3m}$ network shown as ribbons containing the molecular axes axis (black rods) and f) loop of 6 junctions in this network. g–j) Details of the two types of junctions in the ${{\it Im}\bar 3m}$ phase in mesogen (g,i) and ribbon (h,j) representations.

See this image and copyright information in PMC

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Dynamic mirror-symmetry breaking in bicontinuous cubic phases

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