Hale
Ocak
*ab,
Belkız
Bilgin Eran
a,
Sevgi
Nuray
a,
Aykun
Özkonstanyan
a,
Silvio
Poppe
b and
Carsten
Tschierske
*b
aDepartment of Chemistry, Yildiz Technical University, Davutpasa Yerlesim Birimi, Esenler, TR-34220, Istanbul, Turkey
bInstitute of Chemistry, Organic Chemistry, Martin Luther University Halle-Wittenberg, Kurt-Mothes-Str. 2, D-06120 Halle, Germany. E-mail: hocak@yildiz.edu.tr; carsten.tschierske@chemie.uni-halle.de
First published on 11th January 2021
4-Cyanoresorcinol based bent-core compounds combining one branched chiral with one achiral linear end-chain have been synthesized in enatiomerically pure and one compound also in racemic form. All homochiral compounds form a chiral cybotactic nematic phase at relatively low temperature with a selective reflection ranging from the near IR to near UV. For the compound with the longest chains superparaelectric and antiferroelectric switching smectic phases were observed, whereas the corresponding racemate is non-polar. This is attributed to sterically induced polarization by the denser packing of uniform enantiomers due to chirality synchronization of the helical conformers. For the racemic mixture this chirality synchronization requires additional surface stabilization. There are unprecedented effects of an applied magnetic field (1 T) on the LC phases, leading to a layer shrinkage by 6–13% for the enantiomer and a layer expansion by 5–8% for the racemate. It is proposed that the magnetic field couples with the π-systems of the almost rod-like molecules. For the racemate this increases the core order, whereas for the enantiomer the reduction of the heliconical twist is considered to provide the major effect. These magnetic field effects could lead to new applications of chiral LC materials at the cross-over between rod-like and bent shapes.
Scheme 1 Molecular structures of the 4-cyanoresorcinol based bent-core compounds 1/n and 2/n under discussion, and the related symmetric compounds 418 with two linear alkyl chains and with two chiral chains (323); R* represents a branched chiral carbon chain, explained at the bottom; for space filling models of compounds 2, see Fig. S25 (ESI†) and for phase sequences and transition temperatures, see Table 1 and Table S4 (ESI†). |
Fig. 1 Distinct modes of chirality in LC phases. (a–c) Permanent molecular chirality leads to a bias of the helical twist of the conformers, shown in (b), which induces either (a) a longitudinal twist in an oblique helicoid (heliconical) structure or (c) a transversal twist in a right-angled helicoid (helocoidal) structure. (d) In the lamellar phases of achiral bent-core molecules the combination of polar order, tilt and layer normal define a right- or left-handed system, providing an additional source of chirality (see also Fig. S35, ESI†). |
Heliconical phases with a much longer pitch of the longitudinal twist are known for tilted smectic phases (SmC*) of permanently chiral rod-like molecules,35–38 whereas related chiral nematic phases (N*, cholesteric) have a helicoidal (transversal) twist (Fig. 1c).39–42 Chirality and helicity have a major impact on the structure and the material properties of LCs and lead to numerous applications, for example in optics, electro-optics and photonics.2,39,41,46 Moreover, geometric frustration arises by helicoidal twist developing in different spatial directions (blue phases41,43–45) or by competition between helicoidal twist and long range lamellar order (e.g. twist grain boundary phases = TGB phases).8,39,41,46–49 Though chirality effects have been well studied for rod-like LCs and their dimeric,49 oligomeric and polymeric analogs,50,51 the investigation of chiral bent-core mesogens has much less been conducted and comparisons between enantiomerically pure compounds and their racemic mixtures are especially rare.52–68 Molecular chirality can be incorporated into the bent-core molecules by the introduction of asymmetric carbon centers in the terminal chains.52–59 In some cases the presence of a chiral moiety induces the emergence of the conventional chiral LC phases known from rod-like molecules such as cholesteric,60 and blue phases (BPI-BPIII),61,62 as well as chiral smectic23 and TGB phases.63,64 In other cases it has no influence on the mesophase type, as for example in the modulated smectic (B1) phase of biphenyl based bent-core molecules.63,68 A series of several new helical superstructures were found for nematic phases of chiral bent dimesogens (NTB*).49 An important question concerns the transition from the right-angle helicoidal structure as known from the classical cholesteric N* phases of ordinary rod-like molecules, having transversal twist (see Fig. 1c), to the oblique helicoidal (=heliconical) nematic phases, having longitudinal twist (Fig. 1a), as known for the NTB phases.65 The latter are formed by bent molecules with small or negative twist elastic constant K33. This transition from helicoidal to heliconical twist in a nematic phase was recently achieved by mixing a spontaneous mirror symmetry broken NTB phase with an ordinary cholesteric phase.65 The development of transversal twist is also likely to be distorted and the development of longitudinal twist is supported by the development of lamellar SmCs*-clusters in the cybotactic nematic phases at the transition to the SmCs* phases.
In previous work we have investigated several series of 4-cyanoresocinol based bent core mesogens showing a wide variety of LC phases at the transition from nematic to smectic16 and from non-polar to polar LC phases.66 Moreover, they show a series of spontaneous mirror symmetry broken LC phases, involving superparaelectric SmCsPR[*] phases67 and heliconical smectic phases (SmCsPhelF).21,22,25–27 As a consequence, the question arose in how far the transient chirality of these spontaneously chiral phases can be affected by a permanent molecular chirality. In previous work we have introduced two stereogenic centers, which lead to highly chirality frustrated BPIII phases with high Kerr constants, replacing the nematic phase,23,24 and diastereomerism between layer chirality and molecular chirality in the smectic phases.23,59 Here we use only one stereogenic center, assuming to have smaller steric and chirality effects, to find new structures and effects by the interplay of these two sources of chirality, especially concerning the transition from transversal (helicoidal) to longitudinal (heliconical) twist (Fig. 1a–c).
In the lamellar phases of bent-core molecules the development of polar order leads to superstructural layer chirality (see Fig. 1d and Fig. S35, ESI†),3 providing an additional source of chirality. This layer chirality can assume diastereomeric relations with the permanent molecular chirality as well as with the spontaneously formed or chirality induced helicoidal and heliconical superstructures,8,17,22,23,59,63,68,69 leading to geometric frustration and the development of complexity in their self-assembly.8,51,70
Whereas electric field effects on the LC phases of bent-core molecules are well studied and understood,3–7 magnetic field effects are much less investigated, mainly for paramagnetic compounds.71,72 Investigation of diamagnetic bent-core mesogens under the magnetic field was focused on the stabilization of nematic phases and attempts to induce phase biaxiality.73–77 Magnetic fields up to 25 T were also found to suppress the onset of the BPIII phase of chiral bent-core mesogens by almost 1 K,78 as well, the helical pitch in cholesteric phases was tuned.79 Similarly, the heliconical and helicoidal superstructures in SmC* and TGBC* phases of chiral rod-like mesogens80,81 were shown to be fully or partly removed under a sufficiently strong magnetic field. However, all these effects on diamagnetic LCs are very small or require high magnetic field strength.
Herein, we report a unique and unexpectedly strong effect of an applied magnetic field on the layer spacing of SmC and SmC* phases of chiral bent-core molecules. There is a huge effect of a relatively weak magnetic field of only 1 Tesla providing a change of the layer spacing by up to 13%, and surprisingly, the effect of the applied field is opposite for the racemate and the pure enantiomer. The newly designed, synthesized and investigated compound showing this phenomenon represents a member of a series of non-symmetric bent-core molecules derived from a 4-cyanoresorcinol central unit. In these compounds (S)-1/n, (S)-2/n and rac-2/12 (Schemes 1 and 2) a (S)-2-methylbutoxy or (S)/rac-3,7-dimethyloctyloxy substituted phenylbenzoate based rod-like wing is attached in ortho-position besides the CN group of the central 4-cyanoresorcinol derived core, and a linear n-alkoxy chain (RCnH2n+1, n = 6–12) is positioned at the phenylbenzoate unit in para-position to CN at the opposite side (Scheme 2).
Scheme 2 Synthesis of 4-cyanoresorcinol-based chiral bent-core molecules ((S)-1/n, (S)-2/n and rac-2/12). Reagents and conditions: (i) DCC, DMAP, dry CH2Cl2, 20 °C; (ii) Pd/C-10%, THF, 40 °C; (iii) (1) (COCl)2, (2) dry pyridine, dry CH2Cl2 (for details, see ESI†). |
The racemic compound rac-B was prepared in a similar way starting from racemic 3,7-dimethyl-1-octanol as described previously.23 The 4-(4-n-alkyloxybenzoyloxy)benzoic acids90,91Fn (n = 6, 8, 10, 12) were prepared starting with appropriate alkyl bromides by using the same procedures as described the above.92 4-Benzyloxy-2-hydroxybenzonitrile C was prepared from commercially available 4-benzyloxy-2-hydroxybenzaldehyde by the formation of the oxime, followed by dehydration as previously reported.16,64 The acylation of C first with the chiral or racemic benzoyloxybenzoic acids (S)-A, (S)-B or rac-B followed by hydrogenolytic debenzylation and acylation with the appropriate benzoic acid Fn leads to the target compounds (S)-1/n, (S)-2/n and rac-2/12 which were purified by column chromatography on silica gel using chloroform as eluent and recrystallized from ethanol. Detailed synthesis procedures and analytical data are given in the ESI.† Identical chemical structures of (S)-2/12 and its racemate rac-2/12 were confirmed by NMR investigation (Fig. S21–S24, ESI†), MS and thin-layer chromatography (for details, see ESI†).
X-ray investigations were carried out at Cu-Kα line (λ = 1.54 Å) using a standard Coolidge tube source with a Ni-filter. Non-aligned samples were prepared on a glass slide while aligned samples were prepared in a glass capillary. All samples were slowly cooled (rate: 0.1 K min−1) from the isotropic liquid phase to the mesophase. Alignment was achieved by cooling the sample under an applied magnetic field of ∼ 1 T (direction of the magnetic field is perpendicular to the X-ray beam) to the measuring temperature. The samples were held on a temperature-controlled heating stage and the diffraction patterns were recorded with a 2D detector (Vantec 500, Bruker); exposure time was 15–30 min. For the wide-angle X-ray scattering (WAXS) measurement the distance between the sample and the detector was defined to be 9.0 cm; for small-angle X-ray scattering (SAXS) measurement the distance is 26.9 cm. The obtained XRD patterns were transformed into 1D plots over the full Chi-range by using GADDS. For the calculation of the d-values and the line width (full width at half maximum = FWHM) of the magnetically aligned samples of rac-2/12 (B = 1 T) and of unaligned samples of (S)-2/12 (B = 0 and 1 T) and rac-2/12 (B = 0 T) different techniques were used to obtain comparable results. For the unaligned powder-like samples the integration of the signal was performed over the whole χ-range. For the aligned sample of rac-2/12, especially in the nematic phase, this integration technique cannot be used due to the dumbbell-like shape of the scattering (see Fig. 9a further below). In this case we performed an integration only over the χ-range for the scattering maxima. The mean average of all four scattering maxima was taken for the construction of the plots discussed in Section 3.5.
Electro-optical investigations were performed in a 10 μm polyimide (PI) non-coated ITO cell (EHC, Japan) with a measuring area of 1 cm2. The cell was filled in the isotropic liquid phase. Switching experiments were carried out with the triangular-wave method using a combination of a function synthesizer (Agilent, model 33220A, load was set to 10 kΩ), an amplifier (Tabor electronics, model 9400), and the current response traces were recorded using an oscilloscope (Agilent, model DSO3202A) across a 5 kΩ resistance.
Compd. | R* | R | T/°C [ΔH/kJ mol−1] |
---|---|---|---|
a Peak temperatures and enthalpy values (in italics in brackets) taken from the 2nd heating and cooling scans at a rate of 10 K min−1; abbreviations: Cr = crystalline phase (for compounds with multiple Cr-Cr transitions and stepwise melting, see for example Fig. 2, only the melting transition at highest temperature is given); Iso = isotropic liquid phase; NCybC* = chiral nematic (cholesteric) LC phase composed of SmCs layer fragments (skewed cybotactic chiral nematic phase); SmCs = tilted smectic phase with uniform tilt direction in adjacent layers (synclinic tilt); SmCs′ = SmCs phase with enhanced packing density; SmCs* = chiral SmCs phase; SmCsPAR* = paraelectric phase with antiferroelectric like response; SmCsPA* = antiferroelectric switching chiral SmCs phase; for DSC traces, see Fig. 2, 5 and Fig. S29; for textures, see Fig. 3, 6, 7 and Fig. S30–S33; a comparison with related achiral compounds and compounds with two chiral chain is given in Table S4 (ESI). b Partial crystallization. c It is unknown if this is a polar or nonpolar SmCs phase. | |||
(S)-1/6 | (S)-2-Methylbutyl | C6H13 | H: Cr 85 [25.4] NCybC* 111 [0.7] Iso |
C: Iso 109 [−0.5] NCybC* 52 [−3.3] Crb | |||
(S)-1/8 | (S)-2-Methylbutyl | C8H17 | H: Cr 82 [29.1] NCybC* 112 [0.5] Iso |
C: Iso 110 [−0.5] NCybC* 43 [−4.2] Crb | |||
(S)-1/10 | (S)-2-Methylbutyl | C10H21 | H: Cr 85 [38.2] NCybC* 105 [0.3] Iso |
C: Iso 103 [−0.6] NCybC* 35 [−22.1] Cr | |||
(S)-1/12 | (S)-2-Methylbutyl | C12H25 | H: Cr 81 [42.6] NCybC* 107 [0.8] Iso |
C: Iso 105 [−0.8] NCybC* 47 [−22.9] Cr | |||
(S)-2/6 | (S)-3,7-Dimethyloctyl | C6H13 | H: Cr 69 [22.6] NCybC* 86 [0.4] Iso |
C: Iso 85 [−0.4] NCybC* 27 [−3.2] Crb | |||
(S)-2/8 | (S)-3,7-Dimethyloctyl | C8H17 | H: Cr 86 [39.1] NCybC* 106 [0.7] Iso |
C: Iso 104 [−0.7] NCybC* 52 [−4.3] Crb | |||
(S)-2/10 | (S)-3,7-Dimethyloctyl | C10H21 | H: Cr 72 [21.2] NCybC* 96 [0.7] Iso |
C: Iso 95 [−0.7] NCybC* 51 [−0.9] SmCs*c < 10 Cr | |||
(S)-2/12 | (S)-3,7-Dimethyloctyl | C12H25 | H: Cr 69 [16.1] SmCs* 93 [0.1] NCybC* 107 [1.6] Iso |
C: Iso 106 [−1.7] NCybC* 92 [−0.1] SmCs* 62 [—] SmCsPAR* 53 [0.2] SmCsPA* 35 [−0.8] Crb | |||
rac-2/12 | rac-3,7-Dimethyloctyl | C12H25 | H: Cr1 60 [17.1] Cr2 72 [1.4] SmCs 97 [0.1] NCybC 110 [1.6] Iso |
C: Iso 108 [1.7] NCybC 94 [0.1] SmCs 54 [0.2] SmCs′ 33 [1.1] Crb |
Fig. 2 DSC thermograms of (S)-2/10 on 2nd heating and cooling (10 K min−1); for the DSC traces of the other compounds (S)-1/n and (S)-2/n, see Fig. S29 (ESI†). |
Fig. 3 Textures of (S)-2/12 as observed between crossed polarizers on cooling from NcybC* to SmCsPA* at the given temperatures in the indicated phases; (a)–(f) show the change of the selective reflection in the cholesteric phase range, being in the near UV range in (a) and in the near IR in (f); (h) was obtained after shearing the sample shown in (g); (i) was observed after spontaneous transition to the optically isotropic homeotropic texture (the small regions) with a bit higher birefringence are residues of the texture in (g); for more details of the transition g → j, see Fig. S33 (ESI†). |
Despite of the significant cybotaxis, these chiral nematic phases behave like ordinary orthogonal helicoidal chiral nematics with transversal twist and the pitch developing perpendicular to the substrate surfaces (Fig. 3a–f). The transition to a heliconical structure appears to be associated with the NCybC*–SmCs* transition (Fig. 3f–h), meaning, that the effects of molecular bent and cluster formation are obviously not sufficient to induce a helicoidal → heliconical transition within the nematic phase range. Nevertheless, for the long chain compounds (S)-10 and (S)-12 with additional smectic phases, the helicoidal twist could be reduced upon approaching the SmC* range, which is likely to contribute to the strong increase of the selective reflection wave length (Fig. 3a–f). Moreover, there appear to be surface alignment effects, so that different textures can be observed for the chiral nematic phase of these long-chain compounds, one of them being surface induced with low birefringent (gray) fan texture of heliconical smectic surface layers (SmCs*, see Fig. S30f, ESI†), coexisting with the selective reflecting helicoidal chiral nematic phase (NCybC*) of the bulk material (Fig. S30f and g, ESI†).
Fig. 4 (a) SAXS and (b) WAXS pattern of the NCybC* phase (60–90 °C) and the SmCs* phase (50 °C) of compound (S)-2/10, measured under a magnetic field of 1 T (no magnetic field effect on the d spacing is observed in this case, see Fig. S26; for additional data, see Table S1, ESI†). |
The intensity of the SAXS increases almost continuously and the width decreases with lowering temperature, indicating a continuously growing size of the cybotactic clusters. At the phase transition around 52 °C the diffuse SAXS becomes a sharp peak, associated with a jump of the d-value from around 4.2 nm in the cholesteric phase to 3.6 nm in the smectic phase (Fig. 4, Fig. S26 and Table S1, ESI†). No additional diffraction peaks can be found besides the SAXS and therefore we attribute it to a layer reflection of a smectic phase.
A tilted organization of the molecules in the cybotactic clusters of the nematic phase (NCybC*) and in the smectic phase (SmCs*) can be deduced from the difference between molecular length (Lmol = 5.4 nm for 2/10) and the recorded d-spacings (d = 3.6–4.4 nm, see Table S1 and Fig. S26, ESI†). Additional confirmation is provided by investigation of aligned samples of the racemate of the next homologue (rac-2/12), as described further below. The smectic phase of compound (S)-2/10 was only observed on cooling as a monotropic LC phase and therefore could not be investigated in more detail due to crystallization and presently it cannot be decided if it is a polar or non-polar SmCs* phase. The next even numbered homologue (S)-2/12 has an enantiotropic SmCs* range, and therefore, the following detailed investigations were focused on (S)-2/12 and its racemic mixture rac-1/12.
The two phase transitions in the LC range are also visible by textural investigations of planar (Fig. 6a–d, left column) as well as homeotropic samples of the corresponding racemate rac-2/12 (Fig. 6e–g, right column). On cooling the planar aligned sample of the nematic phase (planes of the cybotactic clusters are perpendicular to the cell surfaces) the fan-like texture of a smectic phase develops at the transition around 94 °C, (Fig. 6a and b). This is immediately followed by the emergence of tilt domains, indicated by dark domains, at 58 °C having their maximum darkness if inclined by ∼30° with respect to the orientation of polarizer and analyzer (Fig. 6c). This is in line with a model where the tilt randomized SmCs clusters in the NCybC phase grow in coherence length, thus forming layers at the NCybC to SmCs transition. Immediately below this transition the phase appears almost SmA-like, i.e. without the typical tilt domains (see Fig. 6b and c) and on further cooling the tilt domains become clearly visible (Fig. 6c). It appears that close to the NCybC to SmCs transition the tilt correlation is weak or heliconical, and that it becomes uniformly synclinic with lowering temperature. The next transition at 54 °C is associated with another textural change (SmCs → SmCs′ transition, Fig. 6c and d) due to the further increasing packing density (see below).
Fig. 6 Textures of the (a–d) planar aligned (6 μm polyimide coated ITO cell, R is the rubbing direction) and (e–g) homeotropic samples (between non-treated microscopy glass plates) of the racemate rac-2/12 as observed on slow cooling (5 K min−1) from the isotropic liquid phase into the distinct phases at the indicated temperatures; for additional textures at other temperatures, see Fig. S31 (ESI†). |
The homeotropic aligned NCybC phase of rac-2/12 (Fig. 6e) appears almost optically isotropic with only weak birefringence, the latter we attribute to thin surface layers with the tilted layers pinned to the surface. This is in line with a completely randomized tilt direction of the cybotactic SmCs-like clusters in the NCybC phase and an alignment of these clusters parallel to the substrate surfaces. At the NCybC to SmCs transition at 94 °C bright domain boundaries develop, though the texture remains almost isotropic (Fig. 6e and f). This means that despite of the tilt, the birefringence remains very small, which might be due to a persisting tilt randomization or a developing heliconical superstructure. Upon approaching the next phase transition at 54 °C the birefringence in the homeotropic texture increases considerably, indicating the transition to a significantly tilted smectic phase with uniform tilt-correlation (SmCs′, Fig. 6f and g).
Fig. 7 Chiral domains as observed in the SmCs phase of rac-2/12 at T = 90 °C as (b) observed between crossed polarizers and (a and c) with the analyzer slightly rotated (a) in clockwise and (c) in counter clockwise direction. That the brightness of the domains does not change by rotating the sample between crossed polarizers is shown in Fig. S32 (ESI†). |
Similar spontaneously formed chiral domains in SmCs phases of achiral bent-core mesogens have previously been reported for the paraelectric SmCsPR[*] phases67 and were also observed in some cybotactic nematic phases of bent-core mesogens (NCybC[*]).8,97,98 These spontaneous mirror symmetry broken LC phases of achiral bent-core molecules result from a combination of different effects, among them a small or negative twist elastic constant,99 surface pinning effects97 and a high degree of helicity of the molecular conformations.6–8 However, the spontaneous formation of chiral domains in a SmCs phase of a racemic mixture is according to our knowledge, reported here for the first time. It is a bit surprising, because uniform helical self-assembly in the domains leads to energetically different states for the permanently chiral (R)- and (S)-enantiomers. A spontaneous separation of the enantiomers would be diffusion controlled and therefore expected to be a slow process, whereas chirality synchronization of transiently chiral molecules in LC helical superstructures is known to be fast.8,98 Nevertheless, the domain formation appears to be rapid and therefore it is assumed that the diastereomeric coupling between the permanent and transient molecular and supramolecular chirality is only weak8 and the synchronization of the transient chirality is dominating.
Upon approaching the next phase transition at 54 °C the birefringence in the homeotropic texture increases significantly, indicating the transition to a helix-free SmCs′ phase (Fig. 6g). Thus, there are heliconical superstructures in the SmCs ranges of the enantiomer as well as of the racemate of 2/12, in the first case being uniform and supported and biased by the permanent molecular chirality and in the second case as a conglomerate resulting from the spontaneous local chirality synchronization. In both cases the transition to the low temperature mesophase around 52–54 °C is associated with a loss of the helical self-assembly.
It appears that in the SmCs* range between 62 and 92 °C a paraelectric switching of polar domains takes place, whereas below 53 °C, i.e. in the SmCs′ range of rac-2/12, a B2-like antiferroelectric switching SmCsPA* phase develops for (S)-2/12. Upon approaching the SmCsPA* phase the switching in the paraelectric SmCs phase changes at 62 °C from a single peak type (SmCsPR*-like range) to a double peak type (SmCsPAR* range) with growing size of the polar clusters. This means that with lowering temperature the growing steric polarization of the bent molecules induces a transition from paraelectric via superparaelectric switching of polar domains to an antiferroelectric switching of the polar layers.66 At a certain critical domain size, reached below 62 °C, the synpolar correlation of the domains changes to an antipolar. Thus, the observed sequence on cooling is NCybC*–SmCs*–SmCsPAR*–SmCsPA*.
Optical investigation under an applied DC field indicate no effect of the electric field on the optical textures of the SmCs and SmCs′ phases of the racemate rac-2/12. Investigation of the enantiomerically pure compound (S)-2/12 shows that under the applied E-field the extinctions in the planar samples are inclined with the directions of polarizer and analyzer, confirming a synclinic tilted SmCsPF-like state (Fig. 8b and d). Between 92 and 63 °C this field-induced state relaxes back to a nonspecific texture (Fig. 8c) due the distortion caused by the helix developing after switching off the applied electric field (helielectric switching37). Below 62 °C the fan texture is retained after switching off the applied field (Fig. 8e). This means that the helix is permanently removed and only a change of the birefringence is observed, whereas the fan texture and the orientation of the extinctions in this texture do not change (Fig. 8d and e). It is concluded that the structure at 0 V is synclinic, too, but assumes an antiferroelectric polar correlation between the layers and hence it is SmCsPA in the ground state (Fig. 8g). This means that a SmCsPA ↔ SmCsPF switching takes place by rotation around the molecular long axis (Fig. 8f and g).
The tilted organization of the molecules in polar layers leads to a superstructural chirality of the layers, where polar direction, tilt direction and layer normal define either a right-handed or a left-handed Cartesian coordinate system (see Fig. 1d and Fig. S35, ESI†). Stacking layers with uniform chirality leads to the homochiral SmCsPF and SmCaPA structures, whereas stacking of layers with alternating chirality leads to racemic SmCsPA and SmCaPF structures (Fig. S35, ESI†).3 The observed formation of a polar smectic phase with racemic layer structure (SmCsPA), and the switching process taking place by rotation around the long axis, thus inverting the layer chirality (chirality flipping), indicate that the coupling between permanent molecular chirality and this superstructural layer chirality is only weak for (S)-2/12.21,22 Nevertheless, the emerging antipolar correlation, leading to a local or long range racemic SmCsPA structure below 62 °C and 53 °C, respectively, disfavors the helix formation, so that below 62 °C the heliconical structure becomes unstable. Hence, the tendency to assume an antipolar organization with racemic structure is likely to be responsible for the loss of (chirality induced or spontaneous) heliconical self-assembly at the transition from SmCs*/SmCs to the low temperature smectic phases (SmCsPA*/SmCs′) of (S)-2/12 and rac-2/12, respectively.
Comparison of (S)-2/12 with the racemate rac-2/12 shows that uniform molecular chirality, allowing a denser packing of the molecules, is required for development of polar order in the smectic phases of this series of compounds. The polarization and the increasing contribution of the antipolar correlation between the synclinic tilted layers at reduced temperature are considered as resulting from a change of the molecular shape from being only weakly to more strongly bend. Thus, the polar switching is dominated by the steric induced polar order of the bent molecules, increasing with lowering temperature, and not directly caused by the reduced phase symmetry due to the permanent molecular chirality.59 If polar order would be due to the reduction of the phase symmetry, as in the case of SmCs* phases of rod-like molecules (C2h → C2), then ferroelectric switching by precession on a cone would be expected for these synclinic tilted smectic phases39,41 instead of the actually observed switching by rotation around the long axis. The rotation around the long axis also indicates that the achieved packing density is even in the SmCsPA* phase of (S)-2/12 not sufficient to suppress this mode of switching. For the racemate rac-2/12, the sterically induced polar order in the SmCs′ range is even insufficient to produce any polar switching because of the weaker chirality synchronization in the absence of the permanent chirality is incapable of providing the required packing density to achieve a significant polar domain size. Therefore, a transition from preferred synpolar to preferred antipolar domain correlation at the SmCs–SmCs′ transition of rac-2/12 is likely, but cannot be confirmed by electro-optical investigations.
Fig. 9 (a and b) 2D XRD patterns of (a) the NCybC phase of compound rac-2/12 at T = 100 °C and (b) the NcybC* phase of compound (S)-2/12 at T = 100 °C, both recorded under a magnetic field of ∼1 T; the arrows indicate the direction of the applied magnetic field; (c) χ-scans over the SAXS range (1–3°) of the diffraction patterns of the magnetically aligned rac-2/12 at the indicated temperatures with (d) numerical values of the tilt angles calculated from the χ-scans (βexp) and from the layer spacing (βcalc) according to cosβcalc = d/Lmol (with Lmol = 5.7 nm); (e) shows the alignment of the molecules and the cybotactic SmCs-clusters in the magnetic field; for more details, see Fig. S28 (ESI†). |
The tilt angle in the cybotactic clusters of the NCybC phase of rac-2/12, corresponding to the χ-angle between the scattering maxima and the meridian is βexp = 19 ± 3° in the nematic phase at 100 °C and remains almost unchanged in the SmCs-range down to 70 °C. The tilt increases upon approaching the transition to the SmCs′ phase (25 ± 3° at 60 °C) and reaches 32 ± 3° in the SmCs′ phase at 50 °C (see Fig. 9d and Fig. S28, ESI†). The measured d-value of the SAXS in the SmCs phase at 90 °C is d = 4.56 nm, which according to cosβ = d/Lmol (Lmol = 5.7 nm in a conformation shown in Fig. S25 (ESI†) with 120° bend of the aromatic core and stretched alkyl chains), would lead to an almost doubled tilt angle of βcal = 37° (Fig. 9d) compared to βexp = 19 ± 3°. This means that the effective molecular length (Leff), as calculated from the measured tilt angle and the layer spacing is only 4.7 nm, which is much shorter than the measured value of Lmol = 5.7 nm (Fig. S25b, ESI†) due to conformational disorder or alkyl chain intercalation. Remarkably, the growing tilt starting at ∼60 °C does not lead to a reduction of the birefringence in the planar samples (Fig. 6b–d and Fig. S31, ESI†), meaning that the development of the tilt is accompanied by a simultaneously increasing orientational order parameter. Overall, the NCybC–SmCs transition is associated with an increase of the correlation length of the NCybC clusters, while the tilt is retained; the transition SmCs–SmCs′ is associated with the restriction of the rotation around the molecular long axis, leading to an increase of the tilt due to the denser core packing.
For the enantiomer (S)-2/12 the SAXS forms a closed diffuse ring due to the distortion provided by the helicoidal organization of the homogeneously chiral molecules in the NCybC* phase (Fig. 9b). This means, that due to the helicoidal superstructure, no sufficient alignment is achieved under the magnetic field and that the applied field cannot remove the helicoidal twist completely.
Fig. 10 Temperature dependence of the d-values of the SAXS (black) and WAXS maxima (blue, see also Fig. S27, ESI†) of (a) rac-2/12 and (b) (S)-2/12 as measured on cooling either without applied magnetic field (triangles) or under the magnetic field of 1 T (dots). For (S)-2/12 the investigation could only be conducted down to 60 °C, due to crystallization, see also the comment in footnote;100,101 for numerical data, see Tables S2 and S3 (ESI†). |
It appears that for the racemate rac-2/12 there are two competing effects on the layer distance, one is the growing correlation length of the lamellar ordering (transition from diffuse to Bragg-like scattering), shifting the d-spacing to larger values and another one reducing the d-spacing. The latter could be due to a growing tilt, an increasing alkyl chain intercalation or an increasing conformational disorder of the alkyl chains upon lowering temperature. As the alkyl chain disorder is known to decrease with lowering temperature and the measured tilt does not change significantly down to ∼60 °C (see Fig. 9d) it is concluded that chain intercalation provides the major effect causing the decreasing d. For the pure enantiomer (S)-2/12 the chirality in the SmCs* phase apparently inhibits this layer shrinkage, and hence, the alkyl chain intercalation at reduced temperature.
Though the development of the d-spacing of the SAXS is very different for rac-2/12 and (S)-2/12, there is almost no effect of chirality on the d-value of the diffuse WAXS maximum (blue triangles in Fig. 10a and b). In both cases there is a continuous decrease of the d-value with lowering temperature without recognizable effect of the phase transitions, in line with the almost continuously growing packing density. If there is any difference between the d = f(T) curves of (S)-2/12 and rac-2/12 or any effect of an applied magnetic field on these curves is difficult to say as the differences are very small (Δd < 0.003 nm) and thus within the range of instrumental error.101 It appears that at fixed temperature any decrease of the packing density is compensated by additional intercalation.
In Fig. 11a the development of the line width (FWHM) of the SAXS, which is inversely proportional to the correlation length (ξ) of the cybotactic clusters, is compared for (S)-2/12 (red dots) and rac-2/12 (green triangles). The scattering is diffuse in the isotropic liquid phase and the correlation lengths is almost the same for rac-2/12 and (S)-2/12. Slightly above the Iso(*)–NCybC(*) phase transition at 110 °C it is in both cases around ξ = 16 nm, corresponding to clusters of about three layers. The FWHM becomes smaller and the correlation length ξ increases at the transition to the nematic phase. On further cooling the development of the FWHM becomes different for (S)-2/12 and rac-2/12. For the racemic mixture there is an almost linear decrease of FWHM between 120 and 70 °C (Fig. 11a, green) with a relatively small step at the Iso–NCybC* transition around 108 °C. For the (S)-enantiomer a significant jump to smaller values takes place already around the Iso-NCybC* transition (Fig. 11a, red). This indicates an increased size of the cybotactic clusters in the NCybC* phase of the homochiral compound (ξ ∼ 30 nm at 100 °C) compared to the NCybC phase of the racemic mixture (ξ ∼ 20 nm at 100 °C). The jump in line width confirms the formation of almost infinite layers at the NCybC*–SmCs* transition of (S)-2/12, whereas the smooth change of d at the NCybC–SmCs transition of rac-2/12 suggests an almost continuous growth of the cybotactic clusters. Both T = f(FWHM) curves approach to each other around 60–70 °C where the line width becomes almost resolution limited in both cases (Fig. 11a). At this temperature infinite layers have developed and for (S)-2/12 the superparaelectric switching of polar clusters sets in a few degrees lower at 62 °C (see Table 1).
The increase of the cluster size of (S)-2/12 compared to rac-2/12 is surprising, because one would expect that the chirality induced twist, especially the transversal twist, should have a destabilizing effect on lamellar self-assembly and cluster formation, but it seems that the opposite is the case. Thus, there appears to be a layer stabilizing effect of uniform chirality. This could arise from an improved packing of uniformly chiral molecules in the layers, which might be a result of the improved synchronization of the helix sense of helical molecular conformations under the biasing influence of the uniform permanent molecular chirality.8,35 This intramolecular twist supports the development of an intermolecular helical twist, which for tilted arrangements of molecules is composed of two components. The transversal twist of the layers (helicoidal twist, see Fig. 1c and 12c) which distorts lamellar self-assembly and eventually leads to the TGB phases,48 and the longitudinal twist along the layer normal, i.e. between the layers (Fig. 1a and 12a), leading to heliconical smectic phases (SmC*37). Moreover, it is hypothesized that there is a conservation of the molecular helicity. This means that with growing cluster size the layer distorting transversal twist is not simply removed, but replaced by an increasing longitudinal twist, not distorting lamellar self-assembly (Fig. 12a and c). In the pure enantiomer (S)-2/12 the uniform molecular chirality favors a uniform sense of helicity, supporting a dense packing without intercalation, leading to larger d-values. In the racemate rac-2/12 the chirality synchronization is also present as expressed by spontaneous conglomerate formation (see Fig. 7). However, it is much weaker due to the absence of uniform (permanent) configurational chirality. Thus, the chirality synchronization becomes weaker, which allows more disorder, requiring the alkyl chain intercalation to retain a dense packing. The chirality synchronization obviously decreases with lowering temperature, either as the developing tendency of antipolar ordering supports a (SmCsPA-like) racemic phase structure, or due to the growing strength of the competing unfavorable diastereomeric relations between the synchronized molecular and supramolecular helicity and those molecules of the racemate, which have an opposite configuration. The reduced chirality synchronization distorts the packing and this requires deeper alkyl chain intercalation, then leading to the observed layer shrinkage upon approaching the SmCs′ phase range.
The effect on the racemate rac-2/12 can be attributed to an alignment of the weakly bent molecules with their average long axis parallel to the magnetic field direction (see Section 3.5). This leads to an increase of the orientational order parameter of the π-conjugated cores under the applied magnetic field, which also improves the chain order and thus reduces the space available for alkyl chain intercalation, and this leads to the observed increase of d under the magnetic field (Fig. 10a and 12b). This ordering effect of the magnetic field on the molecules also increases the correlation length of smectic order, which is in line with the observed reduction of the SAXS line width under the magnetic field (Fig. 13a, green vs. blue triangles). The effect of the magnetic field on the line width is especially strong in the Iso and NCybC phase ranges. It continues in the upper temperature range of the SmCs phase until the scattering becomes resolution limited below 70 °C upon approaching the transition to the SmCs′ phase range at 53 °C.
Fig. 13 Effects of an applied magnetic field of B = 1 T on the line width (FWHM) of the SAXS in the distinct LC phases (a) of rac-2/12 and (b) the enantiomer compound (S)-2/12. |
In contrast to the racemate, for the enantiomer (S)-2/12 there is a reduction of the d-spacing of the SAXS under the magnetic field which becomes stronger with lowering temperature (Fig. 10b). It was previously shown that a magnetic field can remove the chirality induced twist even under a comparatively low magnetic field, as reported for SmC* and TGBC* phases of uniformly chiral rod-like molecules.80,81 The effect on the heliconical (longitudinal) twist of the SmC* and TGBC* phases is especially strong and therefore it is easily removed under low fields, whereas the transversal twist of the TGB structure itself requires much higher fields. Similar effect can also be assumed for the influence of the magnetic field on the chiral LC phases of (S)-2/12. It is suggested that the main effect of the magnetic field on (S)-2/12 is again an increase of the orientational order parameter, which in this case leads to a reduction of the longitudinal intermolecular (heliconical) twist between the layers. If the intramolecular (conformational) twist is conserved under the magnetic field, the removal of the heliconical twist has to be compensated by a simultaneously developing transversal twist in the layers, effectively reducing the orientational order parameter. Thus, the chain packing would become less dense and this is avoided by additional chain intercalation, which then reduces the d-value under the applied field (Fig. 10b and 12). Therefore, in the temperature range between 60 and 80 °C the d = f(T) curve of (S)-2/12 under the magnetic field (black dots in Fig. 10b) almost resembles that of rac-2/12 without magnetic field (black triangles in Fig. 10a) only shifted by about 0.2 nm to larger values than measured for rac-2/12. This shift of d is attributed to the general increase of the order parameter under the magnetic field. Accordingly, under a magnetic field rac-2/12 and (S)-2/12 have almost identical d-values in this temperature range (Fig. 10a and b). It means that under the field an almost identical order parameter and degree of alkyl chain intercalation is achieved for (S)-2/12 and rac-2/12. This is assumed to be due to the compensation of two opposing field effects, the reduction of the heliconical (longitudinal) twist, leading to increased transversal twist (reducing ξ) on the one hand, and the increase of the orientational order parameter, reducing the induced transversal twist (and increasing ξ) on the other hand. Due to this compensation there is also almost no effect of the applied magnetic field on the correlation length of smectic order (ξ) in the LC phases of (S)-2/12 below 80 °C (Fig. 13b) when the driving force for the heliconical twist is reduced by the emerging tendency of antipolar order (developing racemic SmCsPA structure). Only in the upper SmC* range, above ∼70 °C, there is some broadening of the line width, i.e. layer distortion, under the magnetic field (Fig. 13b). In this temperature range there is a stronger intrinsic twist, and therefore, the ordering magnetic field effect on (S)-2/12 appears to be sufficient for removing the heliconical (longitudinal) twist, but insufficient to fully remove the simultaneously developing transversal twist.
Compounds with long chains (n = 10, 12) form additional tilted smectic phases (SmCs(*)), but only for the compound combining a homochiral (S)-3,7-dimethyloctyloxy chiral unit with a n-dodecyloxy chain a polar switching smectic phases was observed, whereas the corresponding racemate is non-polar. This is attributed to a denser packing of uniform enantiomers due to chirality synchronization of their chirality biased helical conformers.8 For racemic mixtures this chirality synchronization is more difficult and requires additional surface stabilization.97 Related achiral compounds with two linear n-alkyloxy chains (compounds 4 in Scheme 1) also form a polar SmCPA phase besides the cybotactic nematic phase (Table S4, ESI†).18,103 This indicates that chain branching distorts the core packing and removes polar order, and that this distortion by chain branching can be reduced or removed by chirality synchronization in the case of uniformly chiral compounds.
In the SmCs* phases the switching takes place by rotation around the long axis (see Fig. 8f and g) which means that the polar switching is not the result of the reduced phase symmetry due to the permanent molecular chirality as known for rod-like molecules, but it is due to a sterically induced polarization, as known for bent-core molecules. A ferro-like helielectric switching occurs just after transition from the chiral nematic to the SmCs* phase and below 62 °C a transition to antiferroelectric-like super-paraelectric (SmCsPAR*) and finally at 53 °C to an antiferroelectric polar switching (SmCsPA*) takes place as the polar correlation length in the layers grows with lowering temperature and the correlation between the layers simultaneously becomes antipolar with growing layer polarization.
Most interesting are the unprecedented huge effects of an applied magnetic field on the LC phases of the chiral compound (S)-2/12 as well as on its racemic mixture, leading to a layer shrinkage by up to 0.6 nm for the enantiomer and a layer expansion by 0.2–0.4 nm for the racemate under an applied field of only 1 T. It is proposed that the effect on the racemate is dominated by the coupling of the magnetic field with the almost rod-like π-conjugated molecules parallel to the field direction. In the case of the racemate the field induced increase of orientational order reduces the capability of alkyl chain intercalation, thus leading to a layer expansion. For the enantiomer the reduction of the longitudinal heliconical twist is likely to lead to an increased transversal twist within the layers, which then reduces the core order and allows chain intercalation, thus leading to the reverse effect, the field induced layer shrinkage.
Overall, this work shows that, though the coupling of the magnetic field with diamagnetic molecules is weak, it can lead to huge effects. The extraordinary strong effect of a magnetic field on the layer spacing could provide new applications of diamagnetic LC materials based on molecules at the cross-over between rod-like and bent shapes, by affecting their capability of chirality synchronization, and probably also by modulating the polar switching modes by magnetic fields. For the weakly bent compounds reported here the molecules couple with their long axis parallel to the magnetic field, whereas related molecules with a stronger bend are known to couple in an orthogonal way.73–75 Thus, there are numerous possibilities for the coupling of magnetic and electric field effects in potential electro-magneto-optical devices which needs to be explored in future work.
Footnote |
† Electronic supplementary information (ESI) available. See DOI: 10.1039/d0tc05355d |
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