126 research outputs found
Structure of nanoscale-pitch helical phases: blue phase and twist-bend nematic phase resolved by resonant soft X-ray scattering
Periodic structures of phases with orientational order of molecules, but
homogenous electron density distribution: a short pitch cholesteric, blue phase
and twist-bend nematic phase, were probed by a resonant soft x-ray scattering
(RSoXS) at the carbon K-edge. The theoretical model shows that in case of a
simple heliconical nematic structure two resonant signals corresponding to the
full and half pitch band should be present, while only the full pitch band is
observed in experiment. This suggests that the twist-bend nematic phase has
complex structure with a double-helix, built of two interlocked, shifted
helices. We confirm that the helical pitch in the twist-bend nematic phase is
in a 10 nm range, for both, the chiral and achiral materials. We also show that
the symmetry of a blue phase can unambiguously be determined through a resonant
enhancement of x-ray diffraction signals, by including polarization effects,
which are found to be an important indicator in phase structure determination
Do the short helices exist in the nematic TB phase?
Dimeric compounds forming twist-bend nematic, Ntb, phase show unusual optical textures related to the formation of arrays of focal conic defects (FCDs). Some of the focal conics exhibit submicron internal structure with 8 nm periodicity, which is very close to that found in the crystalline phase of the material, that might suggest surface freezing
Liquid Crystal Dimers and Smectic Phases from the Intercalated to the Twist-Bend
Funding: This research received no external funding. Acknowledgments: The authors gratefully acknowledge Professor Nataša Vaupoticˇ for her central role in the interpretation of the resonant soft X-ray scattering (RSoXS) data and the preparation of the original figures. The authors also wish to thank Ewan Cruickshank for many helpful discussions.Peer reviewedPublisher PD
Remarkable smectic phase behaviour in odd-membered liquid crystal dimers : The CT6O.mseries
Funding Information: EG and DP acknowledge the support of the National Science Centre (Poland): (Grant Number 2016/22/A/ST5/00319). RW gratefully acknowledges The Carnegie Trust for the Universities of Scotland for funding the award of a PhD scholarship 2015-2018.Peer reviewedPublisher PD
The Chiral Twist-Bend Nematic Phase (N*TB)
Acknowledgements E.G. and D.P. acknowledge the support of the National Science Centre (Poland): (Grant Number 2016/22/A/ST5/00319). R.W. gratefully acknowledges The Carnegie Trust for the Universities of Scotland for funding the award of a PhD scholarship.Peer reviewedPostprin
Disturbances in the Biosynthesis or Signalling of Brassinosteroids That Are Caused by Mutations in the HvDWARF, HvCPD and HvBRI1 Genes Increase the Tolerance of Barley to the Deacclimation Process
Tolerance to deacclimation is an important physiological feature in plants in the face of global warming, which is resulting
in incidents of increases in winter temperatures. The aim of the work was to explore how disturbances in the signalling and
synthesis of brassinosteroids (BR) influence the deacclimation tolerance of barley. One group of mutants and their reference
cultivars (Bowman and Delisa) was cold-acclimated, deacclimated and then tested for frost tolerance at − 12 °C. After cold
acclimation, the second group of plants was additionally exposed to frost (− 6 °C) and then, deacclimated and tested for frost
tolerance at − 12 °C. The deacclimated brassinosteroid mutants were characterised by an increased tolerance to frost, and
consequently, had a higher tolerance to deacclimation than their wild-type cultivars. The mechanism of this phenomenon may
be partly explained by analysing the hormonal homeostasis in the crowns. For all of the tested plants, a characteristic feature
of the response to the deacclimation phase was an increase in the growth-promoting hormones and abscisic acid compared
to the cold acclimation phase. The increase was greater in the BR-deficient (BW084) and BR-insensitive (BW312) mutants
compared to the Bowman reference cultivar. Mutant 522DK was characterised by a lower accumulation of total cytokinins
and gibberellins as well as an enhanced auxin deactivation compared to the Delisa. In the second group, when the plants were
exposed to a temperature of − 6 °C before deacclimation, the hormonal homeostasis was further altered in both the mutants
and reference cultivars, but all of the mutants had a higher frost tolerance than the wild types
Mutations in the HvDWARF, HvCPD and HvBRI1 Genes-Involved in Brassinosteroid Biosynthesis/Signalling : Altered Photosynthetic Efficiency, Hormonal Homeostasis and Tolerance to High/Low Temperatures in Barley
Brassinosteroids (BR) are steroid phytohormones that are involved in the growth and stress response in plants, but the precise mechanisms of their action are still being discovered. In our study we have used BR-deficient barley mutants 522DK and BW084 (which carry missense mutations in the HvDWARF and HvCPD genes, respectively). We have also used a BR-signalling mutant that harbors missense substitutions in the HvBRI1 gene. Our aim was (1) to find out if the content of phytohormones in the mutants grown at 20 °C is different than in the wild types and whether/how the content of phytohormones changes after plant acclimation at temperatures of 5 °C and 27 °C?, (2) to characterise the effectiveness of the light reactions of photosynthesis of the barley mutants in comparison to wild types at various temperatures, and (3) to verify the impact of mutations on the tolerance of barley to high and low temperatures. Hormonal characteristics of the BR mutants of barley show the complexity of the interactions between BR and other plant hormones that are additionally modified by temperature and possibly by other factors. The results suggest the participation of BR in auxin catabolism. Further, BR appears to play a role in maintaining the ABA–ABAGlc balance. As for the gibberellin content in plants at a temperature of 20 °C, more in-depth studies will be required to explain the contradictory effects regarding the accumulation of GA3, GA4 and GA5, which appears to be dependent on the type of mutation and connected to the BR level. A fast-kinetic chlorophyll a fluorescence analysis has revealed that the mutants had lower values of energy absorption than the wild types, but the values of the energy transferred via the electron-transport chain was maintained at the wild-type level. We presumed that BR are involved in regulating plant acclimation to extreme (low/high) temperatures, thus the BR-deficient and BR-signalling mutants should be less tolerant to low/high temperatures when compared to the wild types. Unexpectedly, all of the mutants showed a higher tolerance to high temperatures than the wild types. The BW084 and BW312 mutants were less tolerant to frost than the wild type, but 522DK had a similar frost tolerance as the reference wild-type cultivar
Molecular shape, electronic factors, and the ferroelectric nematic phase: investigating the impact of structural modifications.
The synthesis and characterisation of two series of low molar mass mesogens, the (4-nitrophenyl) 2-alkoxy-4-(4-methoxybenzoyl)oxybenzoates (NT3.m) and the (3-fluoro-4-nitrophenyl) 2-alkoxy-4-(4-methoxybenzoyl)oxybenzoates (NT3F.m), are reported in order to investigate the effect of changing the position of a lateral alkoxy chain from the methoxy-substituted terminal ring to the central phenyl ring in these two series of materials based on RM734. All members of the NT3.m series exhibited a conventional nematic phase, N, which preceded the ferroelectric nematic phase, NF, whereas all the members of the NT3F.m series exhibited direct NF-I transitions except for NT3F.1 which also exhibited an N phase. These materials cannot be described as wedge-shaped, yet their values of the ferroelectric nematic-nematic transition temperature, TNPN, exceed those of the corresponding materials with the lateral alkoxy chain located on the methoxy-substituted terminal ring. In part, this may be attributed to the effect that changing the position of the lateral alkoxy chain has on the electronic properties of these materials, specifically on the electron density associated with the methoxy-substituted terminal aromatic ring. The value of TNI decreased with the addition of a fluorine atom ortho to the nitro group in NT3F.1, however, the opposite behaviour was found when the transition temperatures of the NF phase were compared which are higher for the NT3F.m series. This may reflect a change in the polarity and polarizability of the NT3F.m series compared to the NT3.m series. Therefore, it is suggested that, rather than simply promoting a tapered shape, the role of the lateral chain in inhibiting anti-parallel associations and its effect on the electronic properties of the molecules are the key factors in driving the formation of the NF phase
- …