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1. Flow-induced periodic chiral structures in an achiral nematic liquid crystal

   https://doi.org/10.1038/s41467-023-43978-6  

   Zhang, Qing; Wang, Weiqiang; Zhou, Shuang; Zhang, Rui; Bischofberger, Irmgard (January 2024, Nature Communications)

   Abstract Supramolecular chirality typically originates from either chiral molecular building blocks or external chiral stimuli. Generating chirality in achiral systems in the absence of a chiral input, however, is non-trivial and necessitates spontaneous mirror symmetry breaking. Achiral nematic lyotropic chromonic liquid crystals have been reported to break mirror symmetry under strong surface or geometric constraints. Here we describe a previously unrecognised mechanism for creating chiral structures by subjecting the material to a pressure-driven flow in a microfluidic cell. The chirality arises from a periodic double-twist configuration of the liquid crystal and manifests as a striking stripe pattern. We show that the mirror symmetry breaking is triggered at regions of flow-induced biaxial-splay configurations of the director field, which are unstable to small perturbations and evolve into lower energy structures. The simplicity of this unique pathway to mirror symmetry breaking can shed light on the requirements for forming macroscopic chiral structures. 

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2. Switching Chirality in Arrays of Shape‐Reconfigurable Spindle Microparticles

   https://doi.org/10.1002/adma.202303009  

   Liu, Mingzhu; Han, Xingyue; Nah, So Hee; Wu, Tianwei; Wang, Yuchen; Feng, Liang; Wu, Liang; Yang, Shu (June 2023, Advanced Materials)

   Abstract The giant circular photo‐galvanic effect is realized in chiral metals when illuminated by circularly polarized light. However, the structure itself is not switchable nor is the crystal chirality in the adjacent chiral domains. Here spindle‐shaped liquid crystalline elastomer microparticles that can switch from prolate to spherical to oblate reversibly upon heating above the nematic to isotropic transition temperature are synthesized. When arranged in a honeycomb lattice, the continuous shape change of the microparticles leads to lattice reconfiguration, from a right‐handed chiral state to an achiral one, then to a left‐handed chiral state, without breaking the translational symmetry. Accordingly, the sign of rotation of the polarized light passing through the lattices changes as measured by time‐domain terahertz spectroscopy. Further, it can locally alter the chirality in the adjacent domains using near‐infrared light illumination. The reconfigurable chiral microarrays will allow us to explore non‐trivial symmetry‐protected transport modes of topological lattices at the light–matter interface. Specifically, the ability to controllably create chiral states at the boundary of the achiral/chiral domains will lead to rich structures emerging from the interplay of symmetry and topology. 

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3. Chiral Assemblies of π-Conjugated Molecules: Fundamentals, Processing Strategies, and Applications in (Opto)Electronics

   https://doi.org/10.1146/annurev-chembioeng-100722-104224  

   Fernando, Pravini S; Chen, Yen-Chi; Baek, Janice M; Diao, Ying (March 2025, Annual Review of Chemical and Biomolecular Engineering)

   Chirality, a fundamental attribute of asymmetry, pervades in both nature and functional soft materials. In chiral material systems design, achieving global symmetry breaking of building blocks during assembly, with or without the aid of additives, has emerged as a promising strategy across domains including chiral sensing, electronics, photonics, spintronics, and biomimetics. We first introduce the fundamental aspects of chirality, including its structural basis and symmetry-breaking mechanisms considering free energy minimization. We particularly emphasize supramolecular assembly, such as through the formation of chiral liquid crystal phases. Next, we summarize processing strategies to control chiral symmetry breaking, exploiting external fields such as flow, magnetic fields, and templates. The final section discusses interactions between chiral molecular assemblies with circularly polarized (CP) light and electronic spin and their applications in CP light detectors, CP-spin-organic light-emitting diodes, CP displays, and spintronic devices based on the chirality-induced spin selectivity effect. 

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4. Fluid–fluid phase transitions in a chiral molecular model

   https://doi.org/10.1063/5.0105851  

   Wang, Yiming; Stillinger, Frank H.; Debenedetti, Pablo G. (August 2022, The Journal of Chemical Physics)

   Molecular chirality is a fundamental phenomenon, underlying both life as we know it and industrial pharmaceutical syntheses. Understanding the symmetry breaking phase transitions exhibited by many chiral molecular substances provides basic insights for topics ranging from the origin of life to the rational design of drug manufacturing processes. In this work, we have performed molecular dynamics simulations to investigate the fluid–fluid phase transitions of a flexible three-dimensional four-site chiral molecular model developed by Latinwo et al. [J. Chem. Phys. 145, 154503 (2016)] and Petsev et al. [J. Chem. Phys. 155, 084105 (2021)]. By introducing a bias favoring local homochiral vs heterochiral interactions, the system exhibits a phase transition from a single achiral phase to a single chiral phase that undergoes infrequent interconversion between the two thermodynamically identical chiral states: the L-rich and D-rich phases. According to the phase rule, this reactive binary system has two independent degrees of freedom and exhibits a density-dependent critical locus. Below the liquid–liquid critical locus, there exists a first-order vapor–liquid coexistence region with a single independent degree of freedom. Our results provide basic thermodynamic and kinetic insights for understanding many-body chiral symmetry breaking phenomena. 

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5. Phototransformation of achiral metasurfaces into handedness-selectable transient chiral media

   https://doi.org/10.1073/pnas.2318713121  

   Kim, Andrew S; Goswami, Anjan; Taghinejad, Mohammad; Cai, Wenshan (March 2024, Proceedings of the National Academy of Sciences)

   Chirality is a geometric property describing the lack of mirror symmetry. This unique feature enables photonic spin-selectivity in light–matter interaction, which is of great significance in stereochemistry, drug development, quantum optics, and optical polarization control. The versatile control of optical geometry renders optical metamaterials as an effective platform for engineered chiral properties at prescribed spectral regimes. Unfortunately, geometry-imposed restrictions only allow one circular polarization state of photons to effectively interact with chiral meta-structures. This limitation motivates the idea of discovering alternative techniques for dynamically reconfiguring the chiroptical responses of metamaterials in a fast and facile manner. Here, we demonstrate an approach that enables optical, sub-picosecond conversion of achiral meta-structures to transient chiral media in the visible regime with desired handedness upon the inhomogeneous generation of plasmonic hot electrons. As a proof of concept, we utilize linearly polarized laser pulse to demonstrate near-complete conversion of spin sensitivity in an achiral meta-platform—a functionality yet achieved in a non-mechanical fashion. Owing to the generation, diffusion, and relaxation dynamics of hot electrons, the demonstrated technique for all-optical creation of chirality is inherently fast, opening new avenues for ultrafast spectro-temporal construction of chiral platforms with on-demand spin-selectivity. 

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