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1. Upgraded Bioelectrocatalytic N ₂ Fixation: From N ₂ to Chiral Amine Intermediates

   https://doi.org/10.1021/jacs.9b00147  

   Chen, Hui; Cai, Rong; Patel, Janki; Dong, Fangyuan; Chen, Hsiaonung; Minteer, Shelley D. (March 2019, Journal of the American Chemical Society)
2. Transport and optical properties of the chiral semiconductor Ag ₃ AuSe ₂

   https://doi.org/10.1002/zaac.202200055  

   Won, Juyeon; Kim, Soyeun; Gutierrez‐Amigo, Martin; Bettler, Simon; Lee, Bumjoo; Son, Jaeseok; Won Noh, Tae; Errea, Ion; Vergniory, Maia G.; Abbamonte, Peter; et al (May 2022, Zeitschrift für anorganische und allgemeine Chemie)

   Abstract Previous band structure calculations predicted Ag₃AuSe₂to be a semiconductor with a band gap of approximately 1 eV. Here, we report single crystal growth of Ag₃AuSe₂and its transport and optical properties. Single crystals of Ag₃AuSe₂were synthesized by slow‐cooling from the melt, and grain sizes were confirmed to be greater than 2 mm using electron backscatter diffraction. Optical and transport measurements reveal that Ag₃AuSe₂is a highly resistive semiconductor with a band gap and activation energy around 0.3 eV. Our first‐principles calculations show that the experimentally determined band gap lies between the predicted band gaps from GGA and hybrid functionals. We predict band inversion to be possible by applying tensile strain. The sensitivity of the gap to Ag/Au ordering, chemical substitution, and heat treatment merit further investigation. 

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3. Chiral photocurrent in a Quasi-1D TiS ₃ (001) phototransistor

   https://doi.org/10.1088/1361-648x/acb581  

   Gilbert, Simeon J; Li, Mingxing; Chen, Jia-Shiang; Yi, Hemian; Lipatov, Alexey; Avila, Jose; Sinitskii, Alexander; Asensio, Maria C; Dowben, Peter A; Yost, Andrew J (February 2023, Journal of Physics: Condensed Matter)

   Abstract The presence of in-plane chiral effects, hence spin–orbit coupling, is evident in the changes in the photocurrent produced in a TiS 3 (001) field-effect phototransistor with left versus right circularly polarized light. The direction of the photocurrent is protected by the presence of strong spin–orbit coupling and the anisotropy of the band structure as indicated in NanoARPES measurements. Dark electronic transport measurements indicate that TiS 3 is n-type and has an electron mobility in the range of 1–6 cm 2 V −1 s −1 . I – V measurements under laser illumination indicate the photocurrent exhibits a bias directionality dependence, reminiscent of bipolar spin diode behavior. Because the TiS 3 contains no heavy elements, the presence of spin–orbit coupling must be attributed to the observed loss of inversion symmetry at the TiS 3 (001) surface. 

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4. Observation of chiral surface excitons in a topological insulator Bi ₂ Se ₃

   https://doi.org/10.1073/pnas.1813514116  

   Kung, H. -H.; Goyal, A. P.; Maslov, D. L.; Wang, X.; Lee, A.; Kemper, A. F.; Cheong, S. -W.; Blumberg, G. (February 2019, Proceedings of the National Academy of Sciences)

   The protected electron states at the boundaries or on the surfaces of topological insulators (TIs) have been the subject of intense theoretical and experimental investigations. Such states are enforced by very strong spin–orbit interaction in solids composed of heavy elements. Here, we study the composite particles—chiral excitons—formed by the Coulomb attraction between electrons and holes residing on the surface of an archetypical 3D TI, ${\mathrm{B}\mathrm{i}}_2{\mathrm{S}\mathrm{e}}_3$. Photoluminescence (PL) emission arising due to recombination of excitons in conventional semiconductors is usually unpolarized because of scattering by phonons and other degrees of freedom during exciton thermalization. On the contrary, we observe almost perfectly polarization-preserving PL emission from chiral excitons. We demonstrate that the chiral excitons can be optically oriented with circularly polarized light in a broad range of excitation energies, even when the latter deviate from the (apparent) optical band gap by hundreds of millielectronvolts, and that the orientation remains preserved even at room temperature. Based on the dependences of the PL spectra on the energy and polarization of incident photons, we propose that chiral excitons are made from massive holes and massless (Dirac) electrons, both with chiral spin textures enforced by strong spin–orbit coupling. A theoretical model based on this proposal describes quantitatively the experimental observations. The optical orientation of composite particles, the chiral excitons, emerges as a general result of strong spin–orbit coupling in a 2D electron system. Our findings can potentially expand applications of TIs in photonics and optoelectronics. 

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5. IrGe ₄ : A Predicted Weyl-Metal with a Chiral Crystal Structure

   https://doi.org/10.1021/acs.inorgchem.3c01528  

   Skaggs, Callista M; Ryu, Dong-Choon; Bhandari, Hari; Xin, Yan; Kang, Chang-Jong; Lapidus, Saul H; Siegfried, Peter E; Ghimire, Nirmal J; Tan, Xiaoyan (December 2023, Inorganic Chemistry)

   Polycrystalline IrGe4 was synthesized by annealing elements at 800 °C for 240 h, and the composition was confirmed by energy-dispersive X-ray spectroscopy. IrGe4 adopts a chiral crystal structure (space group P3121) instead of a polar crystal structure (P31), which was corroborated by the convergent-beam electron diffraction and Rietveld refinements using synchrotron powder X-ray diffraction data. The crystal structure features layers of IrGe8 polyhedra along the b axis, and the layers are connected by edge- and corner-sharing. Each layer consists of corner-shared [Ir3Ge20] trimers, which are formed by three IrGe8 polyhedra connected by edge-sharing. Temperature-dependent resistivity indicates metallic behavior. The magnetoresistance increases with increasing applied magnetic field, and the nonsaturating magnetoresistance reaches 11.5% at 9 T and 10 K. The Hall resistivity suggests that holes are the majority carrier type, with a carrier concentration of 4.02 × 1021 cm–3 at 300 K. Electronic band structures calculated by density functional theory reveal a Weyl point with a chiral charge of +3 above the Fermi level. 

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