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1. Giant Modulation of Refractive Index from Picoscale Atomic Displacements

   https://doi.org/10.1002/adma.202311559  

   Zhao, Boyang; Ren, Guodong; Mei, Hongyan; Wu, Vincent C.; Singh, Shantanu; Jung, Gwan‐Yeong; Chen, Huandong; Giovine, Raynald; Niu, Shanyuan; Thind, Arashdeep S.; et al (March 2024, Advanced Materials)

   Abstract Structural disorder has been shown to enhance and modulate magnetic, electrical, dipolar, electrochemical, and mechanical properties of materials. However, the possibility of obtaining novel optical and optoelectronic properties from structural disorder remains an open question. Here, we show unambiguous evidence of disorder — in the form of anisotropic, picoscale atomic displacements — modulating the refractive index tensor and resulting in the giant optical anisotropy observed in BaTiS₃, a quasi‐one‐dimensional hexagonal chalcogenide. Single crystal X‐ray diffraction studies reveal the presence of antipolar displacements of Ti atoms within adjacent TiS₆chains along thec‐axis, and three‐fold degenerate Ti displacements in thea‐bplane.^47/49Ti solid‐state NMR provides additional evidence for those Ti displacements in the form of a three‐horned NMR lineshape resulting from a low symmetry local environment around Ti atoms. We used scanning transmission electron microscopy to directly observe the globally disordered Tia‐bplane displacements and find them to be ordered locally over a few unit cells. First‐principles calculations show that the Tia‐bplane displacements selectively reduce the refractive index along theab‐plane, while having minimal impact on the refractive index along the chain direction, thus resulting in a giant enhancement in the optical anisotropy. By showing a strong connection between structural disorder with picoscale displacements and the optical response in BaTiS₃, this study opens a pathway for designing optical materials with high refractive index and functionalities such as large optical anisotropy and nonlinearity. This article is protected by copyright. All rights reserved 

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2. Molten flux growth of single crystals of quasi-1D hexagonal chalcogenide BaTiS3

   https://doi.org/10.1557/s43578-024-01379-5  

   Chen, Huandong; Singh, Shantanu; Mei, Hongyan; Ren, Guodong; Zhao, Boyang; Surendran, Mythili; Wang, Yan-Ting; Mishra, Rohan; Kats, Mikhail A; Ravichandran, Jayakanth (June 2024, Journal of Materials Research)

   Abstract BaTiS₃, a quasi-1D complex chalcogenide, has gathered considerable scientific and technological interest due to its giant optical anisotropy and electronic phase transitions. However, the synthesis of high-quality BaTiS₃crystals, particularly those featuring crystal sizes of millimeters or larger, remains a challenge. Here, we investigate the growth of BaTiS₃crystals utilizing a molten salt flux of either potassium iodide, or a mixture of barium chloride and barium iodide. The crystals obtained through this method exhibit a substantial increase in volume compared to those synthesized via the chemical vapor transport method, while preserving their intrinsic optical and electronic properties. Our flux growth method provides a promising route toward the production of high-quality, large-scale single crystals of BaTiS₃, which will greatly facilitate advanced characterizations of BaTiS₃and its practical applications that require large crystal dimensions. Additionally, our approach offers an alternative synthetic route for other emerging complex chalcogenides. Graphical Abstract 

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3. Orientation-Controlled Anisotropy in Single Crystals of Quasi-1D BaTiS ₃

   https://doi.org/10.1021/acs.chemmater.2c01046  

   Zhao, Boyang; Hoque, Md Shafkat; Jung, Gwan Yeong; Mei, Hongyan; Singh, Shantanu; Ren, Guodong; Milich, Milena; Zhao, Qinai; Wang, Nan; Chen, Huandong; et al (June 2022, Chemistry of Materials)

   Low-dimensional materials with chain-like (one-dimensional) or layered (two-dimensional) structures are of significant interest due to their anisotropic electrical, optical, and thermal properties. One material with a chain-like structure, BaTiS3 (BTS), was recently shown to possess giant in-plane optical anisotropy and glass-like thermal conductivity. To understand the origin of these effects, it is necessary to fully characterize the optical, thermal, and electronic anisotropy of BTS. To this end, BTS crystals with different orientations (a- and c-axis orientations) were grown by chemical vapor transport. X-ray absorption spectroscopy was used to characterize the local structure and electronic anisotropy of BTS. Fourier transform infrared reflection/transmission spectra show a large in-plane optical anisotropy in the a-oriented crystals, while the c-axis oriented crystals were nearly isotropic in-plane. BTS platelet crystals are promising uniaxial materials for infrared optics with their optic axis parallel to the c-axis. The thermal conductivity measurements revealed a thermal anisotropy of ∼4.5 between the c- and a-axis. Time-domain Brillouin scattering showed that the longitudinal sound speed along the two axes is nearly the same, suggesting that the thermal anisotropy is a result of different phonon scattering rates. 

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4. Toward Atomic-Scale Control over Structural Modulations in Quasi-1D Chalcogenides for Colossal Optical Anisotropy

   https://doi.org/10.1021/acsnano.5c07992  

   Ren, Guodong; Singh, Shantanu; Jung, Gwan Yeong; Choi, Wooseon; Chen, Huandong; Zhao, Boyang; Ye, Kevin; Lupini, Andrew R; Chi, Miaofang; Hachtel, Jordan A; et al (October 2025, ACS Nano)

   Optically anisotropic materials are sought after for tailoring the polarization of light. Recently, colossal optical anisotropy (Δn = 2.1) was reported in a quasi-one-dimensional chalcogenide, Sr9/8TiS3. Compared to SrTiS3, the excess Sr in Sr9/8TiS3 leads to periodic structural modulations and introduces additional electrons, which undergo charge ordering on select Ti atoms to form a highly polarizable cloud oriented along the c-axis, hence resulting in the colossal optical anisotropy. Here, further enhancement of the colossal optical anisotropy to Δn = 2.5 in Sr8/7TiS3 is reported through control over the periodicity of the atomic-scale modulations. The role of structural modulations in tuning the optical properties in a series of SrxTiS3 compounds with x = [1, 9/8, 8/7, 6/5, 5/4, 4/3, 3/2] is investigated using density-functional-theory (DFT) calculations. The structural modulations arise from various stacking sequences of face-sharing TiS6 octahedra and twist-distorted trigonal prisms and are found to be thermodynamically stable for 1 < x < 1.5. As x increases, an indirect-to-direct band gap transition is predicted for x ≥ 8/7 along with an increased occupancy of Ti-dz2 states. Together, these two factors result in a theoretically predicted maximum birefringence of Δn = 2.5 for Sr8/7TiS3. Single crystals of Sr8/7TiS3 were grown using a molten-salt flux method. Single-crystal X-ray diffraction measurements confirm the presence of long-range order with a periodicity corresponding to Sr8/7TiS3, which is further corroborated by atomic-scale observations using scanning transmission electron microscopy. Polarization-resolved Fourier-transform infrared spectroscopy of Sr8/7TiS3 crystals shows Δn ≈ 2.5, in excellent agreement with the theoretical predictions. Overall, these findings demonstrate the compositional tunability of optical properties in SrxTiS3 compounds by control over atomic scale modulations and suggest that similar strategies could be extended to other compounds having modulated structures. 

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5. Lithography-free IR polarization converters via orthogonal in-plane phonons in α-MoO3 flakes

   https://doi.org/10.1038/s41467-020-19499-x  

   Abedini Dereshgi, Sina; Folland, Thomas G.; Murthy, Akshay A.; Song, Xianglian; Tanriover, Ibrahim; Dravid, Vinayak P.; Caldwell, Joshua D.; Aydin, Koray (December 2020, Nature Communications)

   null (Ed.)

   Abstract Exploiting polaritons in natural vdW materials has been successful in achieving extreme light confinement and low-loss optical devices and enabling simplified device integration. Recently, α-MoO 3 has been reported as a semiconducting biaxial vdW material capable of sustaining naturally orthogonal in-plane phonon polariton modes in IR. In this study, we investigate the polarization-dependent optical characteristics of cavities formed using α-MoO 3 to extend the degrees of freedom in the design of IR photonic components exploiting the in-plane anisotropy of this material. Polarization-dependent absorption over 80% in a multilayer Fabry-Perot structure with α-MoO 3 is reported without the need for nanoscale fabrication on the α-MoO 3 . We observe coupling between the α-MoO 3 optical phonons and the Fabry-Perot cavity resonances. Using cross-polarized reflectance spectroscopy we show that the strong birefringence results in 15% of the total power converted into the orthogonal polarization with respect to incident wave. These findings can open new avenues in the quest for polarization filters and low-loss, integrated planar IR photonics and in dictating polarization control. 

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