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51. Role of Oxygen Vacancies in Tungsten Oxide on its Photocatalytic activity
Shen et al., ACS Catalysis (2020)
![52. Role of Solid-State Miscibility in Cesium Lead Halide](https://mcube.wustl.edu/files/2022/07/ion_exchange-768x533.png)
52. Role of Solid-State Miscibility in Cesium Lead Halide
Wang et al., J. Phys. Chem. Letters (2020)
![54. Strain-driven Migration of O Vacancies to Apical Sites in YBCO](https://mcube.wustl.edu/files/2022/07/Picture2-768x494.png)
54. Strain-driven Migration of O Vacancies to Apical Sites in YBCO
Steven T. Hartman et al., Nanoscale (2020)
![55. Amorphization and Plasticity of Olivine During Deformation](https://mcube.wustl.edu/files/2022/07/Picture1-768x494.png)
55. Amorphization and Plasticity of Olivine During Deformation
Kelly Kranjc and Arashdeep S. Thind et al., JGR Solid Earth (2020)
![56. Quasi‐Binary TMDC alloys: Thermodynamic Stability Prediction, Scalable Synthesis, and Application](https://mcube.wustl.edu/files/2022/07/TMDCbinaryalloys_AdvMater-768x278.png)
56. Quasi‐Binary TMDC alloys: Thermodynamic Stability Prediction, Scalable Synthesis, and Application
Z. Hemmat, J. Cavin, et al., Advanced Materials (2020)
![57. Highly tunable, polarization-engineered two-dimensional electron gas oxide heterostructures](https://mcube.wustl.edu/files/2022/07/AlGaO_GaO_APEX-768x211.png)
57. Highly tunable, polarization-engineered two-dimensional electron gas oxide heterostructures
P. Ranga, S. B. Cho, R. Mishra, S. Krishnamoorthy, Appl. Phys. Express (2020).
![58. Anion order in oxysulfide perovskites: origins and implications](https://mcube.wustl.edu/files/2022/07/oxysulfide_npjcompmater-768x403.png)
58. Anion order in oxysulfide perovskites: origins and implications
G. Pilania et al., npj Comput Mater (2020)
![59. Room-temperature skyrmions in strain-engineered thin films](https://mcube.wustl.edu/files/2022/07/image-12.jpg)
59. Room-temperature skyrmions in strain-engineered thin films
Budhathoki et al., Phys. Rev. B Rapid (2020)
![60. Workings of a Photocatalyst Revealed by Single-Molecule Fluorescence Imaging](https://mcube.wustl.edu/files/2022/07/BiOBr_JPCL-768x766.png)
60. Workings of a Photocatalyst Revealed by Single-Molecule Fluorescence Imaging
Shen et al., JPCL (2020)
![62. Machine learning formation enthalpies of intermetallics](https://mcube.wustl.edu/files/2022/07/image-13.jpg)
62. Machine learning formation enthalpies of intermetallics
Zhaohan Zhang et al., J. Appl. Phys. (2020)
![63. Band Gap Engineering in Alloys of Metal Dichalcogenides](https://mcube.wustl.edu/files/2022/07/Picture1-768x571.jpg)
63. Band Gap Engineering in Alloys of Metal Dichalcogenides
Wang, Cavin, et al., Adv. Funct. Mater. (2020)
![64. Layered electrides as fluoride intercalation anodes](https://mcube.wustl.edu/files/2022/07/Picture2-1-768x374.png)
64. Layered electrides as fluoride intercalation anodes
Steven T. Hartman, et al., J. Mater. Chem. A, (2020)
![65. Highly conductive PEDOT films for dye-sensitized solar cells](https://mcube.wustl.edu/files/2022/07/Picture3-768x354.png)
65. Highly conductive PEDOT films for dye-sensitized solar cells
Mojgan Kouhnavard, et al., Solar Energy (2020)
![66. Tin Oxynitride-Based Semiconductor for Solar Energy Conversion](https://mcube.wustl.edu/files/2022/07/WeChat-Screenshot_20201113165157-1-768x452.png)
66. Tin Oxynitride-Based Semiconductor for Solar Energy Conversion
Steven T. Hartman, et al., Chem. Mater. (2020)
![67. High-frequency atomic tunneling observed in single crystals](https://mcube.wustl.edu/files/2022/07/image-14.jpg)
67. High-frequency atomic tunneling observed in single crystals
Bo Sun, et al., Nature Communication (2020)