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Prediction of 4f2−4f15d1 transition energy of Pr3+ in fluorides based on first-principles calculations and machine learning
The 4f2−4f15d1 transition energy of Pr3+ in fluorides are utilized for various optical materials such as solid-state lasers, phosphors, and scintillators. Therefore, it is important to predict such energies of unknown materials for theoretical design of novel optical materials. In this study, we tri...
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| Published in: | IOP conference series. Materials Science and Engineering 2020-04, Vol.835 (1) |
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| container_title | IOP conference series. Materials Science and Engineering |
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| creator | Obata, Hayato Takemura, Shota Ogasawara, Kazuyoshi |
| description | The 4f2−4f15d1 transition energy of Pr3+ in fluorides are utilized for various optical materials such as solid-state lasers, phosphors, and scintillators. Therefore, it is important to predict such energies of unknown materials for theoretical design of novel optical materials. In this study, we tried to predict the 4f2−4f15d1 transition energies of Pr3+ in fluorides based on first-principles calculations and machine learning. The first-principles calculations were performed based on the relativistic discrete variational multi-electron (DVME) method using the model clusters composed of the central Pr3+ and the anions closer than the nearest cation. Although the calculated 4f2−4f15d1 transition energies of Pr3+ in fluorides showed a relatively good correlation with the experimental ones, the calculated values tend to be overestimated by ca. 2 eV. In order to improve the accuracy of the prediction, we used the calculated transition energies as an attribute for machine learning. As a result, the regression formula to predict the 4f2−4f15d1 transition energy of Pr3+ in fluorides has been derived by machine learning using the calculated 4f2−4f15d1 transition energy as well as some other electronic and structural parameters as the attributes. The accuracy of the prediction was significantly improved compared to the simple first-principles calculations. |
| doi_str_mv | 10.1088/1757-899X/835/1/012009 |
| format | article |
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Therefore, it is important to predict such energies of unknown materials for theoretical design of novel optical materials. In this study, we tried to predict the 4f2−4f15d1 transition energies of Pr3+ in fluorides based on first-principles calculations and machine learning. The first-principles calculations were performed based on the relativistic discrete variational multi-electron (DVME) method using the model clusters composed of the central Pr3+ and the anions closer than the nearest cation. Although the calculated 4f2−4f15d1 transition energies of Pr3+ in fluorides showed a relatively good correlation with the experimental ones, the calculated values tend to be overestimated by ca. 2 eV. In order to improve the accuracy of the prediction, we used the calculated transition energies as an attribute for machine learning. As a result, the regression formula to predict the 4f2−4f15d1 transition energy of Pr3+ in fluorides has been derived by machine learning using the calculated 4f2−4f15d1 transition energy as well as some other electronic and structural parameters as the attributes. The accuracy of the prediction was significantly improved compared to the simple first-principles calculations.</description><identifier>ISSN: 1757-8981</identifier><identifier>EISSN: 1757-899X</identifier><identifier>DOI: 10.1088/1757-899X/835/1/012009</identifier><language>eng</language><publisher>Bristol: IOP Publishing</publisher><subject>Accuracy ; First principles ; Fluorides ; Machine learning ; Optical materials ; Optics ; Phosphors ; Scintillation counters ; Solid state lasers</subject><ispartof>IOP conference series. Materials Science and Engineering, 2020-04, Vol.835 (1)</ispartof><rights>Published under licence by IOP Publishing Ltd</rights><rights>2020. 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In order to improve the accuracy of the prediction, we used the calculated transition energies as an attribute for machine learning. As a result, the regression formula to predict the 4f2−4f15d1 transition energy of Pr3+ in fluorides has been derived by machine learning using the calculated 4f2−4f15d1 transition energy as well as some other electronic and structural parameters as the attributes. 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Materials Science and Engineering</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Obata, Hayato</au><au>Takemura, Shota</au><au>Ogasawara, Kazuyoshi</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Prediction of 4f2−4f15d1 transition energy of Pr3+ in fluorides based on first-principles calculations and machine learning</atitle><jtitle>IOP conference series. Materials Science and Engineering</jtitle><addtitle>IOP Conf. Ser.: Mater. Sci. Eng</addtitle><date>2020-04-01</date><risdate>2020</risdate><volume>835</volume><issue>1</issue><issn>1757-8981</issn><eissn>1757-899X</eissn><abstract>The 4f2−4f15d1 transition energy of Pr3+ in fluorides are utilized for various optical materials such as solid-state lasers, phosphors, and scintillators. Therefore, it is important to predict such energies of unknown materials for theoretical design of novel optical materials. 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| subjects | Accuracy First principles Fluorides Machine learning Optical materials Optics Phosphors Scintillation counters Solid state lasers |
| title | Prediction of 4f2−4f15d1 transition energy of Pr3+ in fluorides based on first-principles calculations and machine learning |
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