@article{oai:nifs-repository.repo.nii.ac.jp:02000456,
 author = {LI, Heng and ZHANG, Xin and XU, Yuhong and LEI, Guangjiu and LIU, Sanqiu and TSUMORI, Katsuyoshi and NAKANO, Haruhisa and OSAKABE, Masaki and ISOBE, Mitsutaka and OKAMURA, Shoichi and SHIMIZU, Akihiro and OGAWA, Kunihiro and TAKAHASHI, Hiromi and CUI, Zilin and HU, Jun and ZHU, Yiqin and LI, Xiaolong and ZHENG, Huaqing and LIU, Xiaoqiao and GENG, Shaofei and CHEN, Xiaochang and LIU, Haifeng and WANG, Xianqu and LIU, Hai and TANG, Changjian and CFQS team},
 issue = {March 2024},
 journal = {Nuclear Materials and Energy},
 month = {Feb},
 note = {Based on the DFT method, the effects of copper and tungsten impurities present in the negative ion source of neutral beams on the cesiated surface were studied, including their effects on the adsorption energy of cesium on the surface and the surface work function. The results indicate that copper impurities significantly increase the average adsorption energy of cesium, whereas tungsten has limited enhancement on the average adsorption energy of cesium and may even reduce it. The work function calculations show that, at cesium coverages below 4/16 θ, copper impurities cause a significant increase in the work function. However, at cesium coverages above 6/16 θ, high-coverage copper impurities lead to a further decrease in the work function, causing the cesium coverage corresponding to the lowest work function to shift towards higher cesium coverage. Under any tungsten impurity and cesium coverage, tungsten impurities can significantly increase the surface work function, with the maximum increase reaching 0.50 eV. The dipole moment density analysis shows that in most cases, impurities significantly reduce the dipole moment density of the cesiated surface, except when the coverage of cesium and copper impurities is above 6/16 θ. The charge transfer results show that the copper impurity layer has more positive charge compared to the tungsten impurity layer, which significantly affects the dipole moment density of the surface system. In addition, adsorbed atoms cause electrons in the molybdenum atomic layer to migrate to the surface, resulting in the molybdenum substrate having a pronounced negative dipole moment.},
 title = {Effect of metal impurities on the adsorption energy of cesium and work function of the cesiated Mo (001) surface},
 volume = {38},
 year = {2024}
}