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1. jiaren yuan, yuanping chen, yuee xie, xiaoyu zhang, dewei rao, yandong guo, xiaohong yan*, yuan ping feng*, and yongqing cai*. squeezed metallic droplet with tunable kubo gap and charge injection in transition metal dichalcogenides. natl. acad. sci. u s a, 117, 6362-6369 (2020).
2. yu jun tan, hareesh godaba, ge chen, siew ting melissa tan, guanxiang wan, guojingxian li, pui mun lee, yongqing cai, si li, robert f. shepherd, john s. ho & benjamin c. k. tee, a transparent, self-healing and high-¦Ê dielectric for low-field-emission stretchable optoelectronics. nature materials 19, 182¨c188 (2020).
3. yue cao, yu jun tan, si li, wang wei lee, hongchen guo, yongqing cai, chao wang, benjamin c.-k. tee, self-healing electronic skins for aquatic environments. nature electronics 2, 75¨c82 (2019).
4. xiao zhang#, zhimin luo#, peng yu#, yongqing cai#, et al, lithiation-induced amorphization of pd3p2s8 for highly efficient hydrogen evolution. nature catalysis 1, 460 (2018).
5. subhadeep datta#, yongqing cai#, indra yudhistira, zebing zeng, yong-wei zhang, han zhang, shaffique adam, jishan wu, and kian ping loh, tuning magnetoresistance in molybdenum disulphide and graphene using a molecular spin transition. nature communications 8, 677 (2017).
6. qingqing ke, cao guan, xiao zhang, minrui zheng, yong-wei zhang, yongqing cai*, hua zhang*, and john wang*, surface-charge-mediated formation of h-tio2@ni(oh)2 heterostructures for high-performance supercapacitors. adv. mater. 29, 1604164 (2017).
7. yongqing cai, qingqing ke, gang zhang, boris i. yakobson, and yong-wei zhang, highly itinerant atomic vacancies in phosphorene. j. am. chem. soc. 138, 10199-10206 (2016).
8. yongqing cai, qingqing ke, gang zhang, yuan ping feng, vivek b. shenoy, and yong-wei zhang, giant phononic anisotropy and unusual anharmonicity of phosphorene: interlayer coupling and strain engineering. adv. funct. mater. 25, 2230-2236 (2015) (journal cover).
9. yongqing cai, gang zhang, yong-wei zhang, polarity-reversed robust carrier mobility in monolayer mos2 nanoribbons. j. am. chem. soc. 136, 6269−6275 (2014). |