| 1 |
Computational Study of Transition-Metal Substitutions in Rutile TiO2 (110) for Photoelectrocatalytic Ammonia Synthesis
Comer BM, Lenk MH, Rajanala AP, Flynn EL, Medford AJ
Catalysis Letters, 151(4), 1142, 2021 |
| 2 |
Restructuring effects of the chemical environment in metal nanocatalysis and single-atom catalysis
Piccolo L
Catalysis Today, 373, 80, 2021 |
| 3 |
Stabilizing Co, Ni and Cu on the h-BN surface: Using O-O bond activation to probe their performance as single atom catalyst
Datta J, Majumder C
Catalysis Today, 370, 75, 2021 |
| 4 |
SiO2 supported highly dispersed Pt atoms on LaNiO3 by reducing a perovskite-type oxide as the precursor and used for CO oxidation
Zhang SR, An K, Fang CY, Zhang ZY, Liu Q, Lu SH, Liu Y
Catalysis Today, 355, 222, 2020 |
| 5 |
Selective activation of methane C-H bond in the presence of methanol
Xi YJ, Heyden A
Journal of Catalysis, 386, 12, 2020 |
| 6 |
The stability and reactivity of transition metal atoms supported mono and di vacancies defected carbon based materials revealed from first principles study
Ali S, Liu TF, Lian Z, Su DS, Li B
Applied Surface Science, 473, 777, 2019 |
| 7 |
N-2 reduction using single transition-metal atom supported on defective WS2 monolayer as promising catalysts: A DFT study
Ma XG, Hu JS, Zheng MK, Li D, Lv H, He H, Huang CY
Applied Surface Science, 489, 684, 2019 |
| 8 |
Single-Atom Catalysis: How Structure Influences Catalytic Performance
Parkinson GS
Catalysis Letters, 149(5), 1137, 2019 |
| 9 |
Directly catalytic reduction of NO without NH3 by single atom iron catalyst: A DFT calculation
Yang WJ, Gao ZY, Liu XS, Ma CZ, Ding XL, Yan WP
Fuel, 243, 262, 2019 |
| 10 |
In-situ synthesis of single-atom Ir by utilizing metal-organic frameworks: An acid-resistant catalyst for hydrogenation of levulinic acid to gamma-valerolactone
Cao WX, Lin L, Qi HF, He Q, Wu ZJ, Wang AQ, Luo WH, Zhang T
Journal of Catalysis, 373, 161, 2019 |
