19 |
[ACS Energy letters, IF: 23.9, Top 5%] Near-Unity Broadband Quantum Efficiency Enabled by Colloidal Quantum Dot/Mixed-Organic Heterojunction
| NECO | 2023.04.24 | 205 |
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[Journal of Material Chemistry A, IF: 12.7, Top 10%] Small-Molecule-Templated Nanostructure Back Electrode for Enhanced Light Absorption and Photocurrent in Perovskite Quantum Dot Photovoltaics
| NECO | 2022.12.06 | 1048 |
17 |
[Advanced Materials, IF: 30.8, Top 2%] Fast Near-Infrared Photodetection using III-V Colloidal Quantum Dots
| NECO | 2022.12.06 | 567 |
16 |
[Applied Surface Science, IF: 6.8, Top 5%] Surface tailoring enables colloidal quantum dot:metal-oxide nanocrystal hybrid ink for broadband photon energy conversion
| NECO | 2022.12.06 | 511 |
15 |
[Advanced Energy Materials, IF: 29.368] Mediating colloidal quantum dot/organic semiconductor interfaces for efficient hybrid solar cells
| admin | 2022.05.11 | 615 |
14 |
[Journal of Material Chemistry A,IF: 12.732] Small-Molecule-Templated Nanostructure Back Electrode for Enhanced Light Absorption and Photocurrent in Perovskite Quantum Dot Photovoltaics
| admin | 2022.05.11 | 804 |
13 |
[ACS Applied Materials &Interfaces, IF: 8.758] Role of oxygen in two-step thermal annealing processes for enhancing the performance of colloidal quantum dot solar cells
| admin | 2021.06.14 | 21112 |
12 |
[Nature Communications, IF: 12.121]Orthogonal colloidal quantum dot inks enable efficient multilayer optoelectronic devices
| admin | 2020.11.01 | 2565 |
11 |
[Advanced Materials, IF: 27.398]Strategic Optical Structure for Highly Efficient Monolithic Organic/Colloidal Quantum Dot Hybrid Tandem Solar Cells
| admin | 2020.11.01 | 1294 |
10 |
[Joule, IF: 27.054]Monolayer Perovskite Bridges Enable Strong Quantum Dot Coupling for Efficient Solar Cells
| admin | 2020.11.01 | 679 |