Metastable-phase 2D noble-metal oxides: syntheses and advanced catalysts
Y Wang, Q Shao - Trends in Chemistry, 2024 - cell.com
Metastable-phase 2D noble-metal oxides, combining the advantages of noble-metal oxides,
2D materials, and metastable-phase materials are considered some of the most promising …
2D materials, and metastable-phase materials are considered some of the most promising …
Suppression of the redox reaction between the IGZO surface and the reducing agent TMA using fluorine oxidizing agent treatment
We propose that the post-deposition oxidation of the IGZO surface is essential for improving
the interface quality, with Al2O3 prepared by atomic layer deposition (ALD) employing a …
the interface quality, with Al2O3 prepared by atomic layer deposition (ALD) employing a …
The Transport Mechanism and Barrier Height Inhomogeneity in Ag-ZnSnN2 Schottky Barrier Solar Cells
XM Cai, CS He, ZC Zhao, YZ Xie, DP Zhang… - Journal of Alloys and …, 2024 - Elsevier
To address the difference between the barrier height and the open circuit voltage of ZnSnN
2 Schottky barrier solar cells prepared with Ag as the contact metal by sputtering deposition …
2 Schottky barrier solar cells prepared with Ag as the contact metal by sputtering deposition …
Capacitance characterization and current transport mechanism of ZnSnN2 heterojunctions
F Ye, ZC Zhao, CS He, JL Liang, Q Gao, YZ Xie… - Applied Physics …, 2024 - pubs.aip.org
The trap and defect energy levels of ZnSnN 2 and the current transport mechanism of its
heterojunctions are studied. A shallow energy level at 105 meV below the conduction band …
heterojunctions are studied. A shallow energy level at 105 meV below the conduction band …
Synthesis and characterization of magnetron sputtered ZnSnN2 thin films for novel photovoltaics
D Giughello - 2022 - politesi.polimi.it
Nowadays harnessing the solar energy through photovoltaics applications is considered
one of the most promising paths to meet the escalating demand for energy. To exploit most …
one of the most promising paths to meet the escalating demand for energy. To exploit most …