Your search keyword '"Mocatta, David"' showing total 11 results

1. Heavily Doped Semiconductor Nanocrystal Quantum Dots

Author

Mocatta, David, Cohen, Guy, Schattner, Jonathan, Millo, Oded, Rabani, Eran, and Banin, Uri

Subjects

Condensed Matter - Materials Science

Abstract

Doping of semiconductors by impurity atoms enabled their widespread technological application in micro and opto-electronics. For colloidal semiconductor nanocrystals, an emerging family of materials where size, composition and shape-control offer widely tunable optical and electronic properties, doping has proven elusive. This arises both from the synthetic challenge of how to introduce single impurities and from a lack of fundamental understanding of this heavily doped limit under strong quantum confinement. We develop a method to dope semiconductor nanocrystals with metal impurities providing control of the band gap and Fermi energy. A combination of optical measurements, scanning tunneling spectroscopy and theory revealed the emergence of a confined impurity band and band-tailing. Successful control of doping and its understanding provide n- and p-doped semiconductor nanocrystals which greatly enhance the potential application of such materials in solar cells, thin-film transistors, and optoelectronic devices., Comment: Paper - 17 pages, 4 figures SI - 3 pages, 24 figures

Published

2021

2. On the Absence of Carrier Multiplication in InAs Core/Shell/Shell Nanocrystals

Author

Ben-Lulu, Meirav, Mocatta, David, Bonn, Mischa, Banin, Uri, Ruhman, Sandy, Corkum, Paul, editor, Silvestri, Sandro, editor, Nelson, Keith A., editor, Riedle, Eberhard, editor, and Schoenlein, Robert W., editor

Published

2009

3. Heavily Doped Semiconductor Nanocrystal Quantum Dots

Author

Mocatta, David, Cohen, Guy, Schattner, Jonathan, Millo, Oded, Rabani, Eran, and Banin, Uri

Published

2011

4. Effects of Zn2+ and Ga3+ doping on the quantum yield of cluster-derived InP quantum dots.

Author

Friedfeld, Max R., Stein, Jennifer L., Johnson, Dane A., Park, Nayon, Henry, Nicholas A., Enright, Michael J., Mocatta, David, and Cossairt, Brandi M.

Subjects

QUANTUM dot synthesis, ZINC ions, QUANTUM dots, COMPLEX ions, INDIUM phosphide, CHARGE carriers, COMMERCIAL markets

Abstract

As the commercial display market grows, the demand for low-toxicity, highly emissive, and size-tunable semiconducting nanoparticles has increased. Indium phosphide quantum dots represent a promising solution to these challenges; unfortunately, they typically suffer from low inherent emissivity resulting from charge carrier trapping. Strategies to improve the emissive characteristics of indium phosphide often involve zinc incorporation into or onto the core itself and the fabrication of core/shell heterostructures. InP clusters are high fidelity platforms for studying processes such as cation exchange and surface doping with exogenous ions since these clusters are used as single-source precursors for quantum dot synthesis. Here, we examined the incorporation of zinc and gallium ions in InP clusters and the use of the resultant doped clusters as single-source precursors to emissive heterostructured nanoparticles. Zinc ions were observed to readily react with InP clusters, resulting in partial cation exchange, whereas gallium resisted cluster incorporation. Zinc-doped clusters effectively converted to emissive nanoparticles, with quantum yields strongly correlated with zinc content. On the other hand, gallium-doped clusters failed to demonstrate improvements in quantum dot emission. These results indicate stark differences in the mechanisms associated with aliovalent and isovalent doping and provide insight into the use of doped clusters to make emissive quantum dots. [ABSTRACT FROM AUTHOR]

Published

2019

5. Effects of Zn2+ and Ga3+ doping on the quantum yield of cluster-derived InP quantum dots

Author

Friedfeld, Max R., primary, Stein, Jennifer L., additional, Johnson, Dane A., additional, Park, Nayon, additional, Henry, Nicholas A., additional, Enright, Michael J., additional, Mocatta, David, additional, and Cossairt, Brandi M., additional

Published

2019

6. Interface Modifications of InAs Quantum-Dots Solids and their Effects on FET Performance

Author

Soreni-Harari, Michal, primary, Mocatta, David, additional, Zimin, Marina, additional, Gannot, Yair, additional, Banin, Uri, additional, and Tessler, Nir, additional

Published

2010

7. Selective Gold Growth on CdSe Seeded CdS Nanorods

Author

Menagen, Gabi, primary, Mocatta, David, additional, Salant, Asaf, additional, Popov, Inna, additional, Dorfs, Dirk, additional, and Banin, Uri, additional

Published

2008

8. On the Absence of Detectable Carrier Multiplication in a Transient Absorption Study of InAs/CdSe/ZnSe Core/Shell1/Shell2 Quantum Dots

Author

Ben-Lulu, Meirav, primary, Mocatta, David, additional, Bonn, Mischa, additional, Banin, Uri, additional, and Ruhman, Sanford, additional

Published

2008

9. CURE OF CANCER.

Author

Weldon Fell, J., primary and Mocatta, David, additional

Published

1857

10. READERS WRITE.

Author

Everett, Nancy L., Mocatta, David, Panagini, Louis, Satz, Ina, Ahlborn, Mel, and Malone, Helen

Abstract

Several letters to the editor are presented in response to articles in previous issues, including "Gilding for Calligraphers," by Thomas Ingmire, another about Sheila Waters' basic Brava calligraphy series, and "Modern Gilding for Calligraphers," by Thomas Ingmire.

Published

1995

11. Effects of Zn 2+ and Ga 3+ doping on the quantum yield of cluster-derived InP quantum dots.

Author

Friedfeld MR, Stein JL, Johnson DA, Park N, Henry NA, Enright MJ, Mocatta D, and Cossairt BM

Abstract

As the commercial display market grows, the demand for low-toxicity, highly emissive, and size-tunable semiconducting nanoparticles has increased. Indium phosphide quantum dots represent a promising solution to these challenges; unfortunately, they typically suffer from low inherent emissivity resulting from charge carrier trapping. Strategies to improve the emissive characteristics of indium phosphide often involve zinc incorporation into or onto the core itself and the fabrication of core/shell heterostructures. InP clusters are high fidelity platforms for studying processes such as cation exchange and surface doping with exogenous ions since these clusters are used as single-source precursors for quantum dot synthesis. Here, we examined the incorporation of zinc and gallium ions in InP clusters and the use of the resultant doped clusters as single-source precursors to emissive heterostructured nanoparticles. Zinc ions were observed to readily react with InP clusters, resulting in partial cation exchange, whereas gallium resisted cluster incorporation. Zinc-doped clusters effectively converted to emissive nanoparticles, with quantum yields strongly correlated with zinc content. On the other hand, gallium-doped clusters failed to demonstrate improvements in quantum dot emission. These results indicate stark differences in the mechanisms associated with aliovalent and isovalent doping and provide insight into the use of doped clusters to make emissive quantum dots.

Published

2019