Your search keyword '"Ewoldt, David A."' showing total 17 results

1. GaN nanostructure design for optimal dislocation filtering.

Author

Zhiwen Liang, Colby, Robert, Wildeson, Isaac H., Ewoldt, David A., Sands, Timothy D., Stach, Eric A., and García, R. Edwin

Subjects

NANOSTRUCTURES, LIGHT emitting diodes, ELECTROLUMINESCENT devices, SEMICONDUCTOR diodes, GEOMETRY

Abstract

The effect of image forces in GaN pyramidal nanorod structures is investigated to develop dislocation-free light emitting diodes (LEDs). A model based on the eigenstrain method and nonlocal stress is developed to demonstrate that the pyramidal nanorod efficiently ejects dislocations out of the structure. Two possible regimes of filtering behavior are found: (1) cap-dominated and (2) base-dominated. The cap-dominated regime is shown to be the more effective filtering mechanism. Optimal ranges of fabrication parameters that favor a dislocation-free LED are predicted and corroborated by resorting to available experimental evidence. The filtering probability is summarized as a function of practical processing parameters: the nanorod radius and height. The results suggest an optimal nanorod geometry with a radius of ∼50b (26 nm) and a height of ∼125b (65 nm), in which b is the magnitude of the Burgers vector for the GaN system studied. A filtering probability of greater than 95% is predicted for the optimal geometry. [ABSTRACT FROM AUTHOR]

Published

2010

2. III-nitride nanopyramid light emitting diodes grown by organometallic vapor phase epitaxy.

Author

Wildeson, Isaac H., Colby, Robert, Ewoldt, David A., Liang, Zhiwen, Zakharov, Dmitri N., Zaluzec, Nestor J., García, R. Edwin, Stach, Eric A., and Sands, Timothy D.

Subjects

LIGHT emitting diodes, ORGANOMETALLIC chemistry, EPITAXY, ALUMINUM oxide, DIELECTRICS, TRANSMISSION electron microscopy

Abstract

Nanopyramid light emitting diodes (LEDs) have been synthesized by selective area organometallic vapor phase epitaxy. Self-organized porous anodic alumina is used to pattern the dielectric growth templates via reactive ion etching, eliminating the need for lithographic processes. (In,Ga)N quantum well growth occurs primarily on the six [formula] semipolar facets of each of the nanopyramids, while coherent (In,Ga)N quantum dots with heights of up to ∼20 nm are incorporated at the apex by controlling growth conditions. Transmission electron microscopy (TEM) indicates that the (In,Ga)N active regions of the nanopyramid heterostructures are completely dislocation-free. Temperature-dependent continuous-wave photoluminescence of nanopyramid heterostructures yields a peak emission wavelength of 617 nm and 605 nm at 300 K and 4 K, respectively. The peak emission energy varies with increasing temperature with a double S-shaped profile, which is attributed to either the presence of two types of InN-rich features within the nanopyramids or a contribution from the commonly observed yellow defect luminescence close to 300 K. TEM cross-sections reveal continuous planar defects in the (In,Ga)N quantum wells and GaN cladding layers grown at 650–780 °C, present in 38% of the nanopyramid heterostructures. Plan-view TEM of the planar defects confirms that these defects do not terminate within the nanopyramids. During the growth of p-GaN, the structure of the nanopyramid LEDs changed from pyramidal to a partially coalesced film as the thickness requirements for an undepleted p-GaN layer result in nanopyramid impingement. Continuous-wave electroluminescence of nanopyramid LEDs reveals a 45 nm redshift in comparison to a thin-film LED, suggesting higher InN incorporation in the nanopyramid LEDs. These results strongly encourage future investigations of III-nitride nanoheteroepitaxy as an approach for creating efficient long wavelength LEDs. [ABSTRACT FROM AUTHOR]

Published

2010

3. Built-in Electric Field Minimization in (In, Ga)N Nanoheterostructure

Author

Liang, Zhiwen, Wildeson, Isaac, Colby, Robert, Ewoldt, David, Zhang, Tong, Sands, Timothy, Stach, Eric, Benes, Bedrich, and Garcia, R E

Subjects

LIGHT-EMITTING-DIODES, MULTIQUANTUM-WELL STRUCTURES, MULTIPLE-QUANTUM WELLS, A-PLANE GAN, LASER-DIODES, EMISSION, EXCITONS, SINGLE, ARRAYS, Nanoscience and Nanotechnology

Abstract

(In, Ga)N nanostructures show great promise as the basis for next generation LED lighting technology, for they offer the possibility of directly converting electrical energy into light of any visible wavelength without the use of down-converting phosphors. In this paper, three-dimensional computation of the spatial distribution of the mechanical and electrical equilibrium in nanoheterostructures of arbitarary topologies is used to elucidate the complex interactions between geometry, epitaxial strain, remnant polarization, and piezoelectric and dielectric contributions to the self-induced internal electric fields. For a specific geometry-nanorods with pyramidal caps-we demonstrate that by tuning the quantum well to cladding layer thickness ration, h(w)/h(c), a minimal built-in electric field can be experimentally realized and canceled, in the limit of h(w)/h(c) = 1.28, for large h(c) values.

Published

2011

4. III-nitride nanopyramid light emitting diodes grown by organometallic vapor phase epitaxy

Author

Wildeson, Isaac, Colby, Robert, Ewoldt, David, Liang, Zhiwen, Zakharov, Dmitri, Zaluzec, Nestor J, García, R. Edwin, Stach, E A, and Sands, Timothy D

Subjects

GAN NANOWIRES, DIFFRACTION CONTRAST, STACKING-FAULTS, NANOROD ARRAYS, EMISSION, SEMICONDUCTORS, LUMINESCENCE, EFFICIENCY, SHIFT, FILMS, Engineering, Nanoscience and Nanotechnology

Abstract

Nanopyramid light emitting diodes (LEDs) have been synthesized by selective area organometallic vapor phase epitaxy. Self-organized porous anodic alumina is used to pattern the dielectric growth e templates via reactive ion etching, eliminating the need for lithographic processes. (In,Ga)N quantum well growth occurs primarily on the six {1 (1) over bar 01} semipolar facets of each of the nanopyramids, while coherent (In,Ga)N quantum dots with heights of up to similar to 20 nm are incorporated at the apex by controlling growth conditions. Transmission electron microscopy (TEM) indicates that the (In,Ga)N active regions of the nanopyramid heterostructures are completely dislocation-free. Temperature-dependent continuous-wave photoluminescence of nanopyramid heterostructures yields a peak emission wavelength of 617 nm and 605 nm at 300 K and 4 K respectively. The peak emission energy varies with increasing temperature with a double S-shaped profile, which is attributed to either the presence of two types of InN-rich features within the nanopyramids or a contribution from the commonly observed yellow defect luminescence close to 300 K. TEM cross-sections reveal continuous planar defects in the (In,Ga)N quantum wells and GaN cladding layers grown at 650-780 degrees C, present in 38% of the nanopyramid heterostructures. Plan-view TEM of the planar defects confirms that these defects do not terminate within the nanopyramids. During the growth of p-GaN, the structure of the nanopyramid LEDs changed from pyramidal to a partially coalesced film as the thickness requirements for an undepleted p-GaN layer result in nanopyramid impingement. Continuous-wave electroluminescence of nanopyramid LEDs reveals a 45 nm redshift in comparison to a thin-film LED, suggesting higher InN incorporation in the nanopyramid LEDs. These results strongly encourage future investigations of III-nitride nanoheteroepitaxy as an approach for creating efficient long wavelength LEDs.

Published

2010

5. Reflectance analysis on the MOCVD growth of AlN on Si(111) by the virtual interface model

Author

Ng, Tuoh-Bin, primary, Ewoldt, David A., additional, Shepherd, Debra A., additional, and Loboda, Mark J., additional

Published

2015

6. Bulk-Like Laminated Nitride Metal/Semiconductor Superlattices for Thermoelectric Devices

Author

Schroeder, Jeremy L, Ewoldt, David A., Amatya, Reja, Ram, Rajeev J., Shakouri, Ali, Sands, Timothy D., Schroeder, Jeremy L, Ewoldt, David A., Amatya, Reja, Ram, Rajeev J., Shakouri, Ali, and Sands, Timothy D.

Abstract

Bulk-like thermionic energy conversion devices have been fabricated from nanostructured nitride metal/semiconductor superlattices using a novel lamination process. 5-mu m thick (Hf0.5Zr0.5)N (6-nm)/ScN (6-nm) metal/semiconductor superlattices with a 12 nm period were deposited on 100-silicon substrates by reactive magnetron sputtering followed by a selective tetra methyl ammonium hydroxide substrate etching and a gold-gold lamination process to yield 300 mu m x 300 mu m x 290 mu m microscale thermionic energy conversion elements with 16,640 superlattice periods. The thermionic element had a Seebeck coefficient of -120 mu V/K at 800 K, an electrical conductivity of similar to 2500 Omega(-1)m(-1) at 800 K, and a thermal conductivity of 2.9 and 4.3 W/m-K at 300 and 625 K, respectively. The temperature dependence of the Seebeck coefficient from 300 to 800 K suggests a parallel parasitic conduction path that is dominant at low temperature, and the temperature independent electrical conductivity indicates that the (Hf0.5Zr0.5)N/gold interface contact resistivity currently dominates the device. The thermal conductivity of the laminate was significantly lower than the thermal conductivity of the individual metal or semiconductor layers, indicating the beneficial effect of the metal/semiconductor interfaces toward lowering the thermal conductivity. The described lamination process effectively bridges the gap between the nanoscale requirements needed to enhance the thermoelectric figure of merit ZT and the microscale requirements of real-world devices.

Published

2014

7. Bulk-Like Laminated Nitride Metal/Semiconductor Superlattices for Thermoelectric Devices

Author

Schroeder, Jeremy L., Ewoldt, David A., Amatya, Reja, Ram, Rajeev J., Shakouri, Ali, Sands, Timothy D., Schroeder, Jeremy L., Ewoldt, David A., Amatya, Reja, Ram, Rajeev J., Shakouri, Ali, and Sands, Timothy D.

Abstract

Bulk-like thermionic energy conversion devices have been fabricated from nanostructured nitride metal/semiconductor superlattices using a novel lamination process. 5-mu m thick (Hf0.5Zr0.5)N (6-nm)/ScN (6-nm) metal/semiconductor superlattices with a 12 nm period were deposited on 100-silicon substrates by reactive magnetron sputtering followed by a selective tetra methyl ammonium hydroxide substrate etching and a gold-gold lamination process to yield 300 mu m x 300 mu m x 290 mu m microscale thermionic energy conversion elements with 16,640 superlattice periods. The thermionic element had a Seebeck coefficient of -120 mu V/K at 800 K, an electrical conductivity of similar to 2500 Omega(-1)m(-1) at 800 K, and a thermal conductivity of 2.9 and 4.3 W/m-K at 300 and 625 K, respectively. The temperature dependence of the Seebeck coefficient from 300 to 800 K suggests a parallel parasitic conduction path that is dominant at low temperature, and the temperature independent electrical conductivity indicates that the (Hf0.5Zr0.5)N/gold interface contact resistivity currently dominates the device. The thermal conductivity of the laminate was significantly lower than the thermal conductivity of the individual metal or semiconductor layers, indicating the beneficial effect of the metal/semiconductor interfaces toward lowering the thermal conductivity. The described lamination process effectively bridges the gap between the nanoscale requirements needed to enhance the thermoelectric figure of merit ZT and the microscale requirements of real-world devices.

Published

2014

8. Organometallic vapor phase epitaxial growth of GaN on ZrN/AlN/Si substrates

Author

Oliver, Mark H, Schroeder, Jeremy L, Ewoldt, David, Wildeson, Isaac, rawat, vijay, Colby, Robert, Cantwell, Patrick R, Stach, E A, and Sands, Timothy D

Subjects

LAYER, CONTACTS

Abstract

An intermediate ZrN/AlN layer stack that enables the epitaxial growth of GaN on (111) silicon substrates using conventional organometallic vapor phase epitaxy at substrate temperatures of similar to 1000 degrees C is reported. The epitaxial (111) ZrN layer provides an integral back reflector and Ohmic contact to n-type GaN, whereas the (0001) AlN layer serves as a reaction barrier, as a thermally conductive interface layer, and as an electrical isolation layer. Smooth (0001) GaN films less than 1 mu m thick grown on ZrN/AlN/Si yield 0002 x-ray rocking curve full width at half maximum values as low as 1230 arc sec.

Published

2008

9. Bulk-Like Laminated Nitride Metal/Semiconductor Superlattices for Thermoelectric Devices

Author

Schroeder, Jeremy L., primary, Ewoldt, David A., additional, Amatya, Reja, additional, Ram, Rajeev J., additional, Shakouri, Ali, additional, and Sands, Timothy D., additional

Published

2014

10. Controlled Growth of Ordered Nanopore Arrays in GaN

Author

Wildeson, Isaac, Ewoldt, David, Colby, Robert, Stach, Eric A., Sands, Timothy D., Wildeson, Isaac, Ewoldt, David, Colby, Robert, Stach, Eric A., and Sands, Timothy D.

Abstract

High-quality, ordered nanopores in semiconductors are attractive for numerous biological, electrical, and optical applications. Here, GaN nanorods with continuous pores running axially through their centers were grown by organometallic vapor phase epitaxy. The porous nanorods nucleate on an underlying (0001)-oriented GaN film through openings in a SiN(x) template that are milled by a focused ion beam, allowing direct placement of porous nanorods. Nanopores with diameters ranging from 20-155 nm were synthesized with crystalline sidewalls.

Published

2011

11. Built-in Electric Field Minimization in (In, Ga)N Nanoheterostructures

Author

Liang, Zhiwen, primary, Wildeson, Isaac H., additional, Colby, Robert, additional, Ewoldt, David A., additional, Zhang, Tong, additional, Sands, Timothy D., additional, Stach, Eric A., additional, Benes, Bedrich, additional, and García, R. Edwin, additional

Published

2011

12. Controlled Growth of Ordered Nanopore Arrays in GaN

Author

Wildeson, Isaac H., primary, Ewoldt, David A., additional, Colby, Robert, additional, Stach, Eric A., additional, and Sands, Timothy D., additional

Published

2011

13. Publisher's Note: “GaN nanostructure design for optimal dislocation filtering” [J. Appl. Phys. 108, 074313 (2010)]

Author

Liang, Zhiwen, primary, Colby, Robert, additional, Wildeson, Isaac H., additional, Ewoldt, David A., additional, Sands, Timothy D., additional, Stach, Eric A., additional, and García, R. Edwin, additional

Published

2010

14. Publisher's Note: “III-nitride nanopyramid light emitting diodes grown by organometallic vapor phase epitaxy” [J. Appl. Phys. 108, 044303 (2010)]

Author

Wildeson, Isaac H., primary, Colby, Robert, additional, Ewoldt, David A., additional, Liang, Zhiwen, additional, Zakharov, Dmitri N., additional, Zaluzec, Nestor J., additional, García, R. Edwin, additional, Stach, Eric A., additional, and Sands, Timothy D., additional

Published

2010

15. GaN nanostructure design for optimal dislocation filtering

Author

Liang, Zhiwen, primary, Colby, Robert, additional, Wildeson, Isaac H., additional, Ewoldt, David A., additional, Sands, Timothy D., additional, Stach, Eric A., additional, and García, R. Edwin, additional

Published

2010

16. Dislocation Filtering in GaN Nanostructures

Author

Colby, Robert, primary, Liang, Zhiwen, additional, Wildeson, Isaac H., additional, Ewoldt, David A., additional, Sands, Timothy D., additional, García, R. Edwin, additional, and Stach, Eric A., additional

Published

2010

17. Organometallic vapor phase epitaxial growth of GaN on ZrN∕AlN∕Si substrates

Author

Oliver, Mark H., primary, Schroeder, Jeremy L., additional, Ewoldt, David A., additional, Wildeson, Isaac H., additional, Rawat, Vijay, additional, Colby, Robert, additional, Cantwell, Patrick R., additional, Stach, Eric A., additional, and Sands, Timothy D., additional

Published

2008