Najla Alnami Data-verified
Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.
Researcher
unknown
Research Areas
Biography and Research Information
OverviewAI-generated summary
Najla Alnami is a researcher at the University of Arkansas at Fayetteville. Her work focuses on the development and characterization of advanced materials for electronic and optical applications. She has investigated InAs nanostructures for solar cell applications, aiming to improve efficiency through quantum dot integration. Alnami has also studied the temperature-dependent behavior of these quantum dot-based solar cells and explored low-resistance Ohmic contacts for graded InGaN materials.
Her recent publications also include work on high-entropy ceramics, specifically (Ba,Sr)Nb2O6 dielectric bronze structures, examining their ultra-high breakdown strength and near-zero interfacial polarization. Additionally, she has researched the radiation shielding performance of these high-entropy tungsten bronze ceramics, analyzing the role of structural order and high-Z elements in photon attenuation. Alnami collaborates with researchers including Morgan E. Ware, Alaa A. Alnami, Yuriy I. Mazur, and Reem Alhelais, with whom she shares multiple publications.
Metrics
- h-index: 3
- Publications: 4
- Citations: 28
Selected Publications
-
Temperature dependent behavior of sub-monolayer quantum dot based solar cell (2023)
-
Low resistance Ohmic contacts to graded InGaN (2022)
-
InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot (2021)
Collaboration Network
Top Collaborators
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Temperature dependent behavior of sub-monolayer quantum dot based solar cell
- Low resistance Ohmic contacts to graded InGaN
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Temperature dependent behavior of sub-monolayer quantum dot based solar cell
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Low resistance Ohmic contacts to graded InGaN
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Temperature dependent behavior of sub-monolayer quantum dot based solar cell
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Low resistance Ohmic contacts to graded InGaN
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Low resistance Ohmic contacts to graded InGaN
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Temperature dependent behavior of sub-monolayer quantum dot based solar cell
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Temperature dependent behavior of sub-monolayer quantum dot based solar cell
- Radiation shielding performance of high-entropy tungsten bronze ceramics: the role of structural order and high-z elements in photon attenuation
- Ultra-high breakdown strength and near-zero interfacial polarization of (Ba,Sr)Nb2O6 dielectric bronze structure-based ceramics via high-entropy strategy
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- InAs nanostructures for solar cell: Improved efficiency by submonolayer quantum dot
- Low resistance Ohmic contacts to graded InGaN
- Low resistance Ohmic contacts to graded InGaN
- Temperature dependent behavior of sub-monolayer quantum dot based solar cell
- Radiation shielding performance of high-entropy tungsten bronze ceramics: the role of structural order and high-z elements in photon attenuation
Similar Researchers
Based on overlapping research topics